Fact-checked by Grok 2 weeks ago

Species

In biology, a species is the fundamental unit of biological classification and a key element of biodiversity, representing groups of organisms that share common evolutionary histories and ecological roles. The most widely used framework for defining species is the biological species concept, which describes a species as one or more populations of organisms that actually or potentially interbreed in nature to produce fertile offspring, while being reproductively isolated from other such groups. This concept, formalized by in 1942, emphasizes as the primary criterion for distinguishing species, particularly among sexually reproducing organisms. Despite its prominence, the biological species concept has limitations, such as its inapplicability to asexual like or to where reproductive data is unavailable, leading to the development of alternative frameworks. The morphological species concept defines based on consistent differences in physical traits, making it useful for identifying and a wide range of but prone to errors from where unrelated develop similar appearances. In contrast, the phylogenetic species concept identifies as the smallest monophyletic groups—clusters of sharing a common ancestor and distinguished by unique derived traits—relying on genetic and evolutionary data to delineate branches on the . The ecological species concept views a as a adapted to a specific or set of resources, with minimal overlap in resource use compared to other groups, as proposed by Leigh Van Valen in 1976. These concepts highlight the ongoing "species problem" in biology, where no single definition fully captures the complexity of life's diversity, and multiple approaches are often integrated depending on the context, such as , , or . Species serve as essential units for understanding , measuring , and informing efforts, as their delineation directly impacts assessments of risks and . For instance, recognizing distinct species is crucial for legal protections under frameworks like the Endangered Species Act, underscoring the practical implications of these definitions.

Species Concepts

Typological or Morphological Species Concept

The typological or morphological species concept defines species as discrete groups of organisms that share a common set of physical characteristics, such as shape, size, structure, or external appearance, treating them as fixed ideals or types distinct from one another. This approach emphasizes observable traits without accounting for individual variation or evolutionary processes, viewing species as static entities defined by their essential morphological features. Historically, it relies on visible anatomical differences for classification, originating from ancient philosophical ideas and becoming formalized in early modern taxonomy. The concept traces its roots to Aristotle's notion of eidos, or form, which described species as eternal, unchanging types characterized by a shared essence or ideal structure that individuals approximate. In the 18th century, advanced this framework in his (1758), using morphological similarities—such as reproductive organs in plants and overall body plans in animals—to delineate and name species hierarchically. , also contributed by stressing anatomical resemblance in his (1749–1788), grouping organisms based on structural similarities while noting environmental influences on form, though he critiqued rigid typologies. This concept has been applied extensively in , as seen in Linnaean classifications of like the genus (roses), where are distinguished by count, thorn arrangement, and shape, or in animals such as differentiated by and patterns. In , fossil are often identified solely by bone structure; for instance, early hominid like were delimited based on skull shape, jaw robusticity, and limb proportions from fragmentary remains. Despite its simplicity and utility in early , the typological has significant limitations, as it overlooks cryptic species—genetically distinct groups that appear morphologically identical, such as certain marine snails in the Littorina that were long lumped together until molecular studies revealed hidden . It also fails to address polytypic variation, where populations within a single species exhibit substantial morphological differences due to geographic or environmental factors, potentially leading to over-splitting or under-recognition of , as critiqued in analyses of taxa like the polytypic warbler Phylloscopus trochilus. These shortcomings prompted later shifts toward concepts incorporating .

Biological Species Concept

The biological species concept (BSC), introduced by in his 1942 book Systematics and the Origin of Species, emerged as a key component of the modern evolutionary synthesis, emphasizing population thinking over typological essentialism to align species delineation with Darwinian principles of variation and . This approach shifted focus from fixed morphological ideals to dynamic groups defined by reproductive interactions, reflecting Mayr's view that species boundaries arise from evolutionary processes maintaining genetic cohesion within populations. Under the BSC, a species is defined as the smallest group of individuals that actually or potentially interbreed to produce viable, fertile offspring in nature, while being reproductively isolated from other such groups by intrinsic barriers that prevent . This isolation ensures the integrity of the , allowing species to evolve as semi-independent units in response to selection pressures. The concept applies primarily to sexually reproducing organisms, where successful interbreeding maintains species cohesion, but it excludes taxa that do not engage in such exchanges. Reproductive isolation mechanisms are categorized into pre-zygotic barriers, which prevent or fertilization, and post-zygotic barriers, which reduce the of ./18:_Evolution_and_the_Origin_of_Species/18.02:_Formation_of_New_Species/18.2B:_Reproductive_Isolation) Pre-zygotic examples include temporal (different seasons), behavioral (incompatible rituals), and mechanical (mismatched genitalia)./18:_Evolution_and_the_Origin_of_Species/18.02:_Formation_of_New_Species/18.2B:_Reproductive_Isolation) Post-zygotic barriers encompass inviability (embryos fail to develop) and sterility ( survive but cannot reproduce)./18:_Evolution_and_the_Origin_of_Species/18.02:_Formation_of_New_Species/18.2B:_Reproductive_Isolation) The BSC excels in delimiting species among animals with clear sexual reproduction but faces limitations when applied to asexual organisms, such as bacteria or many plants, where reproduction occurs via cloning or parthenogenesis without interbreeding. It also struggles with fossil records, as reproductive behaviors cannot be observed in extinct taxa, relying instead on indirect morphological proxies. Illustrative examples include (Geospiza species) on the , recognized as distinct species due to behavioral isolation via learned mating songs and preferences that limit interbreeding despite occasional hybridization. Similarly, (Equus caballus) and donkeys (Equus asinus) form separate species because their hybrids, mules, exhibit post-zygotic sterility due to chromosomal mismatches (64 in horses, 62 in donkeys), preventing fertile offspring. Critiques of the BSC highlight its inapplicability to allopatric populations, where geographic separation prevents testing potential interbreeding, potentially over-splitting isolated groups. Additionally, it inadequately addresses ongoing in hybrid zones, where low-level blurs species boundaries despite partial isolation.

Phylogenetic or Cladistic Species Concept

The phylogenetic or cladistic species concept defines a species as the smallest diagnosable cluster of individual organisms within which there is a parental pattern of ancestry and descent, emphasizing —all descendants of a common ancestor—and diagnosability through unique derived traits known as synapomorphies. This approach views species as branches on the , where shared derived characteristics distinguish evolutionary lineages from others, rather than relying on current or alone. Rooted in , it prioritizes historical evolutionary relationships over reproductive criteria, making it a cornerstone of modern phylogenetic . The foundational principles of this concept trace back to Willi Hennig's 1950 publication Grundzüge einer Theorie der phylogenetischen Systematik, which introduced cladistic methods to reconstruct evolutionary trees based on shared derived traits. Hennig argued that monophyletic groups, identified by synapomorphies, represent natural classificatory units, influencing subsequent refinements like Joel Cracraft's 1983 formulation of the phylogenetic species concept as diagnosable clusters. Modern applications integrate molecular phylogenetics, where DNA sequences help construct cladograms—branching diagrams depicting hypothesized evolutionary relationships—and assess diagnosability through fixed genetic or morphological differences between lineages. In practice, cladograms are built using parsimony or maximum likelihood methods to minimize evolutionary changes and infer ancestry, with species delimited as the smallest monophyletic groups showing consistent apomorphies (derived traits unique to the clade). For instance, African elephants (Loxodonta africana and L. cyclotis) form a distinct clade from Asian elephants (Elephas maximus), separated by approximately 6 million years of divergence and supported by synapomorphic genetic markers in mitochondrial DNA and morphological traits like skull shape. Similarly, DNA sequencing has split bird taxa into new species under this concept, such as distinguishing the Sri Lankan white-eye (Zosterops ceylonensis) from the Oriental white-eye (Z. palpebrosus) based on fixed nucleotide differences and monophyletic clustering in phylogenetic trees. This concept offers key advantages by applying universally to all life forms, including fossils—where synapomorphies in preserved traits allow lineage delimitation—and asexual organisms, which lack interbreeding but can be grouped by shared ancestry without invoking . It shifts focus to evolutionary history, enabling the recognition of cryptic species invisible under other concepts and supporting assessments through phylogenetic diversity metrics. Despite these strengths, the concept faces challenges, particularly the arbitrary selection of the "smallest" , as hierarchical branching in phylogenies can yield multiple nested clades without a clear cutoff for species boundaries. Debates also arise over in rapidly evolving taxa, where incomplete lineage sorting or historical hybridization can produce conflicting gene trees, complicating the identification of exclusive synapomorphies and leading to over-splitting of lineages.

