Fact-checked by Grok 2 weeks ago

External fertilization

External fertilization is a reproductive strategy in which eggs and sperm are released by parents into the external , typically habitats, where the gametes fuse outside the bodies to form zygotes. This process, known as spawning, is widespread among animals, including , amphibians, such as sea urchins and corals, and some semi-aquatic species. It contrasts with , where gametes unite within the female's reproductive tract, and is considered the ancestral mode of in vertebrates. The process of external fertilization relies on the synchronous release of vast numbers of s—often thousands to millions per individual—to compensate for the low probability of any single encountering an in the open environment. Environmental cues, such as water temperature, lunar cycles, or pheromones, trigger this mass spawning to maximize fertilization success, with water currents aiding gamete dispersal and preventing . In like sea urchins, sperm swim short distances to penetrate the egg's protective layers, initiating embryonic development in the surrounding medium. Notable examples include fish such as , which migrate to freshwater streams to broadcast gametes over gravel beds; amphibians like frogs and toads, where males grasp females in to release as eggs are laid in ; and sessile corals that undergo synchronized broadcast spawning events, releasing buoyant egg-sperm bundles into currents. These strategies highlight adaptations to life, where external fertilization enables high without the need for copulatory organs or prolonged parental contact. External fertilization offers advantages such as the production of large numbers of , promoting and allowing sessile organisms to disperse larvae over wide areas. However, it is disadvantaged by low fertilization rates—often less than 10% in some —due to gamete wastage, predation on free-floating zygotes, and sensitivity to environmental disruptions like or temperature changes. Evolutionarily, this mode has shaped morphology across vertebrates, with external fertilizers exhibiting shorter components adapted for rapid, dilute environments, and it remains prevalent in about 17% of studied vertebrate , particularly in bony fishes and amphibians.

Definition and Characteristics

Definition

External fertilization is a reproductive strategy wherein the union of male and female s— and —occurs outside the bodies of the parents, typically within an aqueous environment into which the gametes are released. In this process, motile cells swim through the surrounding medium to reach and penetrate the , leading to the formation of a , a single diploid that represents the beginning of embryonic development. This mode of reproduction contrasts with by depending on the external medium for gamete transport and protection, often requiring large numbers of gametes to overcome dilution and predation risks. The phenomenon of external fertilization was first systematically observed and described through studies of aquatic species by naturalists in the 18th and 19th centuries, building on earlier anecdotal accounts of spawning behaviors in and . These early investigations, including detailed examinations of marine organisms like sea urchins, laid the groundwork for understanding release and fusion as key biological events. This reproductive strategy is predominantly observed in aquatic animals, where water serves as a conducive medium for gamete dispersal, but it also occurs in certain amphibians that undertake breeding migrations to habitats despite otherwise terrestrial lifestyles.

Comparison to Internal Fertilization

External fertilization fundamentally differs from in the site and mechanism of gamete fusion. In external fertilization, both eggs and are released into the external —typically —where they must encounter and unite without direct physical contact between parents, a process known as spawning. In contrast, internal fertilization involves the transfer of into the female's reproductive tract through copulation, spermatophores, or other methods, allowing fusion within the controlled internal . This external release in external fertilization necessitates a high-volume production of gametes, with organisms allocating substantial energy toward quantity to mitigate low encounter probabilities, whereas internal fertilization permits investment in fewer gametes of higher quality due to targeted delivery. Evolutionarily, external fertilization is well-suited to aquatic ecosystems, where water acts as a transport medium for gametes, reducing the risk of and enabling widespread dispersal over short distances. This mode likely represents the ancestral reproductive strategy in many animal lineages, particularly those in marine or freshwater habitats. , however, emerged as an in lineages transitioning to terrestrial environments, providing protection against , physical damage, and pathogens by enclosing gametes and early embryos within the female's body. This shift allowed for greater reproductive flexibility on land but often at the cost of increased in mating behaviors and structures. Fertilization success rates highlight a key between the two modes. External fertilization typically yields lower rates—often 20-40% in broadcast spawners—owing to dilution in water, limited longevity of free-swimming (seconds to hours), and vulnerability to environmental disruptions like currents or predation. For example, in the external-fertilizing ascidian Styela plicata, rates vary from about 24% with longer-lived to 38% with fresh , reflecting the challenges of open-water encounters. Internal fertilization, by contrast, achieves near 100% success for inseminated in many , as direct deposition minimizes loss and maximizes contact efficiency, though overall reproductive output may be lower due to fewer eggs produced.

Mechanisms

Gamete Release

In external fertilization, are released through a process known as broadcast spawning, where both males and females expel large numbers of eggs and into the surrounding environment simultaneously to enhance the probability of successful encounters. This mass release, or oviposition in females and spermiation in males, occurs in synchronized bursts, often triggered by environmental stimuli that prompt adults to aggregate and discharge over short periods. The physiological mechanisms governing gamete release involve hormonal regulation that coordinates maturation and expulsion. In vertebrates such as and amphibians, (GnRH) from the stimulates the to secrete gonadotropins, which in turn promote production in the gonads, leading to final gamete maturation and spawning. In many , similar steroid-mediated pathways, including gonad-stimulating substances, drive the process, ensuring gametes are viable upon release. Gametes in externally fertilizing exhibit specific adaptations to facilitate dispersal and brief in . Eggs typically feature jelly coats that confer , protect against or predation, and sometimes enhance stickiness to substrates, while are adapted for high to swim toward eggs but possess short lifespans, often lasting only 30 seconds to a few minutes before losing viability. To offset high mortality rates from dilution, predation, and environmental hazards, females release vast quantities of eggs per spawning event, ranging from thousands in some to millions in ; for instance, female sea urchins can expel millions of eggs in a single burst.

Fertilization Process

In external fertilization, the encounter between and eggs occurs primarily through passive diffusion of in water, augmented by where eggs release soluble chemoattractants that form concentration gradients guiding . In like sea urchins, peptides such as speract diffuse from the egg at rates around 240 µm²/s, creating detectable slopes that trigger intracellular calcium oscillations in , prompting reorientation and straight-line swimming toward the source. Moderate water currents enhance this process by elongating chemoattractant filaments, optimizing encounter rates at rates of approximately 0.1 s⁻¹, as observed in species such as red abalone and sea urchins. Once a contacts the 's outer investments, it initiates the : binding to specific receptors on the coat triggers calcium influx, leading to of the acrosomal cap and release of hydrolytic enzymes like acrosin that digest the vitelline or jelly coat. This enzymatic penetration is essential in aquatic external fertilization, allowing the to reach the plasma membrane, as exemplified in models where the reaction exposes fusion proteins on the head. To avert , the penetrating 's fusion activates the 's , a rapid of thousands of cortical granules (about 15,000 in s) that release proteases, mucopolysaccharides, and peroxidases into the perivitelline space. These contents modify the by dissolving attachments to extraneous , swelling it via osmotic influx, and hardening it through protein crosslinking, thereby establishing a durable barrier within 20–60 seconds post-fusion. The culmination of these events is gamete fusion, where sperm and egg membranes merge via proteins like IZUMO1 and , combining their haploid nuclei to form a diploid that restores the full complement and activates embryonic . In external settings, this formation precedes immediate , with the first mitotic divisions partitioning the into blastomeres without overall growth, initiating development in the aquatic environment. However, the process is inefficient due to several barriers: dilution in open water rapidly lowers local concentrations, often reducing fertilization rates below 1% in dilute conditions unless mitigated by high spawning densities. Physical obstacles like water turbulence scatter and disrupt gradients, with velocities exceeding 0.2 m/s inhibiting success in such as , though timing releases to calm periods can achieve near-complete fertilization. Predation further compounds these risks, as planktonic consumers actively forage on broadcast , with cryptic nighttime predation documented in spawning events where up to significant portions of released bundles are consumed by .

Synchronization and Cues

Synchronization of gamete release is essential in external fertilization to maximize the probability of sperm-egg encounters in dilute environments, where gametes are broadcast into the water column. This coordination relies on a combination of environmental and biological cues that trigger mass spawning events across populations, ensuring temporal overlap in reproductive activity. Such synchrony reduces the dilution of gametes and enhances fertilization success, particularly in with low gamete densities or high energetic costs of . Lunar and tidal cycles serve as prominent environmental cues for many marine broadcast spawners, particularly . In corals, the period of darkness following sunset after the acts as a key trigger for synchronized spawning, allowing gametes to be released under conditions of optimal water mixing and reduced predation. For instance, like spp. initiate mass spawning several nights after the , synchronized by moonlight intensity and the timing of moonrise. cues further refine this timing; intertidal often align spawning with high to facilitate larval dispersal and maximize fertilization through enhanced water currents. Chemical pheromones provide biological signals that promote aggregation and precise timing among individuals. In broadcast-spawning invertebrates like the lugworm Arenicola marina, sex pheromones released by females induce males to spawn synchronously, clustering individuals and increasing encounter rates for external fertilization. Similarly, in sea cucumbers such as Holothuria arguinensis, chemicals emitted by males attract conspecifics, mediating aggregation and triggering spawning in groups to optimize overlap. These pheromonal cues are particularly vital in where visual or auditory signals are limited in turbid waters. Temperature and photoperiod act as seasonal thresholds that initiate gonadal maturation and spawning in many aquatic species. In temperate fish like (Perca flavescens), water temperatures of 20-25°C signal the onset of synchronous spawning, aligning reproductive peaks with optimal conditions for development and larval . Photoperiod, or day length, complements this by imposing ; increasing day lengths in trigger hormonal changes leading to mass spawning in species such as the lumpfish (Cyclopterus lumpus). These abiotic factors ensure that spawning coincides with favorable environmental windows, preventing mismatches due to climate variability. Behavioral aggregation through displays further synchronizes releases in group settings. In externally fertilizing like the (Gasterosteus aculeatus), males perform vigorous rituals, including zigzag dances and nest-building, to attract females and align spawning timing within aggregations. These displays facilitate lekking-like behaviors where multiple individuals converge, enhancing concentration and fertilization rates during synchronized broadcasts. Such visual and acoustic cues are crucial in clear-water habitats, promoting precise coordination without relying solely on environmental triggers.

Occurrence in Invertebrates

Marine Invertebrates

Marine invertebrates represent a diverse array of taxa that predominantly rely on external fertilization, with cnidarians, echinoderms, and mollusks serving as key examples. In cnidarians such as scleractinian corals, gametes are broadcast into the water column during synchronized mass spawning events, where eggs and sperm from multiple colonies mix to achieve fertilization. For instance, on the Great Barrier Reef, numerous coral species release gamete bundles annually in October to December, enhancing the probability of cross-fertilization across vast reef areas. Echinoderms, including sea urchins, also exhibit broadcast spawning with highly synchronized release of gametes, often triggered by environmental cues to maximize encounter rates in the water column. Among mollusks, oysters like Crassostrea species release eggs and sperm externally, leading to fertilization in the surrounding seawater before developing into free-swimming larvae. A primary adaptation in these groups is the production of planktonic larvae, which facilitate widespread dispersal after fertilization. These larvae, often lasting days to weeks in the plankton, allow offspring to colonize distant habitats, reducing with adults and promoting across populations. Broadcast spawning itself is adapted for open-water environments, where large quantities of gametes are released to overcome dilution in marine currents, as seen in coral reefs where spawning synchrony aligns with lunar cycles and tidal patterns to concentrate gametes locally. The majority of benthic utilize external fertilization, underscoring its prevalence in saline ecosystems. This strategy supports high reproductive output but is constrained by longevity; for example, in echinoderms like sea urchins, remain viable for less than 30 minutes post-release, necessitating precise temporal and spatial for successful fertilization. Ocean acidification poses significant challenges to these processes, reducing fertilization success in various species by altering performance. Post-2010 studies indicate declines of 20-44% in fertilization rates for sea urchins under near-future pCO₂ levels, primarily due to impaired and velocity. In some cases, cumulative effects on fertilization and subsequent larval can exceed 50% reduction, threatening in acidified waters.

Freshwater Invertebrates

External fertilization in freshwater invertebrates is less prevalent than in marine environments, primarily due to the challenges posed by variable water flows, lower salinity, and limited gamete dispersal in contained habitats like rivers, lakes, and ponds. Unlike the stable oceanic conditions that facilitate widespread broadcast spawning in marine species, freshwater systems often favor localized or semi-external mechanisms to mitigate risks such as rapid dilution of gametes or desiccation during low flows. Invertebrates employing external fertilization in these settings typically release gametes into the water column or protective structures, with fertilization occurring outside the parental body but often in close proximity to enhance success rates. Key groups exhibiting external fertilization include freshwater sponges (Porifera) and some crustaceans. External fertilization is rare in freshwater annelids, with most species using via copulation. Freshwater sponges, such as , release into the surrounding , where currents carry them to fertilize eggs retained within the of nearby individuals; this process supports genetic diversity while relying on flow for gamete transport. Among crustaceans, freshwater crayfish (e.g., species in the genus ) utilize a semi-external process where males deposit spermatophores externally on the female's during ; the female later extrudes eggs and uses the stored for fertilization outside her body, attaching the resulting embryos to her pleopods for brooding. Adaptations to freshwater dynamics include adhesive structures that anchor fertilized eggs or embryos against currents and sedimentation. In crayfish, eggs are coated in a sticky layer post-fertilization, securing them to the female's swimmerets and preventing dislodgement in turbulent flows. Clutch sizes are generally smaller in these systems compared to marine broadcast spawners, reflecting the energetic costs of contained habitats and higher per-egg investment; for instance, freshwater typically produce 100–500 eggs per , balancing predation risks with developmental success. Environmental pressures in freshwater ecosystems, such as elevated from organic decay in stagnant ponds or intensified predation by and amphibians, exert stronger selective forces than in marine settings, often leading to lower fertilization success rates. Seasonal spawning is frequently synchronized with flood events to maximize dispersal and larval survival; in Amazonian river systems, for example, rising waters during wet seasons trigger mass release of in invertebrates like certain , diluting predators and enhancing oxygenation. Despite these adaptations, external fertilization in freshwater remains understudied relative to counterparts, with significant knowledge gaps in long-term . Recent research from the 2020s indicates that climate-driven warming disproportionately impacts external fertilizers in freshwater, reducing fertilization efficiency by up to 50% at elevated temperatures due to altered motility and synchronization, potentially exacerbating declines in hotspots like tropical rivers.

Occurrence in Vertebrates

Fish

External fertilization is the predominant reproductive strategy among fish, occurring in the vast majority of the over 33,000 species of bony fishes (teleosts), where gametes are released into the aquatic environment for fertilization. In contrast, cartilaginous fishes such as sharks and rays primarily employ internal fertilization, facilitated by male claspers that deliver sperm directly into the female's reproductive tract. Notable examples of external fertilization include salmonids, which spawn in freshwater rivers, and clownfish, which deposit eggs on substrates near sea anemones for male fertilization. Fish exhibit diverse spawning strategies adapted to their habitats, broadly categorized as pelagic or demersal. Pelagic spawning involves the release of buoyant eggs into the open water column, allowing them to drift with currents and disperse widely; this is common in marine species like ( morhua), where females can produce 3 to 9 million eggs per spawning event to compensate for high mortality rates. Demersal spawning, conversely, features adhesive eggs that sink and attach to substrates such as rocks or vegetation, often in coastal or reef environments, as seen in many coral reef fishes that benefit from localized protection. These strategies enhance fertilization success by synchronizing release during aggregations, though they expose eggs to predation and environmental variability. Adaptations to external fertilization in fish are generally limited, with parental care being rare due to the high fecundity offsetting low survival rates; however, it does occur in some species, such as mouthbrooding cichlids, where males incubate fertilized eggs in their buccal post-release to guard against predators. In brackish water species, osmoregulation poses specific challenges, as fluctuating salinities can impair and egg viability; for instance, euryhaline fishes like the must precisely time spawning to optimal conditions to maintain activation thresholds. Human activities, particularly , severely disrupt external fertilization by targeting spawning aggregations, leading to significant population declines; for example, many reef fish have experienced over 50% reductions in abundance since the early 2000s due to exploitation of these predictable sites. Such impacts not only reduce reproductive output but also alter and dynamics in affected systems.

Amphibians

External fertilization is the predominant reproductive strategy among , primarily through mechanisms adapted to aquatic or semi-aquatic environments. In anurans (frogs and toads), which constitute the majority of amphibian diversity, it is facilitated by , where the male clasps the female's back or axillary region to position their cloacae in close proximity during egg release into water, allowing to fertilize the eggs externally as they are extruded. This behavior ensures synchronization and increases fertilization success in species that breed in ponds, streams, or temporary water bodies. Among caudates (salamanders), external fertilization is less common, limited to about 10% of species, and typically occurs in lotic (flowing ) habitats such as , where primitive families like Cryptobranchidae (e.g., hellbenders) release gametes directly into the without physical contact between sexes. In contrast, most terrestrial or lentic (still ) salamanders have evolved via spermatophores, reducing reliance on external aquatic conditions. (Gymnophiona), the third order of amphibians, exclusively use . These lotic-adapted species often exhibit male , such as guarding sites post-fertilization, to mitigate risks in dynamic stream environments. Amphibian eggs fertilized externally are typically encased in protective jelly capsules that provide multiple layers of defense, including barriers against , pathogens, , and predators. Clutch sizes vary widely, ranging from 100 to over 50,000 eggs per female, depending on species and environmental factors, with many anurans depositing them in foam nests constructed during to enhance oxygenation and protection; for instance, túngara frogs (Engystomops pustulosus) produce foam nests containing an average of around 2,350 eggs. As an ancestral trait in the , external fertilization reflects their evolutionary origins tied to aquatic breeding, but it renders many species vulnerable to habitat degradation and . According to the , approximately 41% of amphibian species are currently threatened with (as of 2025), largely due to loss of breeding wetlands that are essential for successful release and development.

Ecological and Evolutionary Aspects

Advantages and Disadvantages

External fertilization offers several evolutionary advantages, particularly in environments where it facilitates high and rapid . By releasing vast numbers of gametes—often in the range of thousands to millions per can compensate for low per-gamete success rates, enabling quick recovery from population declines and expansion in favorable conditions. This strategy also eliminates the need for mate guarding or prolonged pair bonding, as gametes are broadcast into the surrounding medium, reducing energy expenditure on behavioral interactions and allowing individuals to allocate resources elsewhere. Furthermore, mass spawning events promote by allowing fertilization of eggs by from multiple males, leading to multiple paternity and increased offspring variability. Despite these benefits, external fertilization incurs significant disadvantages, including low fertilization success rates that often fall below 20% in natural settings due to dilution, hydrodynamic dispersion, and predation. are highly vulnerable to environmental pollutants, such as and pesticides, which directly impair motility, viability, and fertilization capacity since they are released unprotected into the water column. Additionally, the production of excess imposes a substantial energetic , diverting resources from maintenance or growth, as organisms must synthesize large quantities that are frequently wasted without achieving fertilization. In evolutionary terms, external fertilization is favored in stable aquatic habitats where water facilitates dispersal and protects against , but it becomes disadvantageous in variable or terrestrial environments, driving transitions to in lineages like amphibians to reptiles. Recent studies highlight how exacerbates these drawbacks; for instance, ocean warming can reduce in , compromising fertilization outcomes and population persistence. A 2024 meta-analysis indicated that aquatic species employing external fertilization are more vulnerable to the negative effects of warming compared to those using , with particularly strong impacts in freshwater taxa.

Sexual Selection

In species employing external fertilization, sexual selection often manifests prior to gamete release through pre-spawning behaviors that influence mate choice and access to spawning sites. In amphibians such as frogs, males produce species-specific advertisement calls to attract females to optimal aquatic spawning locations, where vocal signals serve as honest indicators of male quality and genetic fitness. These auditory cues facilitate female preference for males in favorable positions, enhancing fertilization success by synchronizing spawning in nutrient-rich or protected waters. Similarly, visual signals like ornate nuptial pads or body coloration in male frogs reinforce mate attraction, directing females toward competitively superior individuals. Male-male competition further shapes pre-spawning selection by establishing dominance hierarchies that determine spawning positions. In anuran amphibians, larger males often displace smaller rivals to secure prime calling or sites, increasing their proximity to females during egg deposition and thereby boosting paternity shares. This intrasexual can escalate to physical contests, where body size correlates with aggressive success and access to mates, as observed in treefrogs where dominant males monopolize group spawning events. In broadcast-spawning like the , males compete aggressively for nest territories, using red breeding coloration and zigzag displays to both intimidate rivals and court females, resulting in size-based hierarchies that favor larger individuals in securing spawning rights. At the gamete level, intensifies post-release through and , particularly in environments where gametes mix freely. In broadcast spawners such as and , faster-swimming from competitively superior males outcompete rivals to reach eggs first, with fertilization success often determined by relative sperm velocity and density in dilute columns. Females exert cryptic choice by modulating egg release timing, allowing ovarian fluids or spawning synchrony to bias fertilization toward preferred males' gametes, as seen in externally fertilizing like where egg- interactions favor compatible or high-quality . This gametic selection amplifies post-spawning variance in , especially in systems with high multiple-mating potential. Theoretical frameworks underscore how external fertilization amplifies Bateman's principle, where male reproductive success scales steeply with mating opportunities due to low per- investment, while female benefits plateau, driving strategies in broadcast spawners. In these systems, multiple matings expose to intense competition, magnifying on traits like traits and pre-spawning signals. Recent models post-2000, such as those integrating density-dependent effects in broadcast , predict that local gamete concentrations and aggregation behaviors evolve to optimize fertilization under variable limitation, further entrenching male-male rivalry and female choosiness.

References

  1. [1]
    Animal Reproductive Strategies | Organismal Biology
    External fertilization usually occurs in aquatic environments where both eggs and sperm are released into the water, a process called spawning. Water protects ...
  2. [2]
    Fertilization - Molecular Biology of the Cell - NCBI Bookshelf - NIH
    In these organisms fertilization occurs in sea water, into which huge numbers of both sperm and eggs are released. Such external fertilization has been more ...
  3. [3]
    [PDF] . I ze rs - FSU Biology
    External fertilization is a common and widespread reproductive strategy in aquatic en vironments ( Giese and Kanatani 1987) and is generally.
  4. [4]
    In the beginning… Animal fertilization and sea urchin development
    Dec 1, 2006 · According to Kay and Shapiro (1985), Derbès' observation of the fertilization envelope is one of the earliest known.
  5. [5]
    External Fertilization | Ask A Biologist - Arizona State University
    Jul 16, 2019 · External fertilization in animals usually occurs in water or in damp areas in a process called spawning. Moisture in the environment keeps the gametes from ...Missing: definition | Show results with:definition
  6. [6]
    [PDF] The Physics of Broadcast Spawning in Benthic Invertebrates
    Aug 14, 2013 · External fertilization incorporates the synchronous release of sperm and eggs from separate locations, whereupon the process depends on ...
  7. [7]
    [PDF] Hormonal Control of Reproduction in Fish for Induced Spawning
    Nov 1, 1991 · spawning substrate. (e.g., aquatic plants, sticks, gravel, spawn- ing mats, spawning caverns); nutrition; disease and parasites; and presence of ...
  8. [8]
    Environmental and biological cues for spawning in the crown-of ...
    Mar 29, 2017 · We propose that environmental cues act as spawning 'inducers' by causing the release of hormones (gonad stimulating substance) in sensitive ...
  9. [9]
    Fertilization ecology of egg coats: physical versus chemical ...
    Jun 1, 2002 · Regression analysis using a standard fertilization kinetics model found that 54-73% of this decline on average was predicted by changes in the ...
  10. [10]
    Gamete plasticity in a broadcast spawning marine invertebrate - PNAS
    Sep 9, 2008 · Many marine invertebrate eggs have accessory structures, such as follicle cells or jelly coats, that increase the overall target size for ...
  11. [11]
    Sperm velocity and longevity trade off each other and influence ...
    Here I investigate how sperm velocity and sperm longevity influence the patterns of fertilization in the sea urchin Lytechinus variegatus. In the laboratory ...
  12. [12]
    Sperm chemotaxis is driven by the slope of the chemoattractant ...
    Spermatozoa of marine invertebrates are attracted to their conspecific female gamete by diffusive molecules, called chemoattractants, released from the egg ...Missing: aquatic | Show results with:aquatic
  13. [13]
    Sperm chemotaxis in marine species is optimal at physiological flow ...
    Apr 12, 2021 · Pioneering experiments suggest that in species with external fertilization, chemotaxis of sperm cells towards the egg may even work better at an ...
  14. [14]
    Gamete Fusion and the Prevention of Polyspermy - NCBI
    Placing unfertilized sea urchin eggs into seawater containing A23187 causes the cortical granule reaction and the elevation of the fertilization envelope.
  15. [15]
    The cell biology of fertilization: Gamete attachment and fusion - PMC
    Fertilization is defined as the union of two gametes. During fertilization, sperm and egg fuse to form a diploid zygote to initiate prenatal development.
  16. [16]
    Successful external fertilization in turbulent environments. | PNAS
    ### Summary of Effects of Turbulence and Dilution on External Fertilization Success
  17. [17]
    Cryptic predation on coral spawn: Hidden trophic links in the dead of ...
    Broadcast‐spawning, where gametes are released into the water for external fertilization, is a widespread reproductive strategy in marine environments, ...
  18. [18]
    Long-term study of gamete release in a broadcast-spawning ...
    Jan 11, 2025 · The gonads of individuals that did not spawn in a given month showed a variety of matu- rity levels, including post-spawning, growth and mature ...
  19. [19]
    Moonrise timing is key for synchronized spawning in coral ... - PNAS
    Aug 9, 2021 · This paper demonstrates that the period of darkness between sunset and moonrise that occurs after the full moon is a trigger for spawning in coral species ...
  20. [20]
    Signaling cascades and the importance of moonlight in coral ... - eLife
    Dec 15, 2015 · We show that moonlight is an important external stimulus for mass spawning synchrony and describe the potential mechanisms underlying the ability of corals to ...
  21. [21]
    Reproductive cycles in tropical intertidal gastropods are timed ... - NIH
    Jun 23, 2017 · Reproduction in iteroparous marine organisms is often timed with abiotic cycles and may follow lunar, tidal amplitude, or daily cycles.
  22. [22]
    Crabs synchronize reproduction to a 14-month lunar-tidal cycle
    Aug 9, 2025 · Tidal cues were more important than moonlight in entraining the reproductive rhythm, although two populations synchronized spawning to the new ...
  23. [23]
    (PDF) Spawning synchrony in Arenicola marina: Evidence for sex ...
    with other individuals increased to 20–30%. Figure 2ademonstrates that males are able to. spawn repeatedly during the spawning season. Nine-. teen out of 20 ...
  24. [24]
    Chemicals released by male sea cucumber mediate aggregation ...
    Jan 10, 2018 · The hypothesis that the sea cucumber Holothuria arguinensis uses chemical communication for aggregation and spawning was tested.
  25. [25]
    Environmental Constraints on Spawning Depth of Yellow Perch
    Magnuson (1991) describes yellow perch as coolwater fish with a preferred temperature range of 20–25°C as adults. They are annual spawners with synchronous ...Missing: threshold | Show results with:threshold
  26. [26]
    The Role of Manipulating Photoperiod and Temperature in Oocyte ...
    Dec 7, 2020 · Photoperiod controls gametogenesis via imposing seasonality on life cycle, while temperature is more related to the metabolism of the ...
  27. [27]
    Reproductive performance of lumpfish (Cyclopterus lumpus, L. 1758 ...
    Oct 15, 2024 · This study investigated the combined effects of photoperiod and temperature manipulations on sexual maturation and spawning in lumpfish females.Missing: thresholds | Show results with:thresholds
  28. [28]
    (PDF) Courtship rate signals fertility in an externally fertilizing fish
    Aug 10, 2025 · By contrast, courtship rate decreases as the OSR becomes increasingly biased, whereas mate guarding and copulation duration increase. Overall, ...
  29. [29]
    Temporal changes in behavior during the group spawning event of ...
    Apr 2, 2025 · The synchronized spawning behavior increases the fertilization rate and minimizes the risks of predation and environmental change as much as ...
  30. [30]
    Sexual reproduction - Corals of the World
    ... reproductive contact: species which spawn must release their gametes into the water simultaneously. ... Many of the broadcast-spawning coral species time their ...
  31. [31]
    Coral spawning breeds a new generation for our Reef
    Nov 13, 2023 · By spawning on mass, corals increase the likelihood of finding a matching bundle from the same species to fertilise. Other external factors like ...
  32. [32]
    THE ECOLOGY OF FERTILIZATION OF ECHINOID EGGS: THE ...
    Within 20 cm of spawning males 60-95% fertilization usually occurred; at distances greater than 20 cm less than 15% of the eggs were fertilized. Higher ...
  33. [33]
    Marine Invertebrates - MarineBio Conservation Society
    Marine Invertebrates 3 Mollusks reproduce through external fertilization where the eggs and sperm are released into the water. In some more complex mollusks ...
  34. [34]
    [PDF] Larval Supply and Dispersal - Marine Evolutionary Ecology Group
    Their small size and poor swimming ability make these larvae vulnerable to a range of predators and to ocean currents, and the larval planktonic period has long ...
  35. [35]
    Patterns of coral spawning in the Palm Islands, Great Barrier Reef
    Aug 23, 2025 · Spawning start times varied widely among taxa. For example, within Acropora, some species spawn early in the evening, such as A. tenuis, whereas ...
  36. [36]
    Ocean acidification changes the male fitness landscape - Nature
    Aug 17, 2016 · The majority of marine species release sperm and eggs directly into the water column for external fertilisation, including several large taxa ...
  37. [37]
    [PDF] UNIVERSITY OF SOUTHAMPTON 'Fertilization Kinetics in Marine ...
    Viability of sperm of the hydroid greatly exceeded that of the sea urchin. (several hours and <30mins respectively). Sperm release rates were also very ...
  38. [38]
    Ocean Acidification Increases Copper Toxicity to the Early Life ...
    Jul 17, 2014 · This is comparable to a 20% reduction in successful fertilization measured in the sea urchin Helicidaris erythrogramma under similar pH ...Missing: post- | Show results with:post-<|separator|>
  39. [39]
    Individual Variability in Reproductive Success Determines Winners ...
    Subsequent fertilization experiments showed strong inter-individual variation in responses to ocean acidification, ranging from a 44% decrease to a 14% increase ...
  40. [40]
    Ocean acidification compromises recruitment success of the ... - PNAS
    Nov 8, 2010 · The cumulative impact of OA on fertilization and settlement success is an estimated 52% and 73% reduction in the number of larval settlers on ...Missing: percentage | Show results with:percentage
  41. [41]
    Section 3: Life Cycle and Reproduction - EdTech Books
    Annelids exhibit diverse reproductive strategies, ranging from external fertilization in marine species to direct sperm transfer in terrestrial and freshwater ...
  42. [42]
    Sponge - Reproduction, Filtering, Habitat - Britannica
    Oct 26, 2025 · The fertilization of an egg by a spermatozoan is peculiar in sponges in that a spermatozoan, after its release from a sponge, is carried by ...
  43. [43]
    Phylum Porifera | manoa.hawaii.edu/ExploringOurFluidEarth
    Sponges also reproduce sexually when specialized gametocyte cells produce sperm and eggs. Sponges undergo synchronous spawning and eject sperm and egg cells ...Missing: external | Show results with:external
  44. [44]
    Density-dependent processes in cohorts of Tubifex tubifex, with ...
    eggs; their frequency distribution according to the clutch size is given in Table 2. Out of the 689 eggs,. 63 % hatched; after 40 days all embryos had either ...
  45. [45]
    Different aspects of reproduction strategies in crayfish: A review
    Crayfish have external fertilization (Hamr, 2002). As is well known, there are differences between the crayfish families in their genital morphology (e.g. ...
  46. [46]
    Orconectes rusticus (rusty crayfish) - Animal Diversity Web
    Males transfer sperm to the females, but external fertilization does not occur until the water temperature increases. The expelled eggs are fertilized by ...Scientific Classification · Reproduction · Behavior
  47. [47]
    Morphometry, size at maturity, and fecundity of marbled crayfish ...
    Fecundity parameters were confirmed to have a tight relationship to marbled crayfish size. Clutch size estimation can be used in future research based on the ...
  48. [48]
    Full article: Oviposition behaviour in the clitellate annelid Tubifex ...
    Mar 23, 2020 · The results show that oviposition behaviour in Tubifex is divided into four successive phases, i.e. cocoon formation around the clitellum, ...Missing: external | Show results with:external
  49. [49]
    Female freshwater crayfish adjust egg and clutch size in relation to ...
    Our results showed that females laid larger but fewer eggs for relatively small-sized, large-clawed males, and smaller but more numerous eggs for relatively ...
  50. [50]
    Marbled Crayfish - Invasive Species Centre
    Reports on the number of eggs that an individual female can produce per clutch has varied, but it is estimated to be between 200 and 700 eggs depending on body ...
  51. [51]
    Influence of seasonal flooding on macroinvertebrate abundance in ...
    Aug 10, 2025 · Typical of newly flooded or newly created (or both) wetlands, initial flooding events can promote relatively high invertebrate production as ...
  52. [52]
    Aquatic organisms respond to flooding and drought disturbance in ...
    Jan 30, 2023 · Populations of various species of aquatic insects and other invertebrates respond to flooding and waterway drying due to drought in different ways that can be ...Missing: spawning freshwater
  53. [53]
    Predicting the Effects of Climate Change on the Fertility of Aquatic ...
    Dec 31, 2024 · Our meta‐analysis revealed that external fertilisers tend to be more vulnerable to warming than internal fertilisers, especially in freshwater ...
  54. [54]
    Meta-analysis reveals temperature increase exacerbates ...
    Oct 27, 2025 · This study investigates the combined effects of microplastics and elevated temperatures on freshwater invertebrates using meta-analysis and ...
  55. [55]
    Sperm competition and fertilization mode in fishes - PMC
    The vast majority of the greater than 33 000 species of bony fishes reproduce using external fertilization, a broad term that describes the release of sperm ...
  56. [56]
    Shark Reproduction
    Nov 2, 2018 · Some female sharks can reproduce without a male to fertilise the eggs. This is known as Parthenogenesis (or 'virgin births'). This has been ...
  57. [57]
    Clownfish | Online Learning Center - Aquarium of the Pacific
    Jun 6, 2008 · The male swims behind the female and fertilizes the eggs. Between 100 and 1000 eggs are laid in several spawning passes, the number depending on ...
  58. [58]
    Atlantic Cod - NOAA Fisheries
    Cod spawn near the ocean floor from winter to early spring. Larger females can produce 3 to 9 million eggs when they spawn. They are top predators in the ...
  59. [59]
    Comparative dispersal of larvae from demersal versus pelagic ...
    Apr 30, 2025 · 1991, Black 1993). Pelagic eggs are generally smaller than demersal eggs, and usually produce smaller larvae (3 to 5 mm) (Thresher 1984) with ...
  60. [60]
    Diverse parentage relationships in paternal mouthbrooding fishes
    May 4, 2022 · Paternal mouthbrooding is a parental care strategy where the male parent incubates eggs/larvae in the buccal cavity to protect the offspring ...
  61. [61]
    Environmental salinity-induced shifts in sperm motility activation in ...
    In general, the sperm of marine fishes are activated by an increase in osmotic pressure (hypertonic salinity), and that of freshwater species by a decrease ( ...Missing: brackish | Show results with:brackish
  62. [62]
    Coral decline threatens fish biodiversity in marine reserves - PNAS
    Over 75% of reef fish species declined in abundance, and 50% declined to less than half of their original numbers. The greater the dependence species have on ...
  63. [63]
    Global decline in capacity of coral reefs to provide ecosystem services
    Sep 17, 2021 · At least 63% of coral-reef-associated biodiversity has declined with loss of coral extent. With projected continued degradation of coral reefs ...
  64. [64]
    Salamander Biodiversity and Conservation - VCE Publications
    Feb 12, 2020 · ... external fertilization, few (10 percent) salamanders exhibit external fertilization. In most salamanders, fertilization is internal. Male ...<|control11|><|separator|>
  65. [65]
    The Frog Life Cycle - Developmental Biology - NCBI Bookshelf - NIH
    In most species of frogs, fertilization is external. The male frog grabs the female's back and fertilizes the eggs as the female frog releases them (Figure 2.2B) ...
  66. [66]
    A review of the reproductive system in anuran amphibians
    Feb 13, 2023 · Amplexus results in external fertilization, when the male fertilizes the eggs as they are being released by the female.
  67. [67]
    The evolution of parental care in salamanders - PMC
    Oct 5, 2022 · Here we show that fertilisation mode is tied to parental care: male-only care occurs in external fertilisers, whereas female-only care exclusively occurs in ...
  68. [68]
    Egg predators improve the hatching success of salamander eggs - NIH
    Aug 22, 2023 · Previous studies show that these jelly layers provide eggs with protection against egg predators, egg pathogens, and desiccation. However, few ...
  69. [69]
    Shedding Light on Ultraviolet Radiation and Amphibian Embryos
    The ova of aquatic-breeding amphibians are surrounded by a number of capsules containing jelly that absorbs UVB radiation and helps shield the enclosed ova. The ...
  70. [70]
    Building a home from foam-tungara frog foam nest architecture and ...
    Dec 10, 2015 · Egg clutches averaged 2350 eggs, each egg being about 1.4 mm in diameter. Males were more abundant than females in traps. Communal foam ...
  71. [71]
    Fertilization mode differentially impacts the evolution of vertebrate ...
    Nov 10, 2022 · Fertilization mode thus influences vertebrate sperm evolution through complex component- and clade-specific evolutionary responses.
  72. [72]
    IUCN Red List of Threatened Species
    Amazing species. More than 48,600 species are threatened with extinction. That is 28% of all assessed species. Amphibians. 41%. Mammals. 26%. Conifers. 34%.About · 3.1 · IUCN Species Information... · Iconic Species
  73. [73]
    Genetic diversity and divergence among coastal and offshore reefs ...
    Genetic structure and diversity of the mass-spawning hard coral, Acropora tenuis, were assessed with seven DNA microsatellite loci from a series of isolated ...
  74. [74]
    Evolutionary consequences of environmental effects on gamete ...
    In externally fertilizing species, gametes are directly exposed to anthropogenically induced environmental impacts including pollution, ocean acidification and ...<|separator|>
  75. [75]
    Longevity, body dimension and reproductive mode drive differences ...
    May 25, 2020 · This pattern is likely linked to the prevalence of external fertilization in aquatic environments, while internal fertilization is more common ...
  76. [76]
    Modeling Fertilization Outcome in a Changing World
    Gamete performance of both sexes declined when exposed to elevated temperatures and/or pCO2 levels. Examples of reduced performance included slower sperm ...
  77. [77]
    Vocal communication in frogs - PubMed - NIH
    Each frog species produces distinctive calls that facilitate pre-mating reproductive isolation and thus speciation.
  78. [78]
    Multiple sexual signals: calls over colors for mate attraction in an ...
    Jun 4, 2014 · Nevertheless, acoustic signals are crucial for sexual selection in frogs, and males of O. pumilio use advertisement calls to attract females.
  79. [79]
    Male‐male competition and repeated evolution of terrestrial ...
    Nov 11, 2019 · We examine the diversification of reproductive modes, male and female body sizes, and sexual size dimorphism (SSD) in the Neotropical frog ...
  80. [80]
    Male-male competition drives sexual selection and group spawning ...
    Feb 23, 2016 · We considered male-male competition as the main driver of sexual selection and group spawning in this prolonged mating species because the cost ...
  81. [81]
    Male–male competition facilitates female choice in sticklebacks
    In the three–spined stickleback Gasterosteus aculeatus, male red breeding coloration plays a dual role in sexual selection by functioning as both a threat ...
  82. [82]
    A mechanism for cryptic female choice in chinook salmon
    Female mate choice after copulation or spawning is cryptic when a female differentially influences the fertilization success of sperm from different males. We ...<|separator|>
  83. [83]
    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 ...
  84. [84]
    [PDF] Density-Dependent Sexual Selection in External Fertilizers
    At low densities, both sexes may be under selection to increase fertilization success; at intermediate densities, males may compete; and at high densities, both ...
  85. [85]
    Sexual selection after gamete release in broadcast spawning ...
    Oct 19, 2020 · Broadcast spawning invertebrates offer highly tractable models for evaluating sperm competition, gamete-level mate choice and sexual conflict.Missing: freshwater | Show results with:freshwater