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Sexual dimorphism

Sexual dimorphism refers to the systematic differences in physical characteristics, physiology, and behavior between males and females of the same species, often manifesting as variations in size, coloration, body structures, or reproductive roles. These distinctions are widespread across the animal kingdom and are shaped by evolutionary pressures that enhance reproductive success and survival. In many species, sexual dimorphism is evident in body size, with males typically larger than females in polygynous mammals such as gorillas (Gorilla gorilla) and northern fur seals (Callorhinus ursinus), where male body mass can exceed female mass by ratios greater than 1.6 due to intense intrasexual for mates. Conversely, reverse sexual dimorphism occurs in taxa like (e.g., eagles and hawks), spiders, and certain , where females are larger to support greater egg production or foraging demands. Coloration differences are common in birds, such as the vibrant of male pheasants contrasting with the subdued tones of females, which aids in mate attraction while reducing female predation risk. Specialized body parts, like antlers in male deer or elongated tusks in male , further exemplify dimorphism driven by male-male rivalry. The primary drivers of sexual dimorphism include , where traits evolve through or , and favoring ecological adaptations, such as divergent strategies or environmental tolerances. For instance, in damselflies (Megalagrion calliphya), female color morphs (dull green at low altitudes versus bright red at high altitudes) reflect viability selection for UV protection rather than solely of males. In mammals, dimorphism correlates with mating systems: minimal in monogamous species but pronounced in polygynous ones, influenced by and resource distribution. Behavioral dimorphisms, such as male aggression or female , often accompany morphological ones, reinforcing sex-specific roles. Overall, sexual dimorphism underscores the adaptive diversity in , appearing across phyla from to , and continues to inform studies in , , and . Its study reveals how sex-biased and environmental factors interact to produce these differences, with implications for understanding and conservation.

Introduction

Definition and Scope

Sexual dimorphism refers to the systematic differences in , , or behavior exhibited by males and females of the same , extending beyond primary such as gonads and gametes to include traits like size, coloration, ornamentation, and behaviors. These differences arise due to divergent evolutionary pressures on the sexes and are a widespread phenomenon in nature. The concept of sexual dimorphism was prominently discussed by in his 1871 publication The Descent of Man, and Selection in Relation to Sex, where he described such differences as a product of mechanisms that favor traits enhancing . Sexual dimorphism manifests across multiple kingdoms of life, including in via dioecy, where separate male and female individuals display distinct reproductive structures and resource allocation; in animals, often through pronounced size or structural variations between sexes; and in fungi, where can lead to dimorphic differences in investment or morphological forms during reproduction. This scope distinguishes sexual dimorphism from mere sex determination, emphasizing its role in adaptive divergence driven by , which operates through intrasexual competition (e.g., same-sex rivalry for mates) or intersexual choice (e.g., preferences for attractive traits in ). A key metric for quantifying sexual dimorphism, particularly in body , is the sexual size dimorphism (SSD) ratio, defined as body mass divided by body mass, which highlights the extent of size disparity and its evolutionary implications. This index, along with others like logarithmic transformations for comparative analyses, allows researchers to assess patterns of dimorphism across taxa without assuming directional bias toward larger s or s.

General Types and Examples

Sexual dimorphism manifests in various forms across animal species, primarily driven by to enhance success. Common types include size differences, coloration variations, structural ornaments, and behavioral traits, each serving roles in or . These traits often exhibit a cost-benefit , where elaborate features signal genetic quality despite potential survival drawbacks. Size dimorphism, or differences in body size between sexes, is prevalent in many vertebrates, particularly mammals where males are typically larger to facilitate intrasexual competition for mates. For instance, in , males can weigh more than twice as much as females, with body weight ratios around 2.0-2.4 in various populations, aiding in dominance displays and defense. In contrast, in birds, patterns of sexual size dimorphism often follow Rensch's rule, where the degree of dimorphism scales with body size—typically with females larger in smaller , such as raptors, to support egg production and , while larger show reduced female bias or male bias. This pattern underscores how size differences evolve in response to ecological pressures like predation risk and reproductive roles. Color dimorphism, often termed sexual dichromatism, involves distinct pigmentation between sexes, usually with males displaying brighter hues to attract females. In guppies (Poecilia reticulata), males exhibit vibrant orange, black, and iridescent spots, while females are duller olive-gray, allowing males to stand out in visual courtship. Similarly, in birds like the mallard duck (Anas platyrhynchos), males possess iridescent green heads and chestnut breasts during breeding season, contrasting with the mottled brown plumage of females, which provides for nesting. In fish such as cichlids, male nuptial coloration evolves rapidly under , promoting species recognition and . Additionally, (UV) reflectance contributes to hidden dimorphism in ; for example, male pierid butterflies like display UV-reflecting scales on their wings absent in females, aiding sexual recognition during courtship. Structural dimorphism encompasses sex-specific modifications to body parts, frequently as ornaments or weapons used in display or rivalry. Antlers in male deer, such as the (Cervus elaphus), are seasonally grown bony structures absent in females, serving as honest signals of male health and vigor during rutting contests; larger antlers correlate with higher testosterone levels and mating success. A classic ornament is the peacock's (Pavo cristatus) elongated tail feathers, which males fan in elaborate displays to females; these train feathers impose aerodynamic costs, aligning with the proposed by Zahavi, where only high-quality males can afford such handicaps without compromising survival. This principle posits that costly signals reliably indicate genetic fitness, as weaker individuals cannot sustain the trait's energetic or predatory burdens. Behavioral dimorphism includes sex-specific actions like rituals, which amplify physical differences. Males in many perform dynamic displays, such as the bowing and wing-spreading of male birds-of-paradise, to showcase agility and coloration, thereby influencing female mate selection. These behaviors often integrate multiple sensory cues, reinforcing morphological traits. Beyond morphology, non-physical dimorphism appears in sensory signals like vocalizations and chemical cues. In songbirds, males typically produce complex for territory defense and mate attraction, supported by sexually dimorphic brain regions; for example, in zebra finches (Taeniopygia guttata), the song control nuclei are significantly larger in males, enabling learned repertoires absent or simpler in females. also exhibit dimorphism, as in male greater spear-nosed bats (Phyllostomus hastatus), whose chest glands secrete odors signaling mating status and dominance, detected by females via pheromones to assess reproductive viability. These traits highlight how dimorphism extends to communication systems, enhancing and success.

Mechanisms of Sexual Dimorphism

Genetic and Chromosomal Bases

Sexual dimorphism arises fundamentally from differences in sex determination systems across taxa, which establish the genetic framework for sex-specific development. In mammals, the system predominates, where males possess one X and one Y chromosome, while females have two X chromosomes; the presence of the triggers male development. In contrast, birds and many reptiles employ the ZW system, in which males are ZZ (homogametic) and females are ZW (heterogametic), with the dosage of Z-linked genes influencing sex differentiation. Among insects, particularly in the order (such as bees, ants, and wasps), is common, where unfertilized eggs develop into haploid males and fertilized eggs into diploid females, leading to inherent genetic differences that contribute to dimorphic traits like size and behavior. Key genes on sex chromosomes play pivotal roles in initiating these dimorphic pathways. In mammals, the SRY gene on the acts as the primary testis-determining factor, encoding a that upregulates genes for male development around embryonic day 10.5 in mice, thereby directing the bipotential toward testes formation and subsequent male-specific traits. In birds and reptiles, the DMRT1 gene, located on the Z , serves a analogous function; its higher dosage in ZZ males promotes testis differentiation, as demonstrated by knockdown experiments in embryos that result in ovarian-like development. To mitigate imbalances from sex , dosage compensation mechanisms evolved, such as X-chromosome inactivation in female mammals, where one X is randomly silenced via the long non-coding RNA , equalizing X-linked between XX females and XY males. Beyond chromosomal composition, epigenetic modifications fine-tune sex-specific , amplifying dimorphism without altering DNA sequences. and modifications, including at residues on histones and H4, repress or activate genes in a sex-biased manner, particularly in the and gonads; for instance, sex-specific patterns at promoter regions of steroidogenic genes contribute to dimorphic reproductive behaviors in . Recent research highlights how these mechanisms intersect with development in sexual dimorphism (SSD); a 2024 comparative genomic analysis of 124 species revealed that greater SSD correlates with contracted families involved in and expanded families for olfactory signaling in the larger sex, suggesting epigenetic regulation of these repertoires underlies adaptive dimorphisms. Many dimorphic s are polygenic, involving additive effects from numerous loci rather than single genes, with moderate indicating substantial genetic contributions modifiable by selection. Genome-wide association studies (GWAS) in humans further illustrate this for , a classic dimorphic trait; sex-stratified analyses of over 270,000 individuals identified loci where X- and Y-linked genes, such as those in pseudoautosomal regions, contribute to the ~10-12 cm average difference between adult stature through dosage effects. These findings underscore the polygenic architecture, where thousands of variants across autosomes and collectively drive dimorphism, with minimal overlap in effect sizes between sexes for some traits.

Hormonal and Developmental Influences

Hormonal influences play a pivotal role in the of sexual dimorphism by directing the and of sexually dimorphic traits across vertebrates. Androgens, particularly testosterone, promote male-specific characteristics such as increased and skeletal robustness through binding to androgen receptors, which regulate in target tissues like . Estrogens, on the other hand, contribute to female skeletal dimorphism by modulating formation and resorption, preserving and influencing pelvic structure to support . The timing of hormone exposure during is crucial, with critical periods determining the establishment of dimorphic traits. In embryos, gonadal begins around 6-8 weeks of , when bipotential gonads develop into testes or ovaries under hormonal cues, setting the stage for subsequent sex-specific growth patterns. Hormonal effects are categorized as organizational, occurring during early to permanently shape neural and somatic structures, or activational, which transiently modulate traits in adulthood in response to circulating hormones. Recent research has elucidated the mechanisms underlying these processes. A 2024 demonstrated that in the drive dimorphism by inducing global gene suppression, leading to male-biased proliferation and size differences in muscle fibers. Another 2024 investigation revealed sex-specific of sex hormones in cells, with signaling enhancing male muscle during development. Additionally, sex-specific patterns of secretion in vertebrates, such as episodic pulses in males versus continuous release in females, contribute to dimorphic body size and metabolic differences. Environmental factors can interfere with these hormonal and developmental pathways. Endocrine-disrupting chemicals, such as those from effluents, reduce sexual dimorphism in by altering gonadal , decreasing gonad size, and inducing conditions that blur male-female trait distinctions. These pollutants mimic or block hormones, disrupting critical periods and leading to diminished reproductive and somatic dimorphism in affected populations.

Sexual Dimorphism in Plants

Dioecy and Floral Differences

, the condition where reproductive structures occur on separate individuals, is a key manifestation of sexual dimorphism in , particularly among angiosperms. Approximately 5-6% of angiosperm species exhibit dioecy, encompassing around 15,600 species across 987 genera and 175 families. This sexual system contrasts with , in which both flowers are borne on the same , a more common arrangement that serves as a frequent evolutionary precursor to dioecy through the separation of sexual functions onto distinct individuals. Prominent examples include willows (Salix spp.), where catkins differ markedly, and (Ilex spp.), with male producing more numerous flowers for dispersal. In dioecious plants, floral dimorphism is pronounced, with male flowers typically featuring multiple stamens optimized for production and dispersal, while female flowers emphasize larger ovaries and pistils for development and maturation. Male flowers often exhibit enhanced structures such as more numerous or elongated stamens to maximize release, whereas female flowers prioritize robust carpels to support and set. For instance, in the dioecious plant , male plants produce more flowers and emit significantly higher amounts of scent per flower to attract pollinators, although individual male flowers have smaller petals than those of s. These differences arise from sex-specific selection pressures, where males invest heavily in traits promoting export, and s in those ensuring fertilization and offspring viability. Pollinator-mediated selection further drives floral dimorphism, particularly in traits like scent and production that influence behavior. Male flowers frequently emit stronger or more attractive scents to draw for collection, as seen in where males produce significantly higher floral scent emissions per flower compared to females. In contrast, female flowers may offer greater rewards or differ in scent profiles to facilitate deposition while conserving energy for development, reflecting a division where males emphasize display and attraction, and females focus on resource investment in reproduction. Such dimorphisms enhance cross-pollination efficiency in dioecious systems by tailoring floral signals to preferences. Recent genomic studies have illuminated the evolutionary origins of through sex chromosome development in like (Asparagus officinalis). A 2023 review highlights how and chromosomal rearrangements contribute to and the stabilization of , with serving as a model due to its young sex chromosomes that evolved from autosomes, suppressing female functions on the . These findings underscore the role of epigenetic and genetic mechanisms in transitioning from hermaphroditism to separate sexes, often via monoecious intermediates, and reveal ongoing evolutionary dynamics in dioecious lineages.

Size and Structural Variations

Sexual dimorphism in plant size manifests in various dioecious species, where differences in stature between males and females often align with sex-specific reproductive demands. In the wind-pollinated annual Rumex hastatulus, males grow taller than females during the flowering period, facilitating greater pollen dispersal by elevating inflorescences above the canopy. This height advantage reverses post-flowering, allowing females to allocate resources toward seed production without the ongoing costs of maintaining elevated structures. Conversely, in the aquatic herb Vallisneria natans, females exhibit larger overall size, including greater leaf length and vegetative biomass, which supports the substantial energy investment required for seed maturation and dispersal. Such patterns reflect broader trends where male-biased size dimorphism predominates in species prioritizing pollen export, while female-biased dimorphism occurs in those emphasizing fruit and seed development. Structural variations beyond height also contribute to sexual dimorphism in vegetative traits, optimizing resource acquisition and allocation to reproductive functions. Leaf morphology often differs between sexes; for instance, in dioecious (boxelder maple), females exhibit higher photosynthetic rates than males under well-watered conditions but are more sensitive to stress. Root systems similarly show sex-specific adaptations; for example, in the dioecious annual , males allocate more to to capture mobile like for production, while females may adjust root allocation based on resource availability. These differences arise from divergent physiological needs, where males focus on rapid growth and nutrient mobility, and females on sustained resource storage. Ecological costs associated with size and structural dimorphism can impose selective pressures, particularly on females in resource-poor environments. Larger female plants, as seen in Vallisneria natans, incur higher metabolic demands for maintenance and reproduction, leading to elevated mortality rates if nutrients or become limiting, as females deplete local resources more intensively than males. In woody dioecious species, this often results in females being smaller overall to mitigate such costs, though herbaceous taxa like tolerate greater female size due to their shorter lifespans and aquatic habitats. Evolutionary trade-offs underpin these dimorphisms through allocation theory, which posits that limited resources force sex-specific partitioning between , maintenance, and . Males typically invest disproportionately in vegetative and structures like taller stems to enhance dispersal, trading off against or . Females, in contrast, allocate more to reproductive sinks such as seeds, often at the expense of somatic , resulting in structural adaptations like broader leaves for increased to offset these costs. This three-way among shoots, roots, and reproductive organs drives the of dimorphism, ensuring optimal under sex-specific selection.

Sexual Dimorphism in Invertebrates

In Insects

Sexual dimorphism in insects manifests in diverse morphological and behavioral traits, shaped by varying mating strategies that favor different reproductive roles between sexes. In groups with haplodiploid sex determination systems, such as Hymenoptera, these differences are further influenced by asymmetric relatedness that contributes to social behaviors. Size differences are prominent, with female-biased sexual size dimorphism (SSD) common in species where larger body size correlates with higher fecundity, such as in honeybees (Apis mellifera), where queens and workers exhibit compound eyes and overall structures adapted for their roles, contrasting with smaller drones optimized for mating flights. Conversely, male-biased SSD occurs in certain beetles, including horned species like Onthophagus babirussa, where males are significantly larger than females in multiple populations (e.g., sexual dimorphism index ranging from -1.03 to -1.12), enabling greater investment in precopulatory traits like horns for rival combat. Ornamentation further highlights dimorphism, particularly in males of stag beetles (Cyclommatus metallifer), where elongated mandibles—up to 1.30 times body length—serve as weapons in male-male contests to secure access, imposing locomotor costs like a 40% increase in energy expenditure due to shifted body mass. In females, structures like the exemplify sex-specific adaptations; in locusts ( migratoria), extensible abdominal intersegmental membranes, regulated by the Tra/Dsx-JHBP axis, enable deep soil egg-laying, a absent in males and essential for oviposition success. Haplodiploidy plays a key role in eusocial , where favors sterile female workers that forgo reproduction to rear sisters, to whom they are related by 3/4, higher than the 1/2 relatedness to their own , as evidenced in like and bees. This system underpins the evolution of worker sterility and colony-level , with empirical support from investment ratios skewed toward females (e.g., 1:3 male:female in monogynous ). Recent research on reveals sex-biased (SBGE) and sex-specific splicing (SSS) as mechanisms resolving sexual antagonism, with SSS showing adaptive evolution (elevated direction of selection) particularly in male-biased genes, contributing to dimorphic traits. Flight and sensory traits often show male-biased elaboration for mate location, as in diurnal moths like Teia anartoides, where males possess larger, feathery bipectinate antennae packed with sensilla for pheromone detection and enlarged eyes for visual searching, both scaling positively with body size (antennae r² = 0.196; eyes β = 0.354) to enhance in monandrous systems. Sexual dimorphism also occurs in other invertebrates, such as crustaceans (e.g., male claws in fiddler crabs) and mollusks (e.g., shell differences in snails), though less extreme than in insects and spiders.

In Spiders Including Sexual Cannibalism

Spiders exhibit some of the most extreme cases of sexual size dimorphism (SSD) among animals, with females often substantially larger than males, particularly in orb-weaving species. In certain orb-weavers, such as those in the genus (now Trichonephila), adult females can be up to 50 times heavier than males or more, a pattern driven primarily by female rather than male alone. This pronounced size disparity enhances female by allowing greater egg production and web-building capacity but constrains male mobility, making them more agile for locating dispersed females during mate-searching while limiting their lifespan and dispersal range. A striking behavioral manifestation of this dimorphism is sexual cannibalism, where females consume males before, during, or after mating, observed in over 30 spider families including theridiids and araneids. In black widow spiders (Latrodectus spp.), females frequently cannibalize males post-copulation, providing the female with a nutritional boost that supports egg development and offspring survival. From the male's perspective, this act can be adaptive in species where males have low future reproductive potential after a single mating; for instance, males may actively position themselves for consumption to prolong copulation and increase sperm transfer, thereby enhancing paternity share. Sexual dimorphism also extends to sensory and reproductive structures, notably the genitalia. Males possess enlarged pedipalps, modified appendages serving as secondary sexual organs that store and transfer , often bulbous and ornate to facilitate precise insertion during the brief window. Females, in contrast, feature an —a sclerotized external genital plate that receives and prevents multiple or sperm mixing—adapted to the male's palp for species-specific locking . These structures underscore the coevolutionary in , where dimorphic traits minimize interspecific errors while heightening intraspecific conflicts. Recent research has highlighted instances of non-adaptive sexual cannibalism, where female aggression leads to mate consumption without clear nutritional or reproductive benefits. In jumping spiders (Plexippus paykulli), food-deprived females display elevated pre-copulatory aggression, resulting in higher cannibalism rates that reduce overall mating success rather than conferring advantages. Such condition-dependent behaviors suggest that in some contexts, cannibalism arises from heightened female hostility rather than strategic adaptation, potentially disrupting male reproductive strategies.

Sexual Dimorphism in Fish

Size and Coloration Differences

Sexual size dimorphism (SSD) in fish varies widely across species, reflecting differences in mating systems, parental care, and selection pressures. Male-biased SSD, where males grow larger than females, is common in species involving intense male-male competition and nest guarding, as larger size aids in territorial defense and mate attraction. For instance, in wild populations of (Oncorhynchus nerka), males exhibit pronounced male-biased SSD due to for larger body size in competitive breeding contexts. This pattern contrasts with female-biased SSD observed in species with role-reversed , such as pipefishes (), where females are larger to produce excess eggs that fill the male's brood pouch during , enhancing female under male-limited conditions. Coloration differences represent a key aspect of sexual dimorphism in , often serving as visual signals in while balancing predation risks. Males typically develop vibrant nuptial coloration during breeding seasons to advertise to females, whereas females maintain subdued hues for in their environments. In guppies (Poecilia reticulata), males display intricate patterns of orange spots and iridescent scales as secondary sexual traits, which females prefer for mating, while females remain drab to evade predators. These color dimorphisms are hormonally regulated and evolve under , with male brightness correlating to genetic quality and parasite resistance. Beyond size and color, structural dimorphisms in and body markings further distinguish sexes in many fish. Males often evolve exaggerated extensions for and during . In green swordtails (Xiphophorus hellerii), males possess an elongated, sword-like lower caudal lobe, a sexually selected trait that enhances female and signals male vigor, absent in females. Sex-specific spotting patterns, such as brighter or more contrasting markings on male flanks, also occur in species like cichlids, aiding species recognition and mate attraction without compromising female . Environmental factors like temperature can modulate the expression of these dimorphisms through mechanisms such as (TSD) in polygenic or environmentally influenced systems. In species exhibiting TSD, such as the southern flounder (Paralichthys lethostigma), elevated temperatures bias offspring toward maleness, skewing sex ratios and intensifying intrasexual competition, which in turn amplifies male-biased SSD and ornamental traits due to heightened selection pressures. This interaction highlights how abiotic conditions shape morphological divergence between sexes in fish.

Reproductive Structures

Sexual dimorphism in reproductive structures is prominently manifested in the gonads, where males develop paired testes responsible for and the production of spermatozoa, while females develop ovaries that facilitate and egg production. This fundamental distinction arises during embryonic or larval stages, influenced by genetic and environmental factors, and supports the diverse reproductive strategies observed across taxa, from broadcast spawning to . In many species, such as the (Oreochromis niloticus), the morphological of gonads becomes evident around 20-30 days after , with testes forming compact lobular structures and ovaries developing an early . Some species exhibit hermaphroditism as an adaptive reproductive , allowing flexibility in sex roles. Sequential , where individuals change sex during their lifetime, is well-documented in ( spp.), which are protandrous: all individuals initially develop as males with functional testes, but the dominant individual in a social group transitions to , developing ovaries while the testes regress. This process is regulated by social cues and involves molecular , including upregulation of female-biased genes like cyp19a1a during the . Accessory reproductive organs further highlight dimorphism tailored to mating systems. In elasmobranchs such as and rays, males possess paired claspers—elongated, calcified extensions of the pelvic fins—used to deliver sperm directly into the female's during , a trait absent in females. Conversely, in syngnathid fishes like ( spp.), females have a specialized that transfers unfertilized eggs into the male's brood pouch, where fertilization and embryonic development occur, inverting typical parental roles. Spawning-related traits also demonstrate dimorphism linked to investment. Male three-spined sticklebacks (Gasterosteus aculeatus) construct elaborate nests from material and glue secreted by kidneys, a behavior-driven structure that facilitates deposition and protection, which females lack. Females across many fish species, including those with , exhibit variation in size correlated with body size and , often producing larger, yolk-rich s to enhance survival in nutrient-poor environments. Recent genetic research has elucidated mechanisms underlying dimorphic gamete production, particularly in aquaculture species like tilapia. A 2023 study identified the Dmrt1 gene as essential for testicular differentiation and spermatogenesis in Nile tilapia, with its knockout leading to ovarian development in genetic males, underscoring its role in maintaining sex-specific gamete production pathways. These findings highlight how genetic factors drive reproductive dimorphism, with implications for sex ratio manipulation in farming.

Sexual Dimorphism in Amphibians and Reptiles

In Amphibians

Sexual dimorphism in amphibians manifests prominently in anurans (frogs and toads) and caudates (salamanders and newts), often linked to reproductive behaviors in moist-skinned, semi-aquatic environments. In anurans, female-biased sexual size dimorphism (SSD) predominates, with females larger to support higher fecundity, observed in over 90% of species. Male-biased SSD occurs less frequently but is evident in species like the Emei moustache toad (Leptobrachium boringii), where males exceed females in body length by about 13% and mass by 87%, facilitating territorial competition. Skin differences include sexually dimorphic glands and coloration; for instance, males of many species develop breeding glands that secrete pheromones, while females often exhibit thicker skin. Vocal dimorphism is a key trait in anurans, primarily male-driven for advertisement calls that attract females and deter , produced via laryngeal structures and often amplified by subgular vocal sacs. These calls vary in frequency and duration between sexes. Female vocal sacs are uncommon, occurring in fewer than 5% of anuran . In salamanders, is minimal, but auditory processing shows sexual dimorphism. Reproductive traits exhibit marked dimorphism adapted to and transfer. Males develop nuptial pads—keratinized, glandular structures on forelimbs or thumbs—during breeding, induced by androgens to grip females securely, as seen in Rana chensinensis where pads form on the first digit. These pads are absent or rudimentary in females, whose cloacas are adapted for egg extrusion, often larger to accommodate clutches of hundreds to thousands. In , a limbless order, dimorphism includes male-specific copulatory organs like the phallodeum for . In salamanders, environmental factors like influence dimorphism through developmental plasticity. Under Rensch's rule, SSD magnitude increases with body size in male-larger species but decreases in female-larger ones, potentially modulated by temperature-driven growth rates. also affects hormone-mediated traits.

In Reptiles Including Non-Avian Dinosaurs

Sexual dimorphism in reptiles manifests primarily through differences in body size and , often driven by and reproductive demands. In many species, males exhibit larger heads relative to body size compared to females, facilitating enhanced biting performance during male-male competition for mates. This male-biased sexual size dimorphism (SSD) is widespread across lizard taxa, where head size correlates with aggressive interactions rather than differences. In contrast, turtles display a predominantly female-biased SSD, with females achieving larger carapace lengths to accommodate egg production and laying; phylogenetic analyses indicate this pattern as the ancestral condition in the group. Coloration and scale structures further highlight dimorphism in reptiles, particularly in display traits. Male anole lizards (Anolis spp.) possess prominent, extensible dewlaps—throat fans used in visual signaling during and territorial disputes—while female dewlaps are typically rudimentary or absent, reducing visibility to predators and emphasizing for egg-guarding. This sexual dichromatism and structural difference underscores male investment in mate attraction, with female traits prioritizing survival and reproduction over display. Fossil evidence from non-avian dinosaurs reveals evolutionary continuity in reptilian dimorphism, though identification remains challenging due to limited sex determination in specimens. In ornithomimosaurs, subtle differences in femur curvature between individuals from a single herd suggest sexual dimorphism, with equal male-female ratios indicating non-biased mortality. Ornamental crests in hadrosaurs, such as those in , likely served as male-specific display structures for , varying in shape and size to signal fitness during mating. For theropods like Tyrannosaurus rex, bone robusticity variations have been proposed as indicators of SSD, potentially with females larger to support , though definitive is elusive and debated. Parthenogenetic reptiles, such as whiptail lizards (Aspidoscelis uniparens), lack traditional sexual dimorphism due to their all-female composition and via of maternal genomes. These unisexual populations, derived from hybridization of sexual ancestors, exhibit no morphological differences between "sexes" since males are absent, bypassing dimorphic traits like size or coloration.

Sexual Dimorphism in Birds

Plumage and Size Differences

Sexual dichromatism in avian plumage, where males exhibit brighter or more elaborate coloration than females, is a prevalent form of sexual dimorphism driven primarily by sexual selection. In many species, males develop vibrant hues and ornamental feathers to attract mates, while females maintain cryptic plumage for camouflage during nesting. For instance, in birds-of-paradise (family Paradisaeidae), males display spectacular tail plumes, iridescent feathers, and elongated ornaments, contrasting sharply with the subdued browns and greens of females, a pattern that has evolved over millions of years under strong sexual selection pressures. The ZW sex-determination system in birds contributes to this dimorphism, as genes on the Z chromosome, which males (ZZ) possess in double dosage unlike females (ZW), influence pigmentation and ornamentation without full dosage compensation. Sexual size dimorphism (SSD) in varies by and , with female-biased SSD common in raptors where larger females aid in provisioning chicks and defending territories. In species like the (Haliaeetus leucocephalus), females can be up to 25% heavier than males, allowing them to handle larger prey and incubate eggs more effectively. Similarly, in hummingbirds (family Trochilidae), females are typically 15-25% larger than males, a reversal that supports their role in egg production and territorial defense at nectar sources, as seen in the ( colubris). Male-biased SSD occurs in other groups, such as galliforms, where larger males compete for mates, but overall, SSD patterns reflect ecological roles rather than a universal trend. Structural dimorphisms further highlight sex-specific adaptations in . Males often develop prominent combs, wattles, and spurs, which are testosterone-dependent and serve as signals of and dominance; for example, in domestic roosters (Gallus gallus domesticus), these fleshy appendages are significantly larger and more vivid than in hens. In contrast, females exhibit brood patches—vascularized, featherless areas on the abdomen that facilitate —absent in males and forming seasonally under hormonal influence. Long-distance migration influences plumage dimorphism by favoring reduced female ornamentation for survival during travel and wintering, often increasing overall dichromatism as males retain brighter displays. In wood-warblers (family Parulidae), migratory species show evolutionary loss of female coloration compared to resident taxa, enhancing against predation while males' signals remain geared toward . This pattern underscores how migratory constraints can amplify dimorphic traits, linking to display behaviors in non-migratory contexts.

Behavioral Correlates

In exhibiting pronounced sexual dimorphism, behavioral patterns such as displays often leverage physical traits like to facilitate mate attraction and selection. In (Centrocercus urophasianus), males gather in leks to perform elaborate displays, incorporating inflated and tail feathers that amplify acoustic signals, which serve as key cues for female assessment. Females actively compare multiple males, initially attracted by the inter-pop interval of acoustic components in the display, but ultimately mating based on display rate and repetition, reflecting a two-stage process of passive attraction followed by active choice that reinforces on male traits. Size dimorphism in birds can also correlate with reversed parental roles, where larger females compete intensely for mates while smaller males assume primary caregiving duties. In phalaropes, such as the (Phalaropus fulicarius), females are larger and more brightly colored than males, enabling them to engage in sequential and aggressive mate competition; post-laying, females desert the clutch, leaving males to perform all and brood-rearing alone. This aligns with female-biased operational sex ratios during breeding, where male limits their remating opportunities, thus tying body size differences to the division of reproductive labor. Aggressive behaviors among males frequently exploit dimorphic structures adapted for , enhancing access to territories. In galliform like pheasants and gamefowl (), males possess longer and more numerous leg spurs than females, which are used in intrasexual fights to establish dominance on leks or display grounds. Phylogenetic analyses indicate that spur dimorphism evolves through repeated gains and losses across the , primarily under selection for male-male competition rather than direct female preference, with rates of evolutionary change lower than for ornamental traits. Recent investigations into vocal behaviors reveal sexual dimorphism in song learning among oscine songbirds, linked to anatomical differences in the , the avian vocal organ. In zebra finches (Taeniopygia guttata), males develop a larger with enhanced muscle mass and contraction speed during the song-learning phase around 20-60 days post-hatch, enabling complex syllable production, whereas female es remain underdeveloped and incapable of similar vocalizations. This dimorphism emerges primarily through behavioral use (daily singing practice) rather than solely hormonal cues, as prevents male maturation; females preferentially respond to songs from males with exercised es, underscoring the behavioral reinforcement of vocal dimorphism in .

Sexual Dimorphism in Mammals

General Patterns

Sexual size dimorphism (SSD) in mammals most commonly manifests as male-biased patterns, where males are larger than females, occurring in approximately 45% of species across the class, with in 39% and female-biased SSD in 16%. This male-biased SSD is often linked to intrasexual competition, such as for mates, as seen in species where larger body size confers advantages in establishing dominance or defending territories. In contrast, female-biased SSD predominates in certain orders like bats, where females are typically larger to support the energetic demands of , , and flight efficiency during migration or foraging. Fur and scent-based dimorphisms further highlight sex-specific adaptations in mammals. Males in some species develop prominent secondary sexual traits in pelage, such as the mane in lions (Panthera leo), which emerges at and signals maturity, health, and fighting ability to potential mates and rivals. Sex-specific pheromones, volatile chemical signals produced by glands, are widespread and mediate reproductive behaviors; for instance, male-specific pheromones in like the (Mus musculus) attract females and influence estrus synchronization. These olfactory cues often differ between sexes, with males emitting signals that promote female receptivity during breeding seasons. Sensory dimorphisms also contribute to sexual differences in mammalian . In certain , such as howler monkeys (Alouatta spp.), males exhibit routine dichromatic due to X-linked genetics, limiting color discrimination, while heterozygous females can achieve , enhancing detection of ripe fruits or social signals. Females across many mammalian taxa demonstrate superior olfactory acuity compared to males, aiding in mate selection, , and resource location; for example, in , females show heightened sensitivity to pheromones during reproductive cycles. Lactation represents a profound physiological dimorphism exclusive to mammals, involving the development of mammary glands that produce for nourishment. This trait significantly alters , with mammary expansion and associated fat deposition supporting extended periods, as observed in species ranging from monotremes to placentals. The energetic investment in often correlates with female-specific skeletal and muscular adaptations to accommodate postures and milk ejection.

In Pinnipeds

Pinnipeds exhibit some of the most extreme examples of sexual size dimorphism (SSD) among mammals, with adult males often 2 to 10 times heavier than females due to intense in polygynous mating systems. In northern elephant seals (Mirounga angustirostris), males can reach lengths of up to 5 meters and weights up to 2,300 kg, while females typically measure up to 3.5 meters and weigh 600 to 900 kg. This disparity arises primarily from males' need to compete aggressively for access to females on breeding beaches, where larger body size enhances success in territorial contests. Similar patterns occur in other pinnipeds, such as southern elephant seals (Mirounga leonina), where males weigh up to 4,000 kg compared to females at around 800 kg, underscoring the role of SSD in male-male rivalry. Male pinnipeds display pronounced secondary sexual ornaments adapted for display and combat, further accentuating dimorphism. In elephant seals, the —a flexible, trunk-like nasal extension unique to mature males—serves to amplify roars during agonistic interactions, producing sounds up to 102 dB to deter rivals without physical contact. Additionally, males develop thickened, callused on the chest, , and , forming a protective shield that withstands bites and impacts during fights; this epidermal armor is absent or minimal in females. In otariids like California sea lions (Zalophus californianus), males possess a dense of coarse hair around the and shoulders, which signals maturity and dominance during territorial defense. These traits evolve under , as they correlate with mating success in resource-limited breeding colonies. Reproductive strategies in pinnipeds reinforce dimorphism through sex-specific adaptations tied to . Females employ delayed implantation, where the remains dormant in the for 3 to 4 months post-mating, allowing synchronized pupping with optimal environmental conditions despite variable conception timing. This mechanism supports female energy conservation during long foraging migrations. In contrast, males focus on defense, establishing and guarding groups of 10 to 100 females on beaches, often for up to 3 months while expending vast energy in combats that can last days. The resulting variance in —top males siring over 80% of pups—drives the of male-biased SSD. Recent studies highlight how environmental pressures modulate SSD and territoriality in pinnipeds. In California sea lions, increasing has intensified male-male competition, leading to accelerated growth in male body size and skull dimensions since the 1990s, as larger males better secure territories amid resource competition. This density-dependent exemplifies how ecological factors interact with mating systems to sustain dimorphism in dynamic marine environments.

In Primates

Sexual size dimorphism (SSD) in non-human primates varies widely, often reflecting mating systems and social structures. In species with polygynous systems, such as gorillas (Gorilla gorilla), males are substantially larger than females, with mature males weighing approximately twice as much, enabling dominance in harem defense and resource control. This male-biased SSD, ranging from 1.5 to 2 times female body mass in lowland gorillas, underscores intense male-male competition for reproductive access. Conversely, in monogamous callitrichids like marmosets (Callithrix spp.), SSD is minimal or absent, with females sometimes slightly heavier than males, aligning with cooperative breeding and reduced intrasexual rivalry. Facial and dental dimorphisms in non-human primates frequently serve social signaling roles. Male baboons (Papio spp.), for instance, possess significantly larger canine teeth than females, which grow to lengths of up to 4 cm and function in displays of dominance during agonistic encounters. These exaggerated canines correlate with higher social rank and mating success, highlighting pressures. In contrast, some female prosimians exhibit anogenital swellings during estrus, characterized by pronounced pinkness and around the genital region, which advertise and elicit male responses without equivalent male counterparts. Locomotor adaptations in arboreal primates like ( spp.) reveal subtle skeletal dimorphisms tailored to brachiation. Males display slightly broader shoulder girdles and elongated clavicles relative to females, facilitating powerful arm swings and suspensory locomotion through forest canopies, though overall SSD remains low due to pair-bonding. These features enhance efficiency in shared arboreal travel and territorial defense. Recent analyses of fossil evidence indicate that early hominins exhibited extreme SSD akin to gorillas, with male potentially 30% larger than females, suggesting harem-based social organizations driven by male competition. This pattern, revealed through postcranial metrics, implies that ancestral societies prioritized before shifts toward more egalitarian structures in later lineages.

In Humans

Sexual dimorphism in humans manifests prominently in morphological traits, with males typically exhibiting greater overall body size. On average, adult males are approximately 10-15% taller than females, a difference that emerges during due to sex-specific growth patterns. Males also possess broader shoulders, with biacromial width averaging about 11-14% greater than in females, contributing to a more V-shaped . In contrast, females display pelvic widening, where the birth canal and overall are wider to accommodate , resulting in a gynecoid pelvis shape that is distinctly larger in transverse dimensions compared to the form more common in males. Physiologically, sexual dimorphism is evident in muscle mass distribution, where males generally have about 40% more upper body relative to females, reflecting higher testosterone-driven . This disparity extends to aging processes; recent 2025 research indicates that muscle mass decline with age is substantially more pronounced in males than in females, potentially exacerbating and reducing physical function more rapidly in older men. Health implications of these dimorphisms include sex-biased disease susceptibilities, such as autoimmune disorders, which affect females disproportionately, accounting for around 80% of cases due to differences in immune regulation. structure also shows dimorphism, with the male being about 10% larger on average before volume correction, linked to variations in emotional processing and stress responses. Cultural and environmental factors, particularly and , have moderated sexual size dimorphism in modern humans, reducing the ratio to approximately 1.1:1 in well-nourished populations compared to higher ratios in resource-scarce historical societies. Improved protein availability and overall caloric intake have minimized growth disparities, highlighting how socioeconomic conditions influence the expression of underlying genetic dimorphisms.

Physiological Aspects

Immune Function Differences

Sexual dimorphism manifests in immune function through pronounced sex-based differences in response to pathogens and self-antigens, often favoring females with more robust defenses but increased autoimmunity risks. Females typically exhibit stronger humoral immunity, producing higher quantities and qualities of antibodies in response to infections and vaccinations compared to males. For instance, women generate up to twofold higher antibody titers following influenza vaccination, contributing to better protection against viral threats. This female-biased immunity is partly attributed to the dosage effect of the X chromosome, which harbors numerous immune-related genes; females possess two X chromosomes, leading to elevated expression of these genes despite X-inactivation mechanisms. In contrast, males often display vulnerabilities to due to relatively suppressed immune responses. Men experience higher rates of severe outcomes from respiratory viruses, such as , where male mortality and hospitalization rates exceed those of females by factors of 1.5 to 2, linked to weaker antiviral defenses. Testosterone plays a key immunosuppressive role in this dimorphism, inhibiting pro-inflammatory production and T-cell activation, thereby dampening overall immune vigilance in males. This hormonal effect is evident in studies showing that higher endogenous testosterone levels correlate with reduced responses to and increased to bacterial and pathogens. Sex differences also extend to autoimmunity, where females predominate at ratios up to 9:1 for conditions like systemic lupus erythematosus (SLE), driven by heightened B-cell activity and antibody production against self-tissues. Recent 2024 research highlights extragenetic factors, including incomplete X-chromosome inactivation and the regulatory RNA , which can trigger autoimmune responses in females by exposing X-linked autoantigens to the . These mechanisms exacerbate female risk beyond , influencing disease onset and progression across taxa. From an evolutionary standpoint, these immune dimorphisms represent trade-offs shaped by reproductive roles, with females evolving stronger immunity to safeguard during and against pathogens. This enhanced maternal defense comes at the cost of susceptibility, balancing investment in with survival pressures, as seen in comparative studies across vertebrates. In males, via testosterone may prioritize energy allocation toward over broad immune maintenance, reflecting divergent life-history strategies.

Cellular Level Dimorphisms

Sexual dimorphism manifests at the cellular level through differences in mitochondrial function, where often exhibit advantages in production and . Mitochondria in cells typically demonstrate superior intrinsic capacity compared to males, with higher rates of I- and I+II-linked in , independent of overall aerobic fitness levels. This sex-specific efficiency contributes to lower (ROS) production in females, reducing oxidative damage to (mtDNA) under conditions. Regarding mtDNA heteroplasmy—the coexistence of wild-type and mtDNA variants—maternal allows for stronger purifying selection in females, as they transmit mtDNA to offspring, potentially conferring advantages by mitigating the accumulation of deleterious mutations that disproportionately affect males. Sex-specific further underscores these differences, with female mitochondria showing greater reliance on oxidation and a higher proton leak, enhancing adaptability to metabolic stress. Protein expression profiles in cells reveal pronounced sex biases, particularly in skeletal muscle proteomes influenced by androgen receptor (AR) signaling. A 2023 study on skeletal muscle identified 189 proteins with sex-specific responses to , where 67% exhibited larger abundance increases in males, often mediated by AR pathways that promote anabolic processes like mitochondrial and the tricarboxylic acid (TCA) cycle. At baseline, 82 proteins differed between sexes, with nearly half more abundant in males, reflecting AR-driven dimorphisms in structural and metabolic proteins such as SIRT3 and MRPL41. These proteome variations highlight how hormonal influences, particularly androgens, shape cellular function differently across sexes, contributing to divergent metabolic efficiencies. Stem cell populations also display sex-dimorphic characteristics, notably in hematopoietic stem cells (HSCs), where males exhibit higher initial activity but accelerated decline with age. In mice, male HSCs undergo significant expansion and down-regulation of hematopoietic genes (e.g., Fzd1, ) earlier in compared to females, leading to a more rapid loss of function. This male-biased HSC activity correlates with increased susceptibility to age-related hematopoietic disorders, while female HSCs maintain steadier output, potentially linking to greater female through sustained immune reconstitution and reduced clonal hematopoiesis risks. Such differences arise from intrinsic effects and microenvironmental factors, independent of systemic hormones. Recent advances in 2025 research further illuminate sex-dimorphic aging at the cellular level in muscle cells, revealing greater functional decline in males. Analysis of data from over 478,000 participants aged 40–82 showed that age-related loss of arm muscle mass and strength is substantially steeper in males than females, with sexual dimorphism evident in accelerated trajectories. This male-specific decline involves heightened mitochondrial dysfunction and imbalances in muscle cells, exacerbating metabolic vulnerabilities compared to females. These findings emphasize the cellular basis for sex differences in aging , informing targeted interventions.

Reproductive Advantages

Sexual dimorphisms often provide males with advantages in , where the reproductive success of a male's ejaculate depends on its ability to outcompete rival within the female's reproductive tract. In , relative testis size is significantly larger in species with multimale breeding systems compared to those with single-male systems, enabling greater production to enhance fertilization probability under intense post-copulatory competition. For instance, chimpanzees exhibit testis sizes up to 3-4 times larger relative to body mass than , correlating with their promiscuous mating patterns and high levels of . This dimorphism in gonadal investment directly boosts male mating success by increasing the volume and quality of ejaculates, thereby improving offspring siring rates in competitive environments. Females in many species benefit from dimorphisms that optimize resource allocation to reproduction, often manifesting as larger body sizes or gametes to support higher fecundity and offspring viability. According to parental investment theory, the sex investing more in gamete production and care—typically females—evolves traits that maximize per-offspring quality and quantity, as the asymmetry in initial investment favors choosiness and resource commitment in females over multiple mating. In fish exhibiting female-biased sexual size dimorphism, such as many salmonids, larger females produce significantly more and larger eggs, which enhance larval survival and growth rates due to increased yolk reserves for early development. This advantage stems from the positive correlation between female body size and ovarian output, allowing for greater reproductive output per breeding season without compromising egg quality. Behavioral dimorphisms in sexually dimorphic species frequently include mate guarding by males, which secures paternity by preventing female remating with rivals and thus elevating fertilization success. In species with pronounced size differences, such as elephant seals, larger males use their body mass to monopolize harems and guard females during estrus, reducing extra-pair copulations and increasing the guarder's siring probability to over 80% in some colonies. Recent studies on insects, like the 2024 analysis of the pine sawyer beetle, demonstrate that sexual size dimorphism enhances male fertilization rates, as larger males deliver bigger ejaculates and engage in more effective guarding, leading to higher paternity shares in competitive mating scenarios. These behaviors are particularly pronounced in dimorphic taxa where male investment in guarding trades off against foraging but yields net reproductive gains through assured fertilization. Despite these benefits, sexual ornaments and associated dimorphisms impose trade-offs, notably increased predation risk that can offset mating advantages. In guppies, brightly colored male ornaments, evolved under for female attraction, make individuals significantly more susceptible to visual predators like pike cichlids, as demonstrated in experimental trials where ornate males suffered higher attack rates. These costs highlight how dimorphic traits, while boosting immediate , require compensatory mechanisms like to mitigate viability risks.

Evolution of Sexual Dimorphism

Theoretical Explanations

Sexual dimorphism in mammals primarily evolves through , a process distinct from where traits enhance mating success rather than survival. first proposed sexual selection as a mechanism driving differences between sexes, particularly in males, through two main forms: intrasexual selection, involving competition among individuals of the same sex (often males fighting for access to females), and intersexual selection, where one sex (typically females) chooses mates based on attractive traits. These processes often result in exaggerated male traits, such as larger body size or ornaments, to secure mating opportunities. Bateman's principle underpins much of this sexual selection theory, positing that due to —the difference in gamete size between males (small, numerous ) and s (large, limited eggs)—males exhibit greater variance in , leading to stronger selection pressures on male traits. This variance incentivizes male investment in competitive or display traits, amplifying dimorphism, while s face less intense selection for such features. A key extension is selection, where a genetic correlation between a for a male ornament and the ornament itself creates a self-reinforcing feedback loop, causing traits to evolve to extremes beyond survival optima. Natural selection counteracts or complements by imposing ecological pressures that favor different optima in each sex, such as reduced ornamentation in females to enhance efficiency and energy allocation to . For instance, in where females bear the primary burden, natural selection may constrain female body size or adornments to minimize energy costs during and . Recent analyses reinforce this interplay, showing that sexual size dimorphism in tetrapods, including mammals, arises from varying sex-specific selection on body size, where often drives male-biased dimorphism but modulates it based on environmental demands. Genetic constraints further shape dimorphism's evolution, as shared genetic architectures between sexes create correlations that limit independent divergence; high cross-sex genetic correlations hinder the breakdown of needed for pronounced differences. These constraints arise because autosomal genes influence both sexes, requiring sex-limited expression or modifiers to allow dimorphism to evolve despite opposing selection pressures.

Fossil Record and Ancient Examples

Evidence of sexual dimorphism in the fossil record provides insights into the evolutionary history of this trait among non-avian dinosaurs and early mammals, revealing patterns of size differences and ornamental structures that likely influenced reproductive behaviors. In theropod dinosaurs, sexual dimorphism has been documented through analyses of fossil assemblages from mass-mortality events, such as the Early Cretaceous Angeac-Charente bonebed in , where statistical comparisons of skeletal elements indicate distinct male and female morphs based on shape differences in bones. In ceratopsian dinosaurs, ornamental frills show positive , with larger individuals—presumed males—displaying exaggerated growth in frill length and width, suggesting for display purposes. A geometric morphometric analysis of andrewsi fossils from indicates positive allometry in frill growth supporting a socio-sexual signaling role, though evidence for sexual dimorphism in shape is not supported and differences are likely minimal. Among early mammals, Eocene primates exhibit clear canine dimorphism, marking some of the oldest evidence for this trait in the order . Specimens of Notharctus venticolus from the Early Eocene of show significant size differences in upper canines between presumed males and females, with males possessing larger, more robust canines indicative of intrasexual competition. Similarly, late Eocene anthropoids from , such as Catopithecus browni and Proteopithecus sylviae, display pronounced canine size disparities, suggesting the emergence of dimorphism linked to polygynous systems by around 40 million years ago. A 2025 study of and A. africanus fossils from eastern and reveals gorilla-like SSD, with male body sizes exceeding females by up to 50-70%, exceeding modern dimorphism levels and implying intense male-male . This , based on postcranial metrics from over 200 specimens, indicates that early hominins maintained high dimorphism for approximately 2 million years, from 3.9 to 1.9 million years ago. Paleoecological inferences from these dimorphic s suggest associations with specific mating systems, such as harem , where elevated SSD correlates with male defense of female groups. In rhinoceroses like Teleoceras, pronounced and body size dimorphism aligns with harem-forming behaviors observed in extant ungulates, indicating similar social structures in ancient ecosystems. For early pinnipeds and hominins, dimorphism patterns further support the transition to polygynous systems around 27-4 million years ago, driven by resource distribution and predation pressures. Despite these findings, significant gaps persist in the record of sexual dimorphism, particularly due to the rare preservation of soft tissues that could reveal coloration differences, such as iridescent feathers or scales used in display. estimates, calibrated against metazoan divergence, suggest that the genetic underpinnings of dimorphism may trace back over 100 million years to the origins of bilaterian animals, though reconciling these with sparse evidence remains challenging owing to rate heterogeneity in substitution models.

References

  1. [1]
    Sexual Dimorphism
    Sexual dimorphism is the systematic difference in form between individuals of different sex in the same species. Examples include size, color, and body parts.
  2. [2]
    Sexual dimorphism - Latest research and news - Nature
    Sexual dimorphism consists of phenotypic distinctions between one sex and another. These distinctions can include physiological and behavioural differences.Missing: biology | Show results with:biology
  3. [3]
    [PDF] SEXUAL DIMORPHISM IN MAMMALS - Smithsonian Institution
    Sexual dimorphism in mammals ranges from females being larger to males being much larger, often in size, and is most common in size.
  4. [4]
    Sexual Dimorphism: Why the Sexes Are (and Are Not) Different
    differences in male and female physiology, morphology or ...
  5. [5]
    Sexual Dimorphism in the Age of Genomics: How, When, Where - NIH
    Sep 6, 2019 · Abstract. In mammals, sex chromosomes start to program autosomal gene expression and epigenetic patterns very soon after fertilization.
  6. [6]
    11.1 Understanding Sexual Reproduction and Sexual Dimorphism
    Nov 13, 2024 · This phenomenon, known as sexual dimorphism, is prevalent throughout the animal kingdom and often extends beyond primary sex traits (i.e., ...
  7. [7]
    Darwin, C. R. 1871. The descent of man, and selection in relation to ...
    Aug 9, 2025 · RECORD: Darwin, C. R. 1871. The descent of man, and selection in relation to sex. London: John Murray. Volume 1. 1st edition.
  8. [8]
    Sexual dimorphism in flowering plants - Oxford Academic
    Nov 25, 2012 · When dioecy evolves from hermaphroditism, females and males are expected to diverge and specialize to their respective unisexual conditions.Abstract · Introduction · Ecology of sexual dimorphism · Evolution and genetics of...
  9. [9]
    Sexual selection and sexual size dimorphism in animals - Journals
    Sep 15, 2021 · Sexual selection is often considered as a critical evolutionary force promoting sexual size dimorphism (SSD) in animals.
  10. [10]
    Sexual selection in fungi - Nieuwenhuis - 2012 - Wiley Online Library
    Nov 16, 2012 · Even though fungi do not have separate sexes, most filamentous fungi mate in a hermaphroditic fashion, with distinct sex roles, that is, ...
  11. [11]
    Sexual Selection | Learn Science at Scitable - Nature
    Sexual selection can operate both intra- and inter-sexually, either sequentially or simultaneously (Table 1). During intrasexual selection, members of the same ...
  12. [12]
    http://www.italian-journal-of-mammalogy.it/pdf-175386-96953?filename=Evolution%20of%20sexual%20size.pdf
  13. [13]
    Sexual Dimorphism and Sexual Selection: A Unified Economic ... - NIH
    ... defined as the ratio of active males to fertilizable females. ... In this paper, we provide a unified approach to explain sexual dimorphism, intrasexual ...
  14. [14]
    Sexual Body Size Dimorphism
    Gorillas, chimpanzees, bonobos and orangutans all exhibit sexual body size dimorphism, but to different extents and for different ontogenetic reasons. Lowland ...
  15. [15]
    Sexual selection explains Rensch's rule of size dimorphism in ... - NIH
    First, male-biased dimorphism increases with male size because directional sexual selection favors large males, and these males typically exhibit nonagile ...
  16. [16]
    Sexual Dimorphism and Sexual Selection
    Examples include breasts, showy tails and headpieces, bright coloration, and crazier traits like the length of the eye-stalks in stalk-eyed flies (see image ...
  17. [17]
    Sexual segregation in marine fish, reptiles, birds and ... - PubMed
    Here we discuss the behavioural patterns of sexual segregation among marine fish, reptile, bird and mammal species.Missing: dichromatism | Show results with:dichromatism
  18. [18]
    Butterfly dichromatism primarily evolved via Darwin's, not Wallace's ...
    Oct 23, 2020 · Nuptial coloration in African cichlid fishes is likely the result of strong sexual ... A genetic mechanism for sexual dichromatism in birds.
  19. [19]
    The Handicap Principle: how an erroneous hypothesis became a ...
    Oct 23, 2019 · Zahavi (1975) argued that sexual signals, such as the tail plumes of peacocks, are 'excessive' (p. 211), implying that they are larger and ...
  20. [20]
    Sexual Dimorphism in Vocal Control Areas of the Songbird Brain
    In canaries and zebra finches, three vocal control areas in the brain are strikingly larger in males than in females.
  21. [21]
    [PDF] Male Scent Gland Signals Mating Status in Greater Spear-Nosed ...
    The male greater spear-nosed bat, Phyllostomus hastatus, possesses a sexually dimorphic gland on the chest that produces an odoriferous secretion.
  22. [22]
    XY Sex-Determination System - an overview | ScienceDirect Topics
    The XX/XY sex-determination system is the most common designation in mammals whereby SRY on the Y-chromosome mainly acts to determine sex.Genetic Sex Determination · Comparative Reproduction · Fish Sex Determining Genes
  23. [23]
    Sex determination: The X, Y, Z's of sex chromosomes
    Jul 15, 2021 · The ZW system is opposite of the XY system in that the mother's sex chromosome determines the genetic sex of the offspring. Just as the ...Missing: Hymenoptera | Show results with:Hymenoptera
  24. [24]
    Sex Determination in the Hymenoptera - Annual Reviews
    Jan 7, 2008 · The dominant and ancestral mode of sex determination in the Hymenoptera is arrhenotokous parthenogenesis, in which diploid females develop from fertilized eggs.Missing: paper | Show results with:paper
  25. [25]
    Sry: the master switch in mammalian sex determination | Development
    Dec 1, 2010 · SRY, the mammalian Y-chromosomal testis-determining gene, induces male sex determination. Recent studies in mice reveal that the major role of SRY is to ...
  26. [26]
    Primary sex determination in birds depends on DMRT1 dosage, but ...
    Our analysis shows that DMRT1 is the key sex determination switch in birds and that it is essential for testis development.
  27. [27]
    Dosage Compensation in Mammals - PMC - NIH
    Dosage compensation in mammals balances X-linked gene expression by silencing one X in females and up-regulating the active X in both sexes.
  28. [28]
    Genetic and epigenetic underpinnings of sex differences in the brain ...
    This chapter reviews emerging evidence that shows how epigenetic mechanisms including DNA methylation, histone modifications, and chromatin remodeling, and non ...
  29. [29]
    Sexual size dimorphism in mammals is associated with changes in ...
    Jul 24, 2024 · Published: 24 July 2024. Sexual size dimorphism in mammals is associated with changes in the size of gene families related to brain development.
  30. [30]
    Adult body mass is heritable, positively genetically correlated and ...
    Feb 23, 2024 · In line with our predictions, we report that body mass was a moderately heritable trait in both sexes and was positively genetically correlated ...
  31. [31]
    Sex-stratified Genome-wide Association Studies ... - PubMed Central
    Our results demonstrate the value of sex-specific GWAS to unravel the sexually dimorphic genetic underpinning of complex traits. Author Summary. Men and women ...
  32. [32]
    X and Y gene dosage effects are primary contributors to human ...
    May 19, 2025 · We conclude that differential expression of height-related pseudoautosomal genes on the X and Y chromosomes contributes to sexual dimorphism for stature.
  33. [33]
    Sexual dimorphism through androgen signaling - NIH
    Jul 27, 2022 · Sexual dimorphism, driven by androgen signaling, is seen in body mass, hair, reproductive structures, and muscle development, with differences ...
  34. [34]
    Development of sexual dimorphism of skeletal muscles through the ...
    Feb 27, 2024 · The size, proliferation, and glucocorticoid synthesis characteristics are all female biased, and sexual dimorphism is established by androgen.
  35. [35]
    Androgens and estrogens in skeletal sexual dimorphism - PMC
    77 Overall, we can conclude that androgens (or AR mediated androgen action) are necessary for musculoskeletal sexual dimorphism in development and ageing, ...
  36. [36]
    Sexual Dimorphism in the Musculoskeletal System: Sex Hormones ...
    Sep 1, 2024 · In females, estrogen preserves bone mass, suppresses bone turnover, and maintains balanced rates of bone formation and bone resorption while ...
  37. [37]
    Estrogens and Androgens in Skeletal Physiology and Pathophysiology
    Nov 2, 2016 · Estrogens and androgens influence the growth and maintenance of the mammalian skeleton and are responsible for its sexual dimorphism.
  38. [38]
    Sexual Differentiation - Endotext - NCBI Bookshelf - NIH
    Jul 24, 2025 · No sexual difference can be observed in the gonads until the 6th week of embryonic life in humans and 11.5 days post-coitum (dpc) in mice.
  39. [39]
    The organizational-activational hypothesis as the foundation for a ...
    Although organizational and activational effects of gonadal hormones also explain some sex differences in the MS-like model (Voskuhl and Palaszynski, 2001 ...
  40. [40]
    Activational vs. organizational effects of sex steroids and their role in ...
    Many biologists have therefore described the effects of sex steroid action on reproductive behavior as both “activational” and “organizational,” respectively.
  41. [41]
    Sexual Dimorphism in Sex Hormone Metabolism in Human Skeletal ...
    Oct 5, 2024 · Muscle tissue is an important target of sex steroids, and particularly, testosterone plays essential roles in muscle cell metabolism.Missing: mass | Show results with:mass
  42. [42]
    Pituitary growth hormone network responses are sexually dimorphic ...
    Thus, the pituitary gland contributes to the sexually dimorphic patterns of GH secretion that play an important role in differences in growth and metabolism ...
  43. [43]
    Sex-specific responses to growth hormone and luteinizing hormone ...
    Across the vertebrate lineage, sexual dimorphism in body size is a common phenomenon that results from trade-offs between growth and reproduction.
  44. [44]
    Endocrine Disruptor Impacts on Fish From Chile - Frontiers
    Mar 24, 2021 · Industrial wastewaters and urban discharges contain complex mixtures of chemicals capable of impacting reproductive performance in freshwater fish.Abstract · Evidence of Pulp Mill Effluent... · Evidence of Endocrine... · Discussion
  45. [45]
    Impacts of endocrine disrupting chemicals on reproduction in wildlife ...
    May 15, 2022 · These fish exhibited altered reproductive development including reductions in gonad size, delayed sexual maturity, and reduced expression of ...
  46. [46]
    Experimental Approaches for Characterizing the Endocrine ...
    In fish, EDCs are known to affect fertility, sexual maturation, somatic growth, stress responses and induce cellular damage, largely through alterations in the ...
  47. [47]
    The relative and absolute frequencies of angiosperm sexual systems
    Oct 1, 2014 · 5–6% of all angiosperm species are dioecious, resulting from 871 to 5000 independent origins of dioecy ; 210 (1.4% of 14559) genera have ...Abstract · MATERIALS AND METHODS · RESULTS
  48. [48]
    Sexual dimorphism in the dioecious willow Salix purpurea
    Aug 18, 2021 · This study aims to examine sexual dimorphism for 26 traits in three populations of Salix purpurea (a diversity panel and F 1 and F 2 populations)
  49. [49]
    floral dimorphism and attractiveness to pollinators in a dioecious plant
    Aug 6, 2009 · The likely reason for this is the significantly higher emission of floral scent per flower in male versus female flowers.
  50. [50]
    Sniffing out patterns of sexual dimorphism in floral scent - 2009
    Sep 18, 2009 · Likewise, if nectar is scented then volatile differences will reflect nectar production differences between the sex morphs. In addition, I ...Hypotheses · Sexual Selection (table 2... · Observed Patterns
  51. [51]
    [PDF] Evolution of plant sex and molecular mechanisms underlying plants ...
    Jan 13, 2023 · DNA methylation is involved in sexual differentiation and sex chromosome evolution in the dioecious plant garden asparagus. Horticulture ...<|control11|><|separator|>
  52. [52]
    DNA methylation is involved in sexual differentiation and sex ...
    Sep 1, 2021 · Garden asparagus (Asparagus officinalis) is a dioecious plant species, and its sex is controlled by X and Y sex chromosomes. It has a 1 C genome ...
  53. [53]
    Variation in sexual dimorphism in a wind‐pollinated plant
    Reversal of height dimorphism promotes pollen and seed dispersal in a wind‐pollinated dioecious plant. Biology Letters 8: 245–248. [DOI] [PMC free article] ...
  54. [54]
    Plasticity in Sexual Dimorphism Enhances Adaptation of Dioecious ...
    Jul 3, 2019 · These findings illustrated considerable plasticity in the degree of sexual dimorphism in a variety of vegetative and reproductive traits across ...
  55. [55]
    [PDF] a gender-specific study of Acer negundo (Boxelder)
    When water stress was imposed, females exhibited greater reductions in photosynthetic rate and higher stomatal limitations to photosynthesis than males. 3. For ...
  56. [56]
    Roots, shoots and reproduction: sexual dimorphism in size ... - NIH
    Females tend to be smaller than males in woody dioecious plant species, but they tend to be larger in herbs. The smaller size of females in woody species ...
  57. [57]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC2605799/
  58. [58]
    [PDF] Haplodiploidy and the Evolution of the Social Insects Robert L. Trivers
    Jun 23, 2007 · Even wingless, workerlike fe- male ants are fertilized in species lacking winged queens (36,37), and in some primi- tively eusocial bees a ...
  59. [59]
    The function and evolution of a genetic switch controlling sexually ...
    Jan 28, 2023 · The sizes of the dorsal lens facets in honeybees are extremely sexually dimorphic and contribute to the overall sex-specific size difference of ...
  60. [60]
    Sexual size dimorphism and male reproductive traits vary across ...
    Sep 16, 2022 · In beetles, only 9% of the reported species exhibit male-biased SSD while 72% exhibit female-biased SSD (Stillwell et al., 2010). More ...
  61. [61]
    Costly sexual dimorphism in Cyclommatus metallifer stag beetles
    May 19, 2014 · Male stag beetles bear one of the most extreme examples of male weaponry: their mandibles can be almost as long as their own body. We question ...
  62. [62]
    The Tra/Dsx-JHBP axis controls female-specific gene expression ...
    Aug 5, 2025 · The finding of Tra/Dsx-JHBP axis significantly advanced understanding of sexual dimorphism and the adaptation of oviposition behavior in insects ...
  63. [63]
    Two Forms of Sexual Dimorphism in Gene Expression in Drosophila ...
    We examine two forms of sexual dimorphism in gene expression in Drosophila melanogaster: 1) sex-biased gene expression (SBGE) in which the sexes ...
  64. [64]
    Investment in sensory structures, testis size, and wing coloration in ...
    Mar 17, 2015 · The antennae of some species of moth are strikingly sexually dimorphic, with males possessing large feathery bipectinate antennae in comparison ...
  65. [65]
    Sexual Size Dimorphism: Evolution and Perils of Extreme ...
    Jan 7, 2020 · Sexual size dimorphism is one of the most striking animal traits, and among terrestrial animals, it is most extreme in certain spider lineages.
  66. [66]
    The phylogenetic basis of sexual size dimorphism in orb-weaving ...
    In orb-weaving spiders, far more taxa are sexually dimorphic as a result of female size increase (22 genera) than as a result of male size decrease (two genera) ...
  67. [67]
    Gigantism and Cannibalism in Female Orb-weaver Spiders
    Oct 25, 2016 · In biology, when one sex is differently sized than the other within the same species it is called sexual size dimorphism, or SSD.
  68. [68]
    Sexual Size Dimorphism in Spiders - Dr. Boris Zakharov - Ad Astra
    The most spectacular cases of sexual size dimorphism occur in the orb-weaving spiders, where dwarf male can be 10 times smaller and 100 times lighter than ...
  69. [69]
    REPEATED EVOLUTION OF MALE SACRIFICE BEHAVIOR IN ...
    May 29, 2007 · According to sexual cannibalism theory, male complicity in terminal mating can be adaptive when the male's future reproductive value is low ...
  70. [70]
    Sexual cannibalism as a manifestation of sexual conflict. - Abstract
    Sexual cannibalism can be a male strategy to maximize paternity and a female strategy to prevent paternity monopolization by any or a particular male.
  71. [71]
    Maydianne Andrade | Scholarly & creative works - Discover Research
    In two species of widow spiders (genus Latrodectus), males trigger sexual cannibalism by “somersaulting” into the fangs of the female after copulatory coupling ...
  72. [72]
    [PDF] Spider Genitalia - Smithsonian Institution
    May 4, 2010 · The structures with which male spiders transfer sperm to females are unique among all animals in several respects.Missing: epigynes | Show results with:epigynes
  73. [73]
    Coevolution of female and male genital components to avoid genital ...
    Aug 17, 2016 · Internal dimensions of female genitalia evolve independently of female body size in nephilid spiders, and similarly, male intromittent genital size evolves ...Missing: epigynes | Show results with:epigynes
  74. [74]
    Condition‐Dependent Female Aggression and Its Effects on Mating ...
    Oct 22, 2024 · Pre-copulatory sexual cannibalism is an extreme form of aggression toward potential mates. In this study, we examined condition-dependent ...
  75. [75]
    (PDF) Ethology Condition-Dependent Female Aggression and Its ...
    Oct 24, 2024 · In addition, food deprived female spiders exhibited higher proportions of aggressive behaviors and pre-copulatory sexual cannibalism, and lower ...
  76. [76]
    Reduced sexual size dimorphism in a pipefish population where ...
    Nov 1, 2019 · We look into an unusual population (Baltic Sea) of the broadnosed pipefish, Syngnathus typhle, where males do not seem to select females based on size.
  77. [77]
    Condition-dependent expression of pre- and postcopulatory sexual ...
    In this polyandrous livebearing fish, males and females exhibit marked sexual dimorphism, with males exhibiting complex color patterns composed of orange ( ...
  78. [78]
    Female preference for swords in Xiphophorus helleri reflects a bias ...
    Male swordtails (Xiphophorus) were cited by Darwin (6) as an example of extreme sexual ornamentation. The lower rays of the caudal fin are elongated into a ...
  79. [79]
    Selection for increased male size predicts variation in sexual size ...
    Jan 15, 2020 · Variation in the degree of sexual size dimorphism (SSD) among taxa is generally considered to arise from differences in the relative ...
  80. [80]
    Warmer waters masculinize wild populations of a fish with ... - Nature
    Apr 25, 2019 · Warm and cold temperatures masculinize fish with mid-range conditions producing at most 50% females. Due to sexually dimorphic growth, southern ...
  81. [81]
    Sexual dimorphic expression of DMRT1 and Sox9a during gonadal ...
    Dec 19, 2007 · The morphological sexual dimorphism during gonadal differentiation consisted of changes in germ cell number and histogenesis (Figs. 1, 2).
  82. [82]
    Sex Change in Clownfish: Molecular Insights from Transcriptome ...
    Oct 17, 2016 · It has been suggested that sequential hermaphroditism in reef habitats improves adaptation, increases survival rates and enhances reproduction.
  83. [83]
    Clasper - an overview | ScienceDirect Topics
    Claspers are defined as scroll-shaped, heavily calcified appendages found in adult male sharks, protruding from the pelvic fins and used for reproductive ...
  84. [84]
    Repeatability in nest construction by male three-spined sticklebacks
    We test this hypothesis in male three-spined sticklebacks, Gasterosteus aculeatus, by measuring the repeatability of nest characteristics. We encouraged males, ...Missing: dimorphism | Show results with:dimorphism
  85. [85]
    Increased offspring provisioning by large female fish and ...
    Oct 3, 2023 · (a) A weighted female total length versus egg diameter trendline (red) supports that larger females produce larger eggs.
  86. [86]
    Identification and functional analysis of Dmrt1 gene and the SoxE ...
    This study indicates that Dmrt1 and SoxE are indispensable for testicular differentiation, and SoxE might play a functional role during ovary differentiation ...
  87. [87]
    Sexual dichromatism in frogs: natural selection, sexual selection and ...
    Sep 19, 2012 · In frogs and toads (anurans), the most common form of sexual dimorphism is body size (more than 90% of species), and these differences are ...
  88. [88]
    Genomic and transcriptomic insights into molecular basis of sexually ...
    Dec 5, 2019 · Findings from amphibian endocrine research have revealed that male-biased structures such as enlarged flexor muscles and nuptial thumb pads are ...
  89. [89]
    Examining the relationship between sexual dimorphism in skin ... - NIH
    Sexual dimorphism in body size is pervasive among amphibians (e.g. De Lisle & Rowe, 2015), yet previous studies of skin anatomy have not corrected for these ...
  90. [90]
    Generating Sexually Differentiated Vocal Patterns: Laryngeal Nerve ...
    Male and female African clawed frogs (Xenopus laevis) produce sexually dimorphic vocalizations; for males these include advertisement, amplectant, and ...
  91. [91]
    Vocalizations of female frogs contain nonlinear characteristics and ...
    Mar 30, 2017 · Anuran vocalization is sexually dimorphic, with males doing the bulk of vocalizing. Female vocalization is rare and has been observed in a ...<|control11|><|separator|>
  92. [92]
    Auditory perception exhibits sexual dimorphism and left ...
    In this study we investigated whether auditory perception exhibits sexual dimorphism in Xenopus laevis. To do this we measured event-related potentials (ERPs) ...
  93. [93]
    Transcriptome analysis reveals the genetic basis underlying the ...
    Dec 30, 2024 · Nuptial pads, a typical sexually dimorphic trait in anurans, are located on the first digit of the male forelimb in Rana chensinensis and ...
  94. [94]
    Sexual size dimorphism in caecilian amphibians - ScienceDirect.com
    A review of the present SSD data for caecilians shows that many species are monomorphic for body size but show dimorphism in head size, while other species ...
  95. [95]
    Rensch's rule and sexual dimorphism in salamanders: patterns and ...
    Apr 17, 2014 · Rensch's rule and sexual dimorphism in salamanders: patterns and potential processes. E. Colleoni,. Corresponding Author. E. Colleoni. orcid.org ...
  96. [96]
    Latitudinal variation in sexual dimorphism in life‐history traits of a ...
    Dec 20, 2016 · One prominent macroecological pattern is the Rensch's rule (Rensch, 1950), which states that the magnitude of SSD tends to increase with ...
  97. [97]
    Sexual dimorphism in lizard body shape: the roles of ... - PubMed
    Sexual dimorphism is widespread in lizards, with the most consistently dimorphic traits being head size (males have larger heads) and trunk length.
  98. [98]
    A Phylogenetic Analysis of Sexual Size Dimorphism in Turtles
    Mar 1, 2009 · Phylogenetic analysis of SSD indices indicates that the basal state of SSD in turtles is female-biased (Fig. 1). However, male-biased or ...<|separator|>
  99. [99]
    Female dewlap ornaments are evolutionarily labile and associated ...
    Nov 16, 2022 · We study the Anolis lizard dewlap, a trait extensively studied as a male secondary sexual characteristic but present in females of several species.
  100. [100]
    Sexual dimorphism in dinosaurs - PMC - NIH
    Jun 14, 2023 · Studying fossils from a mass-mortality event reveals evidence for sexual dimorphism and, unusually, equal numbers of males and females in a herd of dinosaurs.
  101. [101]
    Bizarre structures in dinosaurs: species recognition or sexual ...
    Oct 8, 2010 · Among the best documented examples of exaggerated structures within Dinosauria are the crests of hadrosaurs (Dodson, 1975; Evans, 2010). A ...
  102. [102]
    Did male and female dinosaurs differ? A new statistical technique is ...
    Feb 1, 2022 · My colleagues and I compared sexual dimorphism in body size between three different dinosaurs: the duck-billed Maiasaura, Tyrannosaurus rex and ...<|separator|>
  103. [103]
    How an Asexual Lizard Procreates Alone
    Nov 15, 2024 · Without females, lizards in the Aspidoscelis genus, like this New Mexico Whiptail (Aspidoscelis neomexicana), reproduce asexually.
  104. [104]
    An unexpectedly long history of sexual selection in birds-of-paradise
    Examples of plumage diversity and sexual dimorphism in birds-of-paradise. Lower left male and female of the monogamous Manucodia keraudrenii, lower right ...
  105. [105]
    An unexpectedly long history of sexual selection in birds-of-paradise
    Sep 16, 2009 · The degree of sexual dimorphism found in the majority of species of birds-of-paradise (cryptically coloured females while males have spectacular ...
  106. [106]
    Factors causing sex differences in birds - PMC - NIH
    In birds, genes on the Z chromosome are not well dosage compensated, so that most Z genes are expressed higher in ZZ male cells than in ZW female cells. The sex ...
  107. [107]
    Sex-linked genomic variation and its relationship to avian plumage ...
    Sep 16, 2015 · Sexual dichromatism is the tendency for sexes to differ in color pattern and represents a striking form of within-species morphological ...
  108. [108]
    Why are most female raptors larger than males? | Discover Wildlife
    Oct 10, 2024 · The extent of the size difference between female raptors and male raptors, known as reversed size dimorphism, varies between species.
  109. [109]
    Why Are Female Raptors Bigger Than Males? Understanding ...
    Jul 31, 2025 · Another hypothesis posits that size differences could help reduce food competition between the sexes, allowing males and females to specialize ...
  110. [110]
    external appearance, ageing, sexing - Hummingbird
    Unlike most animal species, in RTHUs adult females are typically about 15-25% LARGER than adult males. (There are still "big" males and "small" females, however ...
  111. [111]
    Female vs. Male Hummingbird: What Are the Differences?
    Oct 23, 2025 · Female hummingbirds tend to be slightly larger than males, a size differential that is necessary to manage the demands of producing eggs ...
  112. [112]
    macroevolution of sexual size dimorphism in birds - Oxford Academic
    Mar 19, 2024 · Sexual size dimorphism was measured according to the size dimorphism index (SDI) of Lovich and Gibbons (1992), which is calculated as the ratio ...
  113. [113]
    Hormonal basis of sexual dimorphism in birds: implications for new ...
    In birds, however, masculinity has dual origins. Male-type behaviour and morphology, such as spurs and wattles, are usually testosterone-dependent.
  114. [114]
    https://digitalcommons.usf.edu/cgi/viewcontent.cgi?article=21463&context=auk
  115. [115]
    Sexual Dimorphism and Population Differences in Structural ...
    Sex was determined by the presence or absence of a brood patch, which develops in all females during the breeding season, but not in males ([1]; pers. obs ...Missing: combs roosters
  116. [116]
    [PDF] Reversed Sexual Size Dimorphism: Effect on Resource Defense ...
    foraging strategies of sexes of birds in which males are larger than females to examine the role of body size in determining sexual foraging strategies.
  117. [117]
    Migration and the evolution of sexual dichromatism - NIH
    We found that the presence of migration and migration distance were both positively correlated with sexual dichromatism, but models including breeding latitude ...
  118. [118]
    (PDF) Migration and the evolution of sexual dichromatism
    We found that the presence of migration and migration distance were both positively correlated with sexual dichromatism, but models including breeding latitude ...
  119. [119]
    The impact of habitat and migration on plumage colour in Cardinalidae
    Oct 20, 2023 · We also find that migration, long heralded as a driver of sexual dichromatism, is correlated with reduced plumage complexity in females, but not ...
  120. [120]
    https://doi.org/10.4061/2011/423938
  121. [121]
    https://doi.org/10.1038/s41467-023-43592-6
  122. [122]
    https://www.nature.com/articles/s41467-024-45739-5
  123. [123]
    https://besjournals.onlinelibrary.wiley.com/doi/full/10.1111/1365-2435.13004
  124. [124]
    New estimates indicate that males are not larger than females in ...
    Mar 12, 2024 · Sexual size dimorphism has motivated a large body of research on mammalian mating strategies and sexual selection.
  125. [125]
    The evolution of male‐biased sexual size dimorphism is associated ...
    Oct 13, 2017 · In insects, females are generally larger than males due to a strong size–fecundity relationship (Honek, 1993). However, despite being rare, male ...Missing: ovipositors | Show results with:ovipositors
  126. [126]
    Patterns of secondary sexual size dimorphism in New World Myotis ...
    Aug 6, 2015 · For bats, when secondary sexual dimorphism is significant, females typically are larger than males. Moreover, in mammals, variation in the ...
  127. [127]
    The Lion's Mane | American Scientist
    Figure 4. Like other sexually selected traits, the lion mane is sexually dimorphic, begins to develop at puberty and is highly variable. The mane of a male ...
  128. [128]
    Mammalian Pheromones - PMC - NIH
    The male mouse pheromone ESP1 enhances female sexual receptive behaviour through a specific vomeronasal receptor. Nature. 2010;466:118–22. doi: 10.1038 ...
  129. [129]
    Pheromones and Mammalian Behavior - NCBI - NIH
    Most species of carnivora have anal glands, including ferrets, which produce sex-specific volatiles that could function as pheromones (Zhang et al. 2005) ...INTRODUCTION · PHEROMONAL DETECTION · PHEROMONAL EFFECTS ON...
  130. [130]
    Color vision diversity and significance in primates inferred from ...
    In this system, all males are dichromatic but females are either dichromatic or trichromatic (“allelic” or “polymorphic” trichromacy). In catarrhine primates ...
  131. [131]
    Olfactory regulation of maternal behavior in mammals - PubMed
    In mammals, olfactory cues are extensively used in many aspects of maternal care to ensure the coordination of mother-infant interactions and consequently ...
  132. [132]
    Quantifying maternal investment in mammals using allometry - Nature
    Apr 18, 2024 · Since, in mammals, the maternal investment should be related to the body mass of the female specifically, we used a subset of the data for which ...
  133. [133]
    Reproductive and resource benefits to large female body size in a ...
    As dimorphism can vary with age in precocial breeding species, we compared females during their first reproduction and during a subsequent breeding attempt.
  134. [134]
    Body condition influences ontogeny of foraging behavior in juvenile ...
    Adult males were not used because they are difficult to equip due to their large size (up to 3,700 kg whereas females only weight between 400 and 800 kg, ...
  135. [135]
    Northern Elephant Seal (U.S. National Park Service)
    May 21, 2021 · Adult males may grow to over 13 feet in length and weigh up to 5,000 pounds while females are smaller, growing up to 10 feet and weighing up to ...
  136. [136]
    Southern elephant seal - Mirounga leonina - OBIS-SEAMAP
    Adult females are similar in size and weight to northern elephant seal females weighing 350-600 kg with exceptionally large females reaching 800 kg. Newborn ...
  137. [137]
    structure, ontogeny, and function of the elephant seal proboscis
    The proboscis of male elephant seals (Mirounga Gray, 1827) has been suggested as an example of a secondary sexual trait since Darwin.
  138. [138]
    Incredible Elephant Seals, Part 1 | Scientific American
    Jun 3, 2017 · The canines are sexually dimorphic, being larger in males. Elephant seals undergo what's known as annual catastrophic moult; the short pelt ...<|control11|><|separator|>
  139. [139]
    [PDF] Sexual Dimorphism - Smithsonian Institution
    In otariids, males have thick necks and massive chests that tend to be covered by a dense mane of hair. The noses of males are sometimes bizarrely modified. For ...
  140. [140]
    Disentangling the contribution of sexual selection and ecology to the ...
    The positive relationship between sexual size dimorphism (SSD) and harem size across pinnipeds is often cited as a textbook example of sexual selection.Missing: defense | Show results with:defense
  141. [141]
    Reproductive biology of seals
    Enders et al. (1946) were the first to report embryonic diapause, or delayed implantation, in Northern fur seals, and later the same phenomenon was.<|control11|><|separator|>
  142. [142]
    DISENTANGLING THE CONTRIBUTION OF SEXUAL SELECTION ...
    Jan 29, 2014 · The positive relationship between sexual size dimorphism (SSD) and harem size across pinnipeds is often cited as a textbook example of ...Missing: defense | Show results with:defense
  143. [143]
    The evolution of reproductive systems in pinnipeds - Oxford Academic
    Their mating system has been characterized as extreme polygyny, based on observations showing that a few males monopolize most of the matings (Le Boeuf, 1991).
  144. [144]
    Unexpected decadal density-dependent shifts in California sea lion ...
    May 22, 2023 · Increased male body size is compatible with an intensification of density-dependent sexual selection for larger and more competitive individuals ...<|control11|><|separator|>
  145. [145]
    Influence of male morphology on male mating status and behavior ...
    The western lowland gorilla (Gorilla gorilla gorilla) is one of the most sexually dimorphic primate species. Mature males are twice the size of females and ...
  146. [146]
    Sexual Body Size Dimorphism
    Lowland gorillas show the greatest dimorphism, having a male/female bodyweight ratio of 2.37. Orangutans also show large dimorphism (male/female ratio = 2.23), ...
  147. [147]
    Callithrix pygmaea (pygmy marmoset) - Animal Diversity Web
    Though pygmy marmosets are not considered sexually dimorphic, females may be slightly heavier than males. Longer hair around the face and neck gives C ...
  148. [148]
    Canine Length in Wild Male Baboons: Maturation, Aging and Social ...
    May 7, 2015 · Many primate species show high sexual dimorphism in the canine teeth, with males possessing larger canines than females [1–2]. Although ...
  149. [149]
    Observations on the Evolution and Behavioral Significance of ...
    D.A. Goldfoot et al. Lack of effect of vaginal lavages and aliphatic acids upon ejaculatory responses in rhesus monkeys. Horm. Behav.
  150. [150]
    Functional anatomy of the gibbon forelimb: adaptations to a ... - NIH
    Gibbons have shoulder flexors, extensors, rotator muscles and elbow flexors ... Gibbons and brachiation. In: Rumbaugh DM, editor. Gibbon and Siamang: A ...Missing: dimorphism | Show results with:dimorphism
  151. [151]
    https://www.healthline.com/health/average-shoulder-width
  152. [152]
    A meta-analysis of the association between male dimorphism ... - eLife
    Feb 18, 2022 · The development of these masculine traits in men is influenced by exposure to androgens, particularly testosterone.
  153. [153]
    Average Shoulder Width and How to Measure Yours - Healthline
    Oct 27, 2018 · Though it varies greatly, the United States average shoulder width is at least 16 inches (41 cm) for men and 14 inches (36 cm) for women.Average shoulder width · to 1994 · Forearm width · Measuring your shoulders<|separator|>
  154. [154]
    Allometry and Sexual Dimorphism in the Human Pelvis - Fischer
    Mar 15, 2017 · Pelvic sexual dimorphism is linked to obstetric needs, with females having a wider canal. Shape differs, but overall size is similar, and ...
  155. [155]
    Skeletal muscle mass and distribution in 468 men and women aged ...
    21.0 kg) and relative to body mass (38.4 vs. 30.6%). The gender differences were greater in the upper (40%) than lower (33%) body (P < 0.01).
  156. [156]
    Sexual dimorphism in human muscle ageing - medRxiv
    Feb 25, 2025 · While there was a modest sex difference in age-related strength decline, muscle mass loss was considerably more pronounced in males, both in ...
  157. [157]
    Why autoimmune disease is more common in women - Nature
    Feb 1, 2024 · Women account for around 80% of all cases of autoimmune disease, a category that includes conditions such as lupus and rheumatoid arthritis.
  158. [158]
    Meta-analysis reveals a lack of sexual dimorphism in ... - PubMed
    Feb 15, 2017 · We found that uncorrected amygdala volume is about 10% larger in males, with pooled sex difference effect sizes of g=0.581 for right amygdala.
  159. [159]
    Height and sexual dimorphism of stature among human societies
    The study found that greater male height is associated with polygynous marriage, and dietary factors can influence the degree of sexual dimorphism in height.Missing: reduced 1.1:1
  160. [160]
    Height and sexual dimorphism of stature among human societies
    Aug 17, 2024 · While in every known society females are on the average shorter than males, societies do vary in the mean male height to mean female height ...
  161. [161]
    Biological sex affects vaccine efficacy and protection against ... - PNAS
    Nov 19, 2018 · Females produce virus-specific antibodies that are of greater quantity and quality than their male counterparts, which appears to be mediated by ...
  162. [162]
    Mechanisms underlying sex differences in autoimmunity - JCI
    Sep 17, 2024 · Most autoimmune diseases occur more often in women than men, with rheumatic autoimmune diseases being among those most highly expressed in women ...The role of sex hormones · The role of environment · Pediatric autoimmune diseases
  163. [163]
    The X-quisite X-ception: Sex Differences with Immune Responses
    Jul 2, 2024 · Increased numbers of X chromosomes is associated with higher risk for the female-biased autoimmune diseases SLE, SS, scleroderma, polymyositis, ...
  164. [164]
    Why do men have worse COVID-19-related outcomes? A systematic ...
    As testosterone physiologically decreases in older males (5), age may play an important role in mediating adverse COVID-19 outcomes according to sex. In this ...
  165. [165]
    Testosterone in COVID-19: An Adversary Bane or Comrade Boon
    Regarding these considerations, men are more vulnerable for COVID-19 severity as compared with women due to the immunosuppressive effects of testosterone ( ...
  166. [166]
    In men, high testosterone can mean weakened immune response ...
    Dec 23, 2013 · Scientists at the Stanford University School of Medicine have linked high testosterone levels in men to a poor immune response to an influenza vaccine.
  167. [167]
    Female-bias in systemic lupus erythematosus: How much is the X ...
    Oct 7, 2024 · Lupus stands as a paradigmatic example of a disease characterized by a marked bias toward women, with a female-to-male ratio of up to 14:1 [3].
  168. [168]
    Stanford Medicine-led study shows why women are at greater risk of ...
    Feb 1, 2024 · One strain is quite susceptible to autoimmune symptoms mimicking lupus, with females more susceptible than males. The other is resistant to ...
  169. [169]
    Toward understanding sexual immune dimorphism in humans - PMC
    From an evolutionary perspective, life history theory explains these differences as the result of trade-offs between reproductive strategies and immune function ...
  170. [170]
    Sexual conflict drives micro- and macroevolution of ... - BMC Biology
    Jun 2, 2021 · Sexual dimorphism in immunity is believed to reflect sex differences in reproductive strategies and trade-offs between competing life history ...
  171. [171]
    Superior Intrinsic Mitochondrial Respiration in Women Than in Men
    Mitochondrial Quality in Women and Muscle Metabolism​​ Strong sexual dimorphism has been shown in rodent models with females exhibiting superior structural and ...
  172. [172]
    Hypoxia-ischemia and sexual dimorphism: modeling mitochondrial ...
    May 24, 2025 · Literature reports indicate favorable survival and neurodevelopment outcome in female compared to male infants affected by HIE [5,6,7,8]. Male ...
  173. [173]
    The contribution of the mitochondrial genome to sex-specific fitness ...
    The contribution of the mitochondrial genome to sex-specific fitness variance. Shane R. T. Smith ,. Shane R. T. Smith. School of Biological Sciences Monash ...Missing: PDF | Show results with:PDF
  174. [174]
    Sex differences in muscle protein expression and DNA methylation ...
    Sep 5, 2023 · Sex differences in muscle protein expression and DNA methylation in response to exercise training. Biol Sex Differ 14, 56 (2023). https ...
  175. [175]
    Sexual dimorphism in aging hematopoiesis: an earlier decline of ...
    Although males and females experience the same types of aging-related changes to the immune system, males experience them earlier or more dramatically than ...
  176. [176]
    Sexual dimorphism in human muscle ageing - medRxiv
    Jan 6, 2025 · We report results from an analysis of arm muscle ageing on 478,438 UK Biobank participants aged 40–82 yr. A clear sexual dimorphism was ...Missing: aging | Show results with:aging
  177. [177]
    Testis weight, body weight and breeding system in primates - Nature
    Sep 3, 1981 · Harcourt, A., Harvey, P., Larson, S. et al. Testis weight, body weight and breeding system in primates. Nature 293, 55–57 (1981). https ...
  178. [178]
    How sperm competition shapes the evolution of testes and sperm
    Oct 19, 2020 · Yet, not all males transfer vast numbers of tiny sperm, and postcopulatory sexual selection can favour larger and more complex sperm. ... primates ...
  179. [179]
    BODY SIZE, SPERM COMPETITION, AND DETERMINANTS OF ...
    Sperm competition, testes size, and breeding systems in primates ... J. Cheverud . 1982 . Correlates of sexual dimorphism in primates: Ecological and size ...
  180. [180]
    (PDF) Parental Investment and Sexual Selection - ResearchGate
    Parental Investment and Sexual Selection January 1972 Authors: Robert Trivers at Chapman University Robert Trivers Download full-text PDF
  181. [181]
    An evolutionary explanation of female‐biased sexual size ... - NIH
    Jan 30, 2023 · Sexual size dimorphism (SSD) is caused by differences in selection pressures and life‐history trade‐offs faced by males and females.
  182. [182]
    Sexual size dimorphism in golden pompano (Trachinotus blochii)
    Oct 6, 2022 · A significant difference between the growth of males and females was observed; females were found to be 17% larger than males after reaching 7 months of age.
  183. [183]
    Increased vigilance of paired males in sexually dimorphic species
    In animal pairs, males are often more vigilant than females. This is generally assumed to result from mate guarding (either against predators or other males).
  184. [184]
    Sexual size dimorphism affecting mate choice and reproduction in ...
    Nov 10, 2024 · Our results revealed that mating latency and frequency of mating attempts varied across different social environments. Both large males and ...
  185. [185]
    (PDF) Predator preference for brightly colored males in the guppy
    Aug 9, 2025 · In situations with fluctuating predation pressures, male fish may modify their pigmentation. For example, male guppies in predator-dense ...
  186. [186]
    Fear, food and sexual ornamentation: plasticity of colour ...
    Predation cost of conspicuous male coloration in ... The degree of response to increased predation risk corresponds to male secondary sexual traits.
  187. [187]
    Sexual selection - Darwin Correspondence Project |
    Descent: The descent of man, and selection in relation to sex. By Charles Darwin. 2 vols. London: John Murray. 1871. Wallace, Alfred Russel. 1871c. Review of ...
  188. [188]
    The measure and significance of Bateman's principles - PMC - NIH
    Bateman's principles explain sex roles and sexual dimorphism through sex-specific variance in mating success, reproductive success and their relationships ...
  189. [189]
    Runaway ornament diversity caused by Fisherian sexual selection
    Fisher's runaway process of sexual selection is potentially an important force generating character divergence between closely related populations.
  190. [190]
    Substantial but Misunderstood Human Sexual Dimorphism Results ...
    It is often assumed that sexually dimorphic traits reflect a history of sexual selection, but natural selection frequently builds different phenotypes in males ...
  191. [191]
    SEXUAL DIMORPHISM WITH FEMALE DEMOGRAPHIC ...
    Sep 1, 2000 · Under the influence of natural and sexual selection, males and females will often differ in the costs and benefits of achieving some ...
  192. [192]
    Evolution of sexual size dimorphism in tetrapods is driven by varying ...
    Dec 23, 2024 · Published: 23 December 2024. Evolution of sexual size dimorphism in tetrapods is driven by varying patterns of sex-specific selection on size.
  193. [193]
    Genetic constraints and the evolution of display trait sexual ...
    The evolution of sexual dimorphism involves an interaction between sex-specific selection and a breakdown of genetic constraints that arise because the two ...
  194. [194]
    Genetic Constraints and the Evolution of Display Trait Sexual ...
    The evolution of sexual dimorphism requires that the genetic control of a shared trait be at least partially independent between the sexes such that the ...
  195. [195]
    Palaeontology: Sexual dimorphism in dinosaurs - eLife
    Jun 14, 2023 · Studying fossils from a mass-mortality event reveals evidence for sexual dimorphism and, unusually, equal numbers of males and females in a herd of dinosaurs.<|separator|>
  196. [196]
    (PDF) The smallest biggest theropod dinosaur: a tiny pedal ungual ...
    Aug 12, 2025 · This peculiar morphology allows to refer the specimen to the smallest known individual of the genus Spinosaurus. The bone belongs to an early ...<|separator|>
  197. [197]
    Sexual selection in Ceratopsia - Palaeontologia Electronica
    An analysis of 37 specimens, encompassing four distinct size classes of animal, shows that the frill (in both length and width) undergoes positive allometry ...
  198. [198]
    Dinosaur frills were likely the result of sexual selection - Phys.org
    Feb 8, 2021 · The growth pattern of Protoceratops' frills matched this, indicating that the frills were very possibly sexually selected. However, the team ...
  199. [199]
    Canine sexual dimorphism in Egyptian Eocene anthropoid primates
    Two very small late Eocene anthropoid primates, Catopithecus browni and Proteopithecus sylviae, from Fayum, Egypt show evidence of substantial sexual ...
  200. [200]
    Sexual Size Dimorphism in Australopithecus: Postcranial ...
    Jul 11, 2025 · This study addresses reasons for differences in published studies and directly compares dimorphism in A. afarensis, A. africanus, and extant ...
  201. [201]
    Were Our Ancestors More Like Gorillas Than Humans? New Study ...
    Aug 28, 2025 · Fossils reveal extreme sexual dimorphism in early hominins. The findings reshape views of their social behavior. A recent study has revealed ...
  202. [202]
    Sexual dimorphism and paleoecology in Teleoceras, a North ...
    (1979) demonstrated significant correlation between the degree of sexual dimorphism and harem size in extant ungulates, indicating that most polygynous ...
  203. [203]
    EARLY EVOLUTION OF SEXUAL DIMORPHISM AND POLYGYNY ...
    We have shown a deep origin of skull shape dimorphism in pinnipeds and thus of highly polyg- ynous, likely harem-forming land-based mating systems. These.
  204. [204]
    Australopithecus robustus societies - one-male or multimale?
    Sexual dimorphism provides clues for reconstructing the social structure and mating systems of extinct species.4,10 The current data for early hominids - the ...
  205. [205]
    A Critical Examination of Relaxed Molecular Clock Age Estimates of ...
    The study examines relaxed molecular clock estimates for bilaterian animals and placental mammals, finding that the analysis does not provide evidence for an  ...Missing: sexual dimorphism tissue coloration
  206. [206]
    The origin of animals: Can molecular clocks and the fossil record be ...
    Dec 5, 2016 · Molecular clocks estimate that animals originated over 100 million years before the first definitive metazoan fossil evidence in the ...Missing: sexual dimorphism coloration