Evolutionary Species Concept

The evolutionary species concept, introduced by in 1951, defines a species as a single lineage comprising an ancestral-descendant sequence of populations that evolves separately from other lineages, maintaining its own distinct evolutionary fate, historical tendencies, and identity through both time and space. This view bridges historical and process-based perspectives on species, emphasizing evolutionary independence rather than static traits or immediate interactions. Central to this concept is the temporal continuity of , which can endure via anagenesis—the gradual within a without splitting—or , where a branches into multiple descendant . In , it proves especially valuable, enabling the delineation of species through observable changes in records, such as morphological adaptations, without reliance on reproductive or genetic data unavailable in extinct forms. For instance, the horse exemplifies this as a , tracing gradual transformations from the small, four-toed () of the Eocene epoch, with its browser-adapted teeth and forest-dwelling habits, to the large, single-toed grazing of the Pleistocene, marked by increases in body size, limb elongation, and over approximately 55 million years. Similarly, hominid s demonstrate this through progressive morphological shifts, such as increasing cranial capacity and bipedal adaptations from early australopiths to later forms, forming connected in the leading to modern humans. In relation to other frameworks, the evolutionary species concept integrates aspects of phylogenetic —recognizing species as distinct branches on the —but extends beyond snapshot analyses by accommodating continuous over time, without mandating complete isolation in reproduction or . However, it faces critiques for practical challenges in application to living taxa, where insufficient long-term observational data hinders determination of true lineage separation, and for potential overlap with designations, which can render species boundaries subjective in cases of slow, transitional change.

Ecological Species Concept

The ecological species concept defines a species as a , or a closely related set of lineages, that occupies an adaptive zone or minimally different from that of any other lineage in its range, evolving separately from lineages in distinct zones. This approach emphasizes species as sets of exploiting similar resources, habitats, or functional roles within their , with boundaries maintained by ecological divergence rather than solely by reproductive or genetic criteria. The concept was formally articulated by Leigh Van Valen in 1976, who argued for integrating ecological adaptation as a core criterion for recognizing evolutionary units, particularly in cases where traditional is ambiguous, such as in oaks and other challenging taxa. Central to this concept are processes like niche partitioning, where drives competing populations to specialize on different resources or environmental conditions, thereby minimizing overlap and competition. Such partitioning fosters ecological divergence and can lead to , in which new species emerge without geographic barriers, primarily through selection for distinct adaptive roles. Unlike concepts focused on , this framework highlights how environmental pressures shape species cohesion, with potentially limited by ecological barriers that reduce hybrid fitness in mismatched niches. Illustrative examples include on the , where closely related species have differentiated primarily through beak morphology adapted to specific food sources—such as large seeds for ground finches or for warbler finches—demonstrating how ecological selection on niches drives during . In rift lakes, fishes provide another paradigm: in , species like Pundamilia pundamilia and P. nyererei have diverged by exploiting contrasting habitats (rocky vs. sandy shores), with genetic adaptations in visual pigments enabling niche-specific mate recognition and resource use under varying water clarity. The ecological species concept excels at elucidating parapatric and , where species form along environmental gradients or within shared ranges, and proves valuable for or clonal organisms like microbes and many , where reproductive barriers are irrelevant. It shifts emphasis from to current functional roles, aiding understanding of community assembly and maintenance. However, limitations arise in cases of niche overlap, where gradual transitions between adaptive zones can obscure clear species boundaries, and it applies poorly to fossils, as inferring historical niches from preserved alone is often unreliable.

Genetic Species Concept

The genetic species concept defines species as distinct clusters of individuals exhibiting high genetic similarity and within the cluster, separated from other clusters by substantial that reflects and independent evolutionary trajectories. This approach emphasizes measurable genetic discontinuities rather than , viewing species as panmictic units where maintains cohesion internally while barriers prevent it externally. Sub-approaches within this concept include single-locus DNA barcoding, which uses standardized gene regions like the mitochondrial cytochrome c oxidase subunit I () gene in animals to identify species based on a divergence threshold of approximately 2-3%, indicating a "barcode gap" between intra- and inter-species variation. Multilocus phylogenetics extends this by analyzing multiple nuclear or mitochondrial loci to reconstruct evolutionary relationships and detect cohesive genetic clusters, often employing coalescent models to account for gene tree discordance. Whole-genome sequencing further refines delimitation by identifying panmictic clusters through genome-wide patterns of linkage disequilibrium and allele sharing, revealing species boundaries even in taxa with low divergence at single loci. Key tools and metrics operationalize this concept, such as the Barcode of Life Data Systems (BOLD) database, which stores and analyzes sequences to facilitate species identification and via automated calculations. Population is quantified using FST statistics, where values above 0.25 often signal significant genetic between clusters, complementing phylogenomic trees constructed from thousands of loci to visualize . These methods provide quantitative thresholds, like Birky's where inter-cluster exceeds four times the expected intra-cluster variation (4Neμ, with Ne as and μ as ). Representative examples illustrate its application; in insects, DNA barcoding has revealed barcode gaps uncovering cryptic species, such as the neotropical skipper butterfly Astraptes fulgerator, initially considered one morphospecies but delineated into ten genetically distinct clusters based on COI variation exceeding 2.2%. Similarly, human and chimpanzee genomes exhibit approximately 1.2% sequence divergence, underscoring clear genetic separation between these species despite shared ancestry.64096-8) This concept offers advantages in objectivity, as it relies on empirical genetic data independent of subjective morphological assessments, making it applicable across all taxa, including asexual organisms where breeding tests fail. It excels at detecting hidden biodiversity, such as cryptic species in diverse groups like , by revealing genetic discontinuities that traditional methods overlook. Challenges persist, including the selection of appropriate loci, as single-gene approaches like may underestimate divergence in cases of incomplete lineage sorting or . In , horizontal gene transfer disrupts cluster cohesion by introducing foreign DNA, complicating delineation of stable genetic units. For viruses, the quasispecies model describes populations as dynamic genetic clouds with high mutation rates and no fixed boundaries, rendering traditional clustering ineffective.

Challenges in Species Delimitation

Problems with Uniform Definitions

The species problem refers to the longstanding challenge in of defining species in a manner that applies universally across all forms of life, a debate that traces back to Charles 's recognition that species boundaries may be arbitrary rather than discrete natural entities. argued that the difficulty arises from the gradual nature of evolutionary change, making it hard to draw sharp lines between varieties and true species, particularly when intermediate forms exist. This issue persists because no single species concept adequately encompasses the diversity of reproductive modes, ecological contexts, and evolutionary histories observed in organisms, leading to calls for where multiple concepts are applied contextually rather than a uniform definition. Core difficulties stem from the mismatch between concepts designed for sexually reproducing animals and other life forms, such as organisms, s, microbes, and hybrids. For instance, the biological species concept, which emphasizes , fails for obligately groups like bdelloid rotifers, where no interbreeding occurs yet distinct lineages have evolved independently, challenging the notion of species as reproductively cohesive units. Similarly, species delimitation relies on morphological stasis over time, but incomplete preservation and lack of genetic data make boundaries subjective and context-dependent, often resulting in polyphyletic groupings under traditional that do not reflect evolutionary —such as certain genera of sea slugs historically lumped together despite deriving from multiple ancestral lineages. In microbes, particularly , species definitions grapple with high genetic exchange via , rendering concepts based on descent or isolation impractical and highlighting the need for genomic similarity thresholds that vary by . These examples illustrate how uniform definitions overlook the continuum of evolutionary processes, such as in where adjacent populations interbreed but distant ones do not, blurring categorical lines. Philosophically, the species problem pits —viewing species as convenient human-imposed labels without objective reality—against , which posits species as natural kinds or individuals with inherent boundaries shaped by evolutionary forces. gains traction from incomplete data and the arbitrary nature of taxonomic decisions, while supports the idea that species represent spatiotemporally bounded entities, though often reveals fuzzy edges due to or . Incomplete sampling exacerbates these debates, as undiscovered intermediates can redefine boundaries, underscoring the provisional nature of species classifications. In response, modern approaches advocate integrative taxonomy, which combines , , , and geography to delimit species without relying on a single criterion, thereby addressing context-dependency across taxa. This pluralistic framework, supported by multi-locus data and coalescent models, has proven effective for resolving cryptic diversity in both sexual and asexual lineages, promoting more robust and verifiable delimitations. By integrating evidence, it mitigates the pitfalls of uniform definitions while advancing assessment.

Hybridization and Gene Flow

Hybridization refers to the interbreeding of individuals from different species, resulting in hybrid offspring that can facilitate —the transfer of genetic alleles between species through viable and fertile . This process introduces novel genetic variation, potentially blurring species boundaries by allowing alleles from one species to integrate into the of another via and . Hybridization occurs naturally more frequently in plants than in animals, where it is rarer but still significant; for instance, at least 10% of animal are known to hybridize with others, often involving closely related taxa. Two main types include homoploid hybridization, which does not involve changes in number and typically results in fertile hybrids through recombination, and allopolyploid hybridization, common in , where chromosome doubling creates new polyploid with combined parental genomes. These events can lead to adaptive , where beneficial alleles from one species spread into another, enhancing fitness in novel environments. Notable examples illustrate these dynamics: in , coyotes (Canis latrans) hybridize with gray wolves (Canis lupus), producing fertile hybrids known as eastern coyotes, which carry approximately 58% coyote, 28% wolf, and 14% ancestry. Similarly, European gray wolves hybridize with domestic s (Canis lupus familiaris), leading to widespread admixture documented across the continent, with up to 25% dog ancestry in some wolf populations. In , sunflower species such as Helianthus annuus and form fertile homoploid hybrids like Helianthus anomalus, which occupy extreme dune habitats through adaptive combinations of parental traits. Evolutionarily, hybridization can drive by generating novel genetic combinations that establish new lineages, as seen in the sunflower , or reverse it by eroding genetic distinctions through persistent . However, reproductive barriers often limit extensive ; Dobzhansky-Muller incompatibilities—epistatic interactions between diverged loci from parental species—reduce viability or fertility, maintaining species integrity despite occasional mating. To quantify , genomic techniques like mapping employ molecular markers to identify segments of introgressed DNA, revealing the extent and direction of transfer in hybrid zones.

Ring Species and Microspecies Aggregates

Ring species represent a geographic pattern where a chain of interbreeding populations forms a roughly circular distribution around a barrier, such that adjacent populations freely exchange genes, but the terminal populations at the ring's ends are reproductively isolated from one another. This configuration arises from sequential expansions and adaptations, often driven by environmental gradients, leading to gradual divergence without discrete boundaries. A classic example is the Ensatina eschscholtzii salamander complex in California, where seven subspecies form a ring around the Central Valley; neighboring forms hybridize, but the southernmost and northernmost populations do not interbreed and show distinct morphologies and behaviors. Similarly, the greenish warbler (Phylloscopus trochiloides) exhibits a ring around the Tibetan Plateau, with two reproductively isolated forms in northern Siberia connected by intergrading populations to the south, demonstrating parallel evolution in song and plumage. The Larus gull complex was formerly proposed to illustrate this pattern, with herring-like gulls suggested to form a ring around the Arctic via stepwise expansions, where eastern and western ends overlap without interbreeding; however, genetic studies have refuted this, showing multiple independent colonizations rather than a single ring. Microspecies aggregates, in contrast, occur primarily in plants through apomixis—a form of —or hybrid polyploid complexes, resulting in swarms of morphologically similar but genetically distinct lineages that challenge traditional species delimitation. These aggregates often arise from repeated hybridization and genome duplication, producing numerous microspecies within a broader complex. For instance, the dandelion genus () includes thousands of apomictic microspecies in , where diploid sexual ancestors hybridize to form polyploid derivatives that vary subtly in shape and features but maintain due to their clonal propagation. The blackberry subgenus Rubus (Rubus subg. Rubus) forms a similar aggregate, with over 300 microspecies in alone, characterized by facultative and hybridization among a few sexual species, leading to diverse thorniness and fruit traits. Hawkweeds () represent an extreme case, with the subgenus Pilosella encompassing hundreds of microspecies in apomictic complexes driven by reticulate evolution, where subtle differences in pappus hairs and phyllary shapes define each entity. These patterns complicate species delimitation by illustrating clinal variation and gradual divergence, where persists locally but breaks down over distance or through clonal barriers, raising questions about whether the entire structure constitutes one polytypic species or multiple distinct ones. In , the lack of clear across the chain suggests ongoing , yet the isolated ends imply completed divergence, prompting taxonomists to either recognize the ring as a single species with or split based on diagnosability of terminal forms. For microspecies aggregates, resolution often involves treating each diagnosable lineage as a separate agamospecies under the biological or phylogenetic concepts, though some classifications group them into broader complexes to reflect their evolutionary interdependence. Evolutionarily, both phenomena highlight as a continuum, providing insights into how spatial isolation and reproductive modes can blur species boundaries without abrupt transitions.

Taxonomy and Nomenclature

Scientific and Common Names

The scientific naming of species follows the system, which assigns a unique two-part Latin or Latinized name to each species: the name (capitalized and italicized) followed by the specific (lowercase and italicized). For example, the binomial name for humans is Homo sapiens. This system, introduced by , ensures universality and stability in identifying organisms across scientific disciplines. In , the (ICZN), governed by the , mandates that species names consist of a binomen ( + specific ), while subspecies use a trinomen (adding a subspecific ). The ICZN's 4th edition (1999), still in effect as of 2025, specifies that the name begins with an uppercase letter and the specific with a lowercase letter, both italicized in print or underlined in handwriting. For , , and fungi, the International Code of Nomenclature for algae, fungi, and (ICN), overseen by the International Association for Plant Taxonomy, applies similar rules but uses "subsp." for rather than "ssp." The ICN's 18th edition (Madrid Code, 2025) confirms the binomial format, with the starting point being Linnaeus's (1753). Scientific names include an authority citation attributing the name to its describer and the year of publication, such as Homo sapiens Linnaeus, 1758, referencing Linnaeus's Systema Naturae (10th edition, 1758), the starting point for zoological nomenclature. The principle of priority governs validity: the earliest validly published name takes precedence, with junior synonyms suppressed to avoid confusion. For instance, if a later name is proposed for the same taxon, it becomes a synonym unless the senior name is conserved by ruling. Publication requires the name to appear in a scientific work with a description or diagnosis, ensuring traceability. Common names, or names, provide accessible alternatives to scientific binomials, varying by , , and ; for example, Orcinus orca is known as "killer whale" in English but "orque" or "épaulard" in . These names enhance public and communication in non-scientific contexts, such as and outreach, by being more intuitive and memorable. However, they lack standardization, leading to ambiguities where the same name applies to different species across regions (e.g., "robin" for Erithacus rubecula in and Turdus migratorius in ) or multiple names for one species, potentially hindering precise identification. Abbreviations simplify references in scientific literature: "sp." (or "spec." in botany) denotes an unidentified or unspecified species within a genus, as in Pinus sp., while "spp." (plural) indicates multiple species, such as Pinus spp. For subspecies, "ssp." (zoology) or "subsp." (botany) precedes the subspecific epithet, e.g., Canis lupus ssp. familiaris. These follow ICZN and ICN conventions to maintain clarity without full repetition. Species are further identified using standardized codes in databases. The (NCBI) Taxonomy Database assigns unique taxonomy identifiers (TaxIDs), numerical codes for each (e.g., TaxID 9606 for Homo sapiens), facilitating genomic and phylogenetic research across public sequence databases. The International Union for Conservation of Nature (IUCN) uses assessment codes for on its Red List, such as CR (), EN (Endangered), VU (Vulnerable), NT (Near Threatened), and LC (Least Concern), to categorize extinction risk based on criteria like and habitat loss. These codes support global biodiversity monitoring and policy.

Species Description Process

The process of describing a new species begins with the collection and examination of specimens, which serve as the foundational evidence for establishing its distinctiveness. Taxonomists typically gather multiple individuals from natural populations to capture variability, focusing on type specimens that anchor the description. The , a single designated specimen, is selected as the name-bearing type to ensure stability in ; additional paratypes provide supporting material for intraspecific variation. Detailed documentation includes morphological characteristics, such as anatomical features and measurements, alongside genetic data like sequences and ecological details, including habitat preferences and behaviors, to support a comprehensive . A valid species description requires a clear diagnosis highlighting unique traits that differentiate the new taxon from closely related species, often through comparative analysis with existing taxa. This involves illustrating key features via photographs, drawings, or micrographs and providing quantitative data where relevant, such as body size ranges or genetic divergence metrics. The holotype and paratypes must be deposited in recognized public institutions, such as natural history museums or herbaria, to ensure accessibility for future verification and study; private collections are generally insufficient under nomenclatural codes. For animals, the (ICZN) mandates this deposition, while the International Code of Nomenclature for algae, fungi, and (ICN) applies similar requirements for botanical taxa. For prokaryotes ( and ), the International Code of Nomenclature of Prokaryotes (ICNP, 2022 Revision) applies similar principles, requiring deposition of type strains in recognized culture collections. Publication formalizes the description and establishes , requiring submission to peer-reviewed scientific journals that adhere to nomenclatural codes. The must include the species' —explaining the origin of the scientific name, often derived from Latin or roots reflecting location, morphology, or honorees—and ensure the name complies with formatting ( ). Availability of the name depends on meeting these criteria, including explicit indication of the new (e.g., "sp. nov."). Modern descriptions increasingly incorporate DNA sequences, deposited in public databases like , as essential components, enhancing reproducibility and enabling phylogenetic placement. Integrative approaches combine morphological, molecular, and ecological evidence to address limitations of single-data methods, promoting robust delimitations. For instance, the description of in 2004 relied on fossil specimens from cave, , integrating morphological analysis of the (LB1 skeleton) with initial genetic considerations to distinguish it from other hominins based on small stature and primitive traits. In , new bacterial species like Pseudomonas fragariae (described in 2024) are validated using whole-genome average nucleotide identity (ANI) below 95% to closest relatives, in addition to 16S rRNA sequences for placement, phenotypic tests, and deposition of strains in culture collections. These examples illustrate how multidisciplinary data strengthen descriptions across domains. Despite standardized protocols, challenges persist, including the loss or destruction of holotypes due to historical events like wars or poor preservation, which complicates verification and may necessitate neotype designation under ICZN or ICN rules. Cryptic species—morphologically indistinguishable but genetically distinct—often require molecular confirmation, delaying descriptions until DNA is obtained from types or topotypes, as traditional alone fails to detect them. These issues underscore the need for robust preservation and integrative methods to mitigate taxonomic instability.

Lumping, Splitting, and Identification

In , lumping refers to the practice of merging previously distinct taxa into a single when new evidence, such as genetic analyses, reveals greater similarity than previously recognized, often treating former synonyms or as variants within one entity. Conversely, splitting involves dividing a recognized into multiple distinct species upon of overlooked morphological, genetic, or behavioral variations that indicate or evolutionary divergence. These practices reflect differing taxonomic philosophies: lumpers for broader species boundaries emphasizing shared traits, while splitters prefer narrower definitions highlighting subtle differences. The choice between lumping and splitting is heavily influenced by the underlying species concept employed, such as the biological species concept favoring for splitting or the phylogenetic species concept promoting splits based on diagnosable lineages. For instance, advances in have prompted splits in cases where DNA sequences uncover cryptic species—morphologically similar but genetically distinct populations previously lumped together. A prominent example is the 2022 splitting of the Eastern Meadowlark (Sturnella magna) into (S. magna) and Chihuahuan Meadowlark (S. lilianae) by the , driven by genomic data revealing distinct evolutionary lineages and differences in vocalizations despite similar plumage. On the lumping side, debates persist regarding s (Homo neanderthalensis), with some researchers proposing their inclusion within an expanded Homo sapiens taxon due to evidence of interbreeding and shared behavioral complexity, supported by genomic admixture estimates of 1-2% Neanderthal DNA in non-African modern humans. These taxonomic revisions contribute to ongoing debates, notably "taxonomic inflation," where the application of stricter criteria, particularly from molecular data, has led to a rapid increase in described species counts—estimated at over 20% for vertebrates since the —by elevating to full species status without proportional discoveries of new taxa. Such inflation can enhance priorities by highlighting but also risks instability in species lists if driven more by conceptual shifts than empirical novelty. Species identification relies on standardized tools like dichotomous keys, which guide users through sequential pairs of contrasting characteristics—such as leaf shape or habitat preference—to narrow possibilities to a single , often drawing from validated species descriptions for accuracy. Modern approaches include community-driven platforms like , where users upload observations and receive identifications through crowdsourced expertise and algorithmic suggestions, facilitating over 100 million verified records annually for monitoring. Emerging and methods, particularly convolutional neural networks trained on image datasets, enable automated recognition with accuracies exceeding 90% for common plants and animals by analyzing visual features like color patterns or silhouettes, though they require large, diverse training data to handle variability.

Species Dynamics

Speciation Mechanisms

is the evolutionary process by which new species arise from existing ones through the accumulation of genetic differences that lead to . This process typically begins with populations becoming separated or diverging within the same area, allowing mechanisms such as , , and to drive changes in allele frequencies. Over time, these changes can result in barriers to gene flow, solidifying distinct species. The primary modes of speciation are classified based on the geographic context of divergence: allopatric, parapatric, and sympatric. Allopatric speciation occurs when populations are geographically isolated, preventing and allowing independent . This mode can arise through vicariance, such as the formation of physical barriers like mountains or rivers, or dispersal, where a subset of a colonizes a new area. and mutations accumulate randomly in small isolated populations, while adapts them to local environments. A classic example is the of the , where ancestral populations dispersed to separate islands, leading to adaptive divergence in beak morphology driven by dietary specialization; genomic analyses show that isolation initiated divergence approximately 1-2 million years ago, with ongoing in secondary contact zones. Parapatric speciation involves populations in adjacent habitats with limited across a , where selection gradients favor different traits on either side, such as in ecotones between and . Here, divergence proceeds gradually as hybrids in the face reduced , promoting of isolating mechanisms. Sympatric speciation happens within the same geographic area without physical separation, often triggered by ecological or behavioral factors that reduce . In , —a form of —plays a key role, where hybridization between species followed by chromosome doubling creates fertile offspring reproductively isolated from parents due to ploidy mismatches. For instance, many angiosperms, like those in the genus , arose via allopolyploidy during the last century in . In animals, is rarer but evident in adaptive radiations, such as African cichlid fishes in , where sensory drive and on male nuptial coloration led to over 500 species in under 15,000 years through disruptive selection on habitat preferences. Key mechanisms underlying all modes include , which randomly fixes alleles in small populations, introducing novel , and favoring adaptive traits. Sexual selection, particularly through , accelerates by reinforcing prezygotic barriers, while strengthens postzygotic isolation in hybrid zones by selecting against unfit hybrids. The timeline of speciation varies: initial isolation may take generations to establish barriers, followed by over thousands to millions of years, as seen in genomic studies of fish where islands—regions of high differentiation—emerge early due to linked selection. Speciation rates differ markedly; adaptive radiations exhibit rapid bursts, with cichlids in East African lakes showing high speciation rates during early phases when ecological niches are abundant. In contrast, anagenesis—linear evolution within a —proceeds slowly, forming , which are sequential forms in records connected by gradual morphological change without branching, such as in the mammalian genus over 20 million years. Modern genomic evidence, including whole-genome sequencing, reveals that divergence often involves heterogeneous patterns, with reduced at loci under selection, supporting as a creative pathway in both plants and animals.

Inter-Species Gene Exchange

Inter-species gene exchange refers to the transfer of genetic material between distinct species after their initial divergence, primarily through mechanisms such as hybridization in eukaryotes and horizontal gene transfer (HGT) in prokaryotes. In eukaryotes, hybridization occurs when individuals from different species mate, leading to fertile hybrids that can backcross with parental populations, resulting in introgression where segments of DNA from one species are incorporated into the genome of another. This process is facilitated by incomplete reproductive barriers and can occur in plants, animals, and fungi, often in regions of secondary contact. In prokaryotes, HGT is a dominant mode of gene exchange, occurring via three main mechanisms: transformation, where free DNA is taken up from the environment; conjugation, mediated by direct cell-to-cell contact often involving plasmids; and transduction, where bacteriophages (viruses) transfer DNA between cells. Plasmids and viruses play crucial roles in disseminating mobile genetic elements across bacterial species boundaries. Detection of inter-species gene exchange relies on genomic signatures that deviate from expected vertical patterns. Phylogenetic incongruence, where gene trees for different loci conflict with the overall species phylogeny, often indicates HGT or , as transferred genes cluster with donor species rather than the recipient's lineage. (LD), the non-random association of alleles at linked loci, is another key indicator; recent creates elevated LD blocks around transferred segments that decay over time due to recombination. Advanced methods, such as modeling and haplotype-based statistics like S*, further distinguish introgressed regions by analyzing spectra and LD patterns across populations. These approaches have revealed exchange events in diverse taxa, from to . Notable examples illustrate the prevalence and consequences of inter-species gene exchange. In microbial evolution, HGT has contributed to approximately 10-20% of protein-coding genes in many bacterial genomes, enabling rapid adaptation to new environments. For instance, antibiotic genes spread via plasmids and phages across bacterial species, conferring survival advantages in clinical settings. In eukaryotes, from Neanderthals into modern humans accounts for about 1-2% of the genome in non-African populations, influencing traits like and skin pigmentation. These exchanges highlight how post-speciation can introduce beneficial alleles, such as those enhancing . The impacts of inter-species gene exchange are multifaceted, offering adaptive advantages while potentially leading to genomic homogenization. In prokaryotes, HGT facilitates the rapid dissemination of traits like antibiotic resistance, allowing to evade treatments and colonize new niches faster than through alone. This can reverse speciation-like by merging genetic pools, blurring species boundaries in microbial communities. In eukaryotes, provides novel for , but excessive can homogenize differentiated populations, counteracting and challenging species delimitation—particularly in cases of hybridization that complicate taxonomic boundaries. Overall, these dynamics underscore HGT's role in accelerating . Evolutionarily, inter-species gene exchange profoundly shapes prokaryotic by promoting a reticulate rather than strictly tree-like phylogeny, where frequent HGT obscures traditional species concepts and drives innovations like metabolic versatility. In contrast, such exchanges are rarer in eukaryotes due to and cellular barriers, yet when they occur, they exert influential effects by introducing adaptive alleles that enhance in changing environments. This asymmetry highlights HGT's centrality to microbial evolution while positioning as a sporadic but potent force in multicellular lineages.

Extinction Processes

Extinction is the permanent loss of all individuals of a species from the global population, rendering it unable to reproduce or persist. In contrast, , also known as extirpation, occurs when a species disappears from a defined geographic or while surviving elsewhere, often due to isolated pressures that do not affect the entire range. Background extinction represents the steady, low-level turnover of species through natural processes over geological time, typically at a rate of about one species per million species per year, allowing for evolutionary replacement. Mass extinction events, however, involve abrupt, widespread losses exceeding 75% of species within a short period, driven by catastrophic global disruptions that overwhelm adaptive capacities. Natural causes of species extinction encompass gradual shifts in environmental conditions, such as fluctuations or geological alterations, that exceed a species' evolutionary adaptability, leading to declines. Ecological interactions, including heightened for limited resources among co-occurring or intensified predation that disrupts stability, can also drive extinctions by favoring more resilient competitors or predators. In small populations, events—random demographic fluctuations, genetic bottlenecks, or chance catastrophes like localized disasters—amplify extinction risk by reducing and increasing vulnerability to minor perturbations, even in the absence of deterministic pressures. Anthropogenic factors have accelerated rates far beyond natural baselines, primarily through loss and fragmentation from land conversion for and , which isolates populations and reduces viable breeding areas. , via unsustainable , , and harvesting, depletes populations faster than they can recover, as seen in historical cases of commercial . introduces toxins and alters biogeochemical cycles, impairing reproduction and survival across ecosystems, while —often human-transported—outcompete or prey upon natives, cascading through food webs. exacerbates these by shifting temperature regimes, precipitation patterns, and sea levels, forcing species into unsuitable s or intensifying existing stressors. Current rates are estimated at 1,000 times the background level, with approximately 41% of species threatened, highlighting the scale of human impact. Illustrative examples underscore these processes: the dodo (Raphus cucullatus), a endemic to , was hunted to by the late as European sailors targeted it for easy meat, compounded by introduced predators like rats and pigs that raided nests. The (Ectopistes migratorius), once numbering in billions across North American forests, succumbed to through market hunting in the , with flocks decimated for food and feathers, leading to the last individual's death in captivity in 1914. On a grander scale, the Permian-Triassic mass extinction around 252 million years ago eradicated approximately 96% of marine species, likely triggered by massive volcanic eruptions releasing greenhouse gases and causing ocean . Perceived recoveries from extinction include Lazarus taxa, which vanish from the fossil record for extended periods—potentially due to rarity, habitat shifts, or preservation biases—only to reemerge later, as with the fish (Latimeria spp.), absent in fossils for 66 million years before living specimens were discovered in 1938. Modern initiatives seek to reverse losses through biotechnology, such as cloning the (Mammuthus primigenius) by inserting its genome into elephant cells via editing, aiming to restore ecological roles in ecosystems, though ethical and feasibility challenges persist. As of 2025, researchers at reported success in creating genetically modified mice with mammoth-like traits, such as thicker fur, as a proof-of-concept toward engineering mammoth-elephant hybrids. These processes of loss and potential revival contribute to the broader evolutionary turnover, where balances to shape over time.

Practical Applications

Conservation and Biodiversity

In conservation biology, the delineation of species units plays a pivotal role in prioritizing protection efforts, particularly through concepts like evolutionarily significant units (ESUs), which identify distinct populations within species that warrant separate safeguarding due to their unique genetic and evolutionary histories. ESUs, first conceptualized as intraspecific conservation targets, help preserve genetic diversity essential for long-term adaptability and are often used to guide decisions on which subpopulations to protect independently. Complementing this, the International Union for Conservation of Nature (IUCN) Red List employs standardized criteria to categorize species based on extinction risk, including assessments of population decline rates, geographic range, habitat fragmentation, and population size, resulting in classifications such as Critically Endangered, Endangered, and Vulnerable. These categories inform global policy by quantifying threats and directing resources toward species facing imminent extinction. Biodiversity is quantified using metrics that emphasize both the variety and distribution of species within ecosystems. measures the total number of species in a given area, providing a indicator of , while evenness assesses how evenly individuals are distributed among those species, highlighting beyond mere counts. At broader scales, captures within-habitat variation, reflects differences between habitats, and encompasses regional totals, enabling comparisons across landscapes and aiding in the identification of priorities. These metrics collectively support efforts by revealing patterns of loss or recovery, though they often integrate with abundance-based indices like the or Simpson for a more nuanced view. Challenges in applying species concepts to conservation arise from cryptic species—morphologically similar but genetically distinct taxa—that inflate biodiversity estimates when overlooked, potentially leading to underestimation of true diversity and fragmented protection strategies. For instance, cryptic diversity is prevalent in insects and marine organisms, complicating global tallies and requiring molecular tools for accurate delineation. Taxonomic instability, driven by ongoing revisions and splits or lumps of species, further disrupts policies by altering legal protections; a taxon split may leave newly recognized entities unprotected under existing laws, while lumping can dilute focus on vulnerable subpopulations. Such flux underscores the need for stable, evidence-based taxonomy to ensure consistent application in biodiversity assessments and regulations. Conservation strategies leverage species units to implement targeted interventions, including the establishment of protected areas that safeguard habitats for multiple taxa and captive breeding programs that bolster populations of endangered species through controlled reproduction and reintroduction. These ex-situ efforts, often conducted in zoos or reserves, maintain genetic viability while in-situ measures like national parks preserve ecological roles. Additionally, phylogenetic diversity metrics prioritize "evolutionary distinctiveness," measuring the unique branch lengths on species' evolutionary trees to favor conservation of lineages with irreplaceable histories, thus maximizing retained biodiversity per unit effort. This approach, rooted in Faith's phylogenetic diversity framework, shifts focus from species counts to evolutionary heritage, enhancing long-term resilience. Illustrative examples highlight these principles: the serves as a , channeling public and financial support toward broader habitat protection in China's bamboo forests, thereby benefiting co-occurring endangered taxa like the . Similarly, coral reefs function as biodiversity hotspots, occupying less than 1% of the ocean floor yet harboring about 25% of all marine species, underscoring the urgency of reef-specific strategies amid threats like bleaching. Post-2020 global assessments, building on frameworks like the IPBES and IUCN evaluations, confirm that approximately 1 million species face extinction risk, driven by habitat loss and , with one-quarter of assessed plants and animals now threatened, necessitating accelerated action through integrated species-focused policies.

Biomedical and Agricultural Uses

In biomedical research, certain species serve as model organisms to elucidate genetic and developmental processes relevant to human health. Drosophila melanogaster, the fruit fly, has been extensively utilized for studying and the biochemical underpinnings of diseases due to its sophisticated genetic tools and rapid life cycle. Similarly, the (Danio rerio) is valued for its genetic and physiological similarities to humans, enabling investigations into and disease modeling. These models facilitate high-throughput experiments that accelerate discoveries in areas such as neurodegeneration and cancer. Drug discovery often draws from species diversity, harnessing natural compounds for therapeutic applications. A prominent example is paclitaxel, derived from the bark of the Pacific yew tree (Taxus brevifolia), which inhibits cancer cell division and has become a cornerstone treatment for breast, ovarian, and lung cancers. This compound's identification underscores the role of biodiversity in yielding novel pharmaceuticals with low toxicity and high efficacy. In agriculture, knowledge of crop wild relatives informs breeding programs to enhance resilience and yield. Wild emmer wheat (Triticum dicoccoides), an ancestor of modern durum wheat, provides genetic diversity for traits like heat stress resistance and improved grain quality, including higher micronutrient content such as iron and zinc. Breeders incorporate these relatives to develop varieties adapted to climate challenges, thereby sustaining global food security. Accurate identification of pest species is crucial for targeted control measures in . Advances in and imaging technologies enable real-time detection of pests like and beetles, allowing for precise interventions that minimize crop damage and reduce use. For instance, models such as YOLOv5 have been adapted for systems to classify and monitor invasive insects, supporting . Industrial biotechnology leverages specific microbial species for efficient production of therapeutics and environmental solutions. Escherichia coli has been engineered to express recombinant human insulin since the late 1970s, revolutionizing treatment by enabling large-scale, cost-effective of this . In , bacteria like Pseudomonas putida degrade organic pollutants such as hydrocarbons, while species including Enterobacter asburiae and Bacillus cereus remove from contaminated soils through precipitation and . Studies of , the diverse mutant populations within viruses, have informed development for diseases like COVID-19. Analysis of SARS-CoV-2 quasispecies in infected individuals revealed patterns that guided the design of mRNA vaccines, enhancing their effectiveness against emerging variants by targeting conserved regions. Genetically modified (GM) crops, such as , incorporate genes from bacterial species via hybridization techniques to confer pest resistance, boosting yields in regions like without relying solely on chemical controls. Ethical considerations in these applications center on , the exploration of species for commercial gain, which raises issues of equitable benefit-sharing. The , adopted under the , mandates prior and fair distribution of benefits from genetic resources, addressing historical inequities where indigenous communities received minimal returns from exploited . Looking ahead, promises to engineer novel "species" or modified organisms for targeted applications. By redesigning microbial pathways, researchers aim to create bio-based solutions for , such as nitrogen-fixing crops, and advanced therapeutics, potentially transforming industries with programmable biological systems that respond to environmental cues.

Historical Development

Ancient and Classical Views

In , Aristotle conceptualized species as fixed, eternal forms known as eide, embodying the essential characteristics and purposes of living beings. These forms were arranged hierarchically in the scala naturae, or ladder of nature, progressing from inanimate objects through plants, , and humans based on the complexity of their souls and capacities for sensation and reason. Aristotle's classification in works like and Parts of Animals emphasized morphological and functional traits, such as the presence of to distinguish major groups, while asserting the immutability of : "If anything can be eternal on earth, it is the eidos of men and ." This essentialist framework influenced Roman , as seen in Pliny the Elder's Natural History, an encyclopedic compilation that described and classified animals based on observable morphology and behaviors without invoking mutability. Pliny treated as stable, divinely ordained kinds, organizing them into broad categories like quadrupeds, , and , often drawing from Aristotelian traditions but adding anecdotal details on habitats and uses. His approach reinforced the view of as unchanging entities within a created order. During the medieval period, scholastic philosophers integrated Aristotelian ideas with , portraying species as immutable kinds directly created by God to reflect divine order. Thinkers like viewed species as fixed essences instantiated in individuals, where reproduction preserved the original created form, aligning with the Biblical notion in that creatures reproduce "after their kind." This immutability underscored a teleological where species occupied eternal positions in the , with no provision for transformation. In the early , naturalists such as Conrad Gesner advanced descriptive cataloging of species as fixed morphological kinds rooted in . Gesner's Historia Animalium (1551–1558) illustrated and classified organisms based on shared structures and breeding consistency, treating them as distinct, God-given entities without variation beyond superficial differences. Herbalists like and Andrea Cesalpino similarly emphasized stable forms through detailed observations of and fructification, laying groundwork for while upholding species fixity. further advanced this by introducing in the 10th edition of Systema Naturae (1758), defining species as the smallest fixed units of based on reproductive constancy and morphological similarity, solidifying their role in systematic . European voyages of discovery began challenging this static view by revealing geographic variations, as articulated by , who proposed that species originated from a common stock but could produce "races" adapted to environments through degeneration. In his (1749–1788), Buffon argued that reproductive isolation defined species boundaries, yet acknowledged potential mutability, marking a transition from absolute immutability toward more dynamic conceptions.

Modern Evolutionary Perspectives

Charles Darwin's On the Origin of Species (1859) fundamentally shifted perspectives on species by portraying them as transient varieties arising through natural selection rather than fixed, immutable entities. Darwin emphasized that species represent no more than well-marked, permanent varieties, blurring the boundary between them and underscoring the gradual, continuous nature of evolutionary change without proposing a rigid definition. This view positioned species as dynamic outcomes of descent with modification, influencing subsequent evolutionary thought by highlighting their provisional status in the tree of life. The Modern Synthesis of the 1930s and 1940s reconciled Darwinian with Mendelian , establishing a unified framework for understanding at the level. Key figures like integrated these fields, introducing the biological species concept in 1942, which defined species as groups of actually or potentially interbreeding natural populations reproductively isolated from other such groups. This synthesis emphasized genetic mechanisms driving divergence, providing a mechanistic basis for that contrasted with earlier typological views. Post-synthesis developments in the 1970s saw the rise of , pioneered by Willi Hennig, which prioritized monophyletic groups based on shared derived characters to reconstruct evolutionary relationships, challenging phenetic and evolutionary approaches. By the 1980s, molecular clocks—calibrating evolutionary divergence using constant rates of genetic change—emerged as tools for timing events, while phylogenomics advanced through genome-wide analyses to resolve deep evolutionary histories. Landmark events, such as the 1953 discovery of DNA's double-helix structure by Watson and Crick, enabled the genetic underpinnings of species concepts by revealing heredity's molecular basis. The Project's completion in 2003 further illuminated interspecies divergence, with comparative sequencing showing about 1.2% nucleotide differences between humans and chimpanzees, underscoring genomic fluidity in evolutionary lineages. Debates intensified with Niles Eldredge and Stephen Jay Gould's 1972 proposal of , arguing that occurs rapidly in small, isolated populations—geologically brief "punctuations"—followed by long periods of , rather than uniform gradualism. This model highlighted allopatric 's role in generating evolutionary patterns observed in the fossil record. Ongoing pluralism in species concepts persists, recognizing that no single definition suffices across taxa, with biological, phylogenetic, and ecological criteria applied contextually. In contemporary , integrative combines morphological, genetic, ecological, and distributional data for robust species delimitation, addressing cryptic diversity and hybridization. Network thinking reframes species as dynamic processes within interconnected webs of and interaction, accommodating reticulate beyond bifurcating trees. These perspectives link to broader by emphasizing ongoing evolutionary flux.

References

  1. [1]
    Ernst Mayr and the modern concept of species - PNAS
    Apr 25, 2005 · For example, the biological species concept emphasizes the property of reproductive isolation (9, 21), the ecological species concept emphasizes ...
  2. [2]
    Biological species concept - Understanding Evolution
    The biological species concept defines a species as members of populations that actually or potentially interbreed in nature, not according to similarity of ...
  3. [3]
    Species concept and speciation - PMC - NIH
    In another words a species is a group of reproducing natural populations incapable to effectively mate or breed with other such groups, and which inhabits a ...<|control11|><|separator|>
  4. [4]
    Why Should We Care about Species? | Learn Science at Scitable
    In his book, On the Origin of Species, Darwin famously wrote, "I was much struck how entirely vague and arbitrary is the distinction between species and ...What Is A Species? How Do We... · Two Classic Viewpoints On... · Identifying Species With The...<|control11|><|separator|>
  5. [5]
    4 Important Species Concept (With Criticism) - Biology Discussion
    1. Typological Species Concept: ... According to this concept, there are a number of diversities on the surface of the earth that exist as a limited number of ...
  6. [6]
    Typological species concept - Oxford Reference
    The concept of a species as a group whose members share certain characteristics that distinguish them from other species. This Aristotelian concept was applied ...<|control11|><|separator|>
  7. [7]
    Aristotle: Biology | Internet Encyclopedia of Philosophy
    “Human” is the species, “animal” is the genus and “rationality” is the differentia. In a similar way, Aristotle adapts his logical theory of genus and species ...The Scope of Aristotle's... · The Biological Practice... · The more and the less” and...Missing: typological | Show results with:typological
  8. [8]
    Species Concepts - UBC Zoology
    1. The typological species concept: A species is a set of organisms that resemble one another and is distinct from other sets (Linnaeus). But:.
  9. [9]
    Identifying Fossils and the Nature of Species - UMD Geology
    Feb 12, 2024 · The science of comparative anatomy was developed to describe, compare, and contrast the homologous structures of different kinds of organisms.
  10. [10]
    Multilevel fine-scale diversity challenges the 'cryptic species' concept
    May 1, 2019 · A cryptic species definition was suggested for those species which manifest low morphological, but considerable genetic, disparity.
  11. [11]
    [PDF] Species: Concepts and Categories - Banaras Hindu University
    Typological/Morphological/ Essentialistic Species. Concept: This is the first concept of species which was explained in detail by Linnaeus and his followers in ...
  12. [12]
    Synthesizer's Parting Words: Ernst Mayr Reflects on Evolutionary ...
    Aug 1, 2005 · Mayr's biological species concept stated that “species are groups of actually or potentially interbreeding natural populations, which are ...
  13. [13]
    Species & speciation (article) - Khan Academy
    Species are separated from one another by prezygotic and postzygotic barriers, which prevent mating or the production of viable, fertile offspring. Speciation ...
  14. [14]
    Role of sexual imprinting in assortative mating and ... - PNAS
    Oct 22, 2018 · We provide evidence that two species of Darwin's finches choose mates on the basis of learning morphological features of their parents and possibly from ...
  15. [15]
    [PDF] Species Concepts in Ornithology
    Cracraft (1983: 170) espoused a phylogenetic species concept (PSC) as an alternative to the BSC: “A species is the smallest diagnosable clus- ter of individual ...
  16. [16]
    Phylogenetics and the origin of species - PMC - NIH
    For example, a phylogenetic species as defined by Cracraft (10) constitutes “the smallest diagnosable cluster of individual organisms within which there is a ...
  17. [17]
    From Taxonomy to Phylogenetics: Life and Work of Willi Hennig ...
    Feb 26, 2014 · ... published the original German version of Hennig's 1966 book. It appears that Willi Hennig and his wife were wonderful parents, and this is ...
  18. [18]
    Phylogenetics of modern birds in the era of genomics - PMC
    The first phylogenetic analysis of higher categories of birds based on DNA sequence data appeared in 1991 (Edwards et al. 1991), soon after the completion of ...
  19. [19]
    [PDF] Phylogenetic Analysis (Cladistics) - Integrative Biology |
    Monophyletic groups are defined using synapomorphies; they include the common ancestor and all descendants with the new trait. For example, the group tetrapods ...
  20. [20]
    Molecular and morphological evidence on the phylogeny of the ...
    The African and Asian elephants and the mammoth diverged ca. 4–6 million years ago and their phylogenetic relationship has been controversial.
  21. [21]
    Birding and DNA: species for the new millennium
    Mar 29, 2010 · Examples are given in the form of 'case studies', and include Carrion/Hooded Crows Corvus corone/cornix, Green-winged/Eurasian Teals Anas ...
  22. [22]
    Chapter 6: Species Concepts – Introductory Biology 2
    The phylogenetic species concept resolves some of the problems of the biological species concept since it can be applied to asexual species and those for which ...
  23. [23]
    The Impact of Species Concept on Biodiversity Studies
    Most prominently, it is widely thought that use of a phylogenetic species concept may lead to recognition of a far greater number of much less inclusive units.
  24. [24]
    Species delimitation based on diagnosis and monophyly, and its ...
    A recently proposed taxonomic classification of extant ungulates sparked a series of publications that criticize the Phylogenetic Species Concept (PSC) ...
  25. [25]
    [PDF] Species, Concepts of - Mallet Group
    The important features of species defined by the “biological species concept” were that they were protected from gene flow by physiological isolating mechanisms ...
  26. [26]
    THE SPECIES CONCEPT - EVOLUTION - Wiley Online Library
    The genetical definition of a species as. Page 4. 288. GEORGE GAYLORD SIMPSON a group of actually or potentially inter- breeding organisms reproductively iso-.
  27. [27]
    The hominin fossil record: taxa, grades and clades - PubMed Central
    This paper begins by reviewing the fossil evidence for human evolution. It presents summaries of each of the taxa recognized in a relatively speciose hominin ...
  28. [28]
    [PDF] The General Lineage Concept of Species, Species Chteria, and the ...
    "An evolutionary species is a lineage (an ancestral-descendant sequence of popu- lations) evolving separately from others and with its own unitary evolutionary ...
  29. [29]
    Biodiversity and the Species Concept—Lineages are not Enough
    Hull (1965) felt that Simpson did not provide sufficient criteria to circumscribe role, but this is an operational criticism rather than a conceptual one—that ...
  30. [30]
    Species Concepts - Evolutionary Genetics
    Species concepts include typological, biological, evolutionary, genealogical, and ecological, each with different definitions and limitations.<|control11|><|separator|>
  31. [31]
    Ecological Species, Multispecies, and Oaks - jstor
    ecological species concept is similar to ecological interpretations of higher taxa ... VAN VALEN, L. I966 - On discussing human races. Persp. Biol. Med. 9: 377- ...
  32. [32]
    Resource Partitioning and Why It Matters | Learn Science at Scitable
    Resource partitioning helps to explain how seemingly similar species can coexist in the same ecological community without one pushing the others to extinction ...
  33. [33]
    Demonstrating the Theory of Ecological Speciation in Cichlids
    Dec 5, 2006 · The rapid evolution of African cichlid fish driven by strong divergent selection is revealed in a gene that influences both ecological ...
  34. [34]
    Every inch a finch: a commentary on Grant (1993) 'Hybridization of ...
    Apr 19, 2015 · The 1993 paper makes it clear that Darwin's finches are an instance of ecological speciation in the presence of hybridization. The species ...
  35. [35]
    Ecological and morphological determinants of evolutionary ...
    Nov 10, 2020 · Darwin's finches are a classic example of adaptive radiation, a process by which multiple ecologically distinct species rapidly evolve from a single ancestor.
  36. [36]
    Using Population Genetic Theory and DNA Sequences for Species ...
    Two reviewers of earlier versions of this paper argued that the clusters we call species could be local populations or demes within one or a few species.
  37. [37]
    SPECIATION IN MAMMALS AND THE GENETIC SPECIES CONCEPT
    This focus on genetic isolation rather than reproductive isolation distinguishes the Genetic Species Concept from the Biological Species Concept.
  38. [38]
    Genetics in geographically structured populations: defining ...
    This Review clarifies how F ST is defined, how it should be estimated, how it is related to similar statistics and how estimates of F ST should be interpreted.
  39. [39]
    Ten species in one: DNA barcoding reveals cryptic species in the ...
    Oct 1, 2004 · Ten species in one: DNA barcoding reveals cryptic species in the neotropical skipper butterfly Astraptes fulgerator.
  40. [40]
    Darwin's solution to the species problem | Synthese
    Apr 11, 2009 · This paper offers a different approach to the species problem. We should be skeptical of the species category, but not skeptical of the existence of those taxa ...
  41. [41]
    Mystery of mysteries: Darwin and the species problem - PubMed
    Darwin offered an intriguing answer to the species problem. He doubted the existence of the species category as a real category in nature, but he did not ...
  42. [42]
    Species Concepts: A Case for Pluralism - Oxford Academic
    Brent D. Mishler, Michael J. Donoghue; Species Concepts: A Case for Pluralism, Systematic Biology, Volume 31, Issue 4, 1 December 1982, Pages 491–503, http.
  43. [43]
    Independently Evolving Species in Asexual Bdelloid Rotifers
    We show that a famous group of asexual animals, the bdelloid rotifers, has diversified into distinct species broadly equivalent to those found in sexual groups.
  44. [44]
    Polyphyly of the traditional family Flabellinidae affects a major group ...
    The Flabellinidae, a heterogeneous assembly of supposedly plesiomorphic to very derived sea slug groups, have not yet been addressed by integrative studies.
  45. [45]
    Genomics and the bacterial species problem
    Sep 29, 2006 · What we want from a species definition is a set of easily applied and stable rules by which to decide when two organisms are similar enough in ...Missing: challenges | Show results with:challenges
  46. [46]
    Is it time to abandon the biological species concept? No - PMC
    Jun 2, 2020 · The biological species concept (BSC) was designed to aid understanding of biological diversity, particularly the ubiquitous observation that ...
  47. [47]
    Species: kinds of individuals or individuals of a kind - Rieppel - 2007
    May 9, 2007 · The thesis of this paper is that species are not either individuals, or natural kinds. Instead, species are complex wholes (particulars, individuals) that ...
  48. [48]
    (PDF) Species Concepts - ResearchGate
    The species is one of the most fundamental units in biology. However, there are different concepts of what is meant by the term 'species' that reflect diverse ...
  49. [49]
    Species, Kinds, and Evolution | National Center for Science Education
    Organisms that are descended from sexual organisms are sometimes asexual ... And finally let us consider the problems of identifying species in fossils.
  50. [50]
    Integrative taxonomy and geographic sampling underlie successful ...
    Apr 12, 2021 · Species delimitation requires a broad assessment of population-level variation using multiple lines of evidence, a process known as integrative taxonomy.INTRODUCTION · CRITERIA FOR SPECIES... · SPECIES DELIMITATION IN...
  51. [51]
    Integrative taxonomy by molecular species delimitation: multi-locus ...
    Jun 6, 2017 · Taxonomy offers precise species identification and delimitation and thus provides basic information for biological research, e.g. through ...
  52. [52]
    Coalescent-based species delimitation in an integrative taxonomy
    Coalescent-based species delimitation will play an important role in an integrative taxonomy that emphasizes the identification of species limits.
  53. [53]
    Hybridization and Gene Flow | Learn Science at Scitable - Nature
    Hybridization between species can allow alleles from one genetic background to integrate into another if favored by selection.
  54. [54]
    Hybridization and hybrid speciation under global change
    May 23, 2016 · Interspecific hybridization is a regular natural phenomenon and it is estimated that as many as 25% of plant species and 10% of animal species ...<|control11|><|separator|>
  55. [55]
    Whole-genome sequence analysis shows that two endemic species ...
    Jul 27, 2016 · We converted these rates to admixture proportions and observed high proportions of coyote gene flow into the red wolf (48 to 88%) and high ...
  56. [56]
    Widespread, long‐term admixture between grey wolves and ...
    The occurrence of hybridisation between grey wolves and domestic dogs is well documented from different parts of the wolf geographic range.
  57. [57]
    Evolutionary Genetics of Hybrid Incompatibility - Nature
    The Dobzhansky-Muller model predicts that hybrid incompatibility will be due to interactions between at least two genes (one from each species), but both ...
  58. [58]
    [PDF] Irwin, DE, and Wake, DB (2016) Ring Species
    Ring species are a chain of intergrading subspecies forming a loop, where terminal forms no longer interbreed, connected by a chain of populations.
  59. [59]
    Ring species as bridges between microevolution and speciation
    We review proposed cases of ring species and the insights they provide into speciation. Ring species have been viewed both as illustrations of the history of ...
  60. [60]
    CIRCULAR OVERLAPS: RARE DEMONSTRATIONS OF SPECIATION
    Jul 1, 2002 · Such a historical approach has been used to study speciation in two ring species, the Ensatina salamanders and the Greenish Warblers ( ...Missing: definition seminal
  61. [61]
    [PDF] How apomictic taxa are treated in current taxonomy: A review
    Oct 5, 2017 · Apomixis occurs in plant genera in which hybridization together with polyploidization play an important role in diversification and causes ...
  62. [62]
    [PDF] Concealed diversity - WUR
    Apr 4, 2017 · To illustrate this, the numbers of microspecies in Rubus, Taraxacum and Hieracium are ... apomictic blackberries (Rubus subgen. Rubus). Watsonia ...
  63. [63]
    Evolutionary aspects in Hieracium subgenus Pilosella | Request PDF
    The hawkweed Hieracium subgenus Pilosella (Cichoriae, Asteraceae) is known for its notoriously complicated taxonomic structure due to ongoing reticulate ...
  64. [64]
    (PDF) Ring Species - ResearchGate
    May 24, 2016 · The biological complexity of Ensatina argues against a simple taxonomic resolution ... polytypic taxonomic species. View. Show abstract. Animal ...
  65. [65]
    Article 5. Principle of Binominal Nomenclature
    Binominal nomenclature uses two names for a species: a generic name (uppercase) and a specific name (lowercase). Subspecies use three names (trinomen).Missing: ICN | Show results with:ICN
  66. [66]
    International Code of Nomenclature for algae, fungi, and plants
    Jul 21, 2025 · The International Code of Nomenclature for algae, fungi, and plants is the set of internationally agreed rules and recommendations that ...
  67. [67]
    [PDF] Writing Plant Names - American Public Gardens Association
    Jun 9, 2020 · A species name comprised of a genus name and specific epithet is also known as a binomial. Example: Pinus strobus. Page 4. Page | 3. Rank ...
  68. [68]
    Linnaean Names — Dumbarton Oaks
    Linnaeus's Species plantarum (1753) became his crowning achievement, arranging almost 6,000 species ... starting point of modern botanical nomenclature.
  69. [69]
    Article 23. Principle of priority
    The Principle of Priority continues to apply to an available name when treated as a junior synonym; it may be used as the valid name of a taxon by an author ...Missing: ICN | Show results with:ICN
  70. [70]
    The International Code of Nomenclature for algae, fungi, and plants
    The International Code of Nomenclature for algae, fungi, and plants, known as “the Code,” is the set of internationally agreed rules and recommendations that ...
  71. [71]
    8. The problem with "common" names
    Common names seldom get used in more than one country. Where they do so, they may get applied to different species -- the bird that is called robin in England ...
  72. [72]
    Choosing The Best Common Names For Plants - bplant.org
    Apr 19, 2024 · Common names can provide continuity through taxonomic changes, and also have the advantage of being in widespread use and more accessible. ...
  73. [73]
    How to Write Scientific Names of Plants and Animals | AJE
    Sep 14, 2022 · Scientific names are two-part, in italics, with the capitalized genus first, then the species epithet. Abbreviate after the first full write ...<|control11|><|separator|>
  74. [74]
    Article 16. Names published after 1999
    In zoological works genus-group names are often abbreviated to one or two letters; such abbreviations should always be followed by a full stop (period), and ...Missing: ICN | Show results with:ICN
  75. [75]
    Home - Taxonomy - NCBI - NIH
    The Taxonomy Database is a curated classification and nomenclature for all of the organisms in the public sequence databases.Taxonomy browser · Taxonomy Name/Id Status... · Taxonomy Help · Genetic Codes
  76. [76]
    NCBI Taxonomy - NIH
    Apr 7, 2011 · Each TaxNode has a stable, unique numerical identifier, the taxonomy identifier (TaxId). Each TaxId has a labelled primary name (a formal or ...
  77. [77]
    IUCN Red List of Threatened Species
    It provides information about range, population size, habitat and ecology, use and/or trade, threats, and conservation actions that will help inform necessary ...About · 3.1 · IUCN Species Information... · Iconic Species
  78. [78]
    How to describe a new species in zoology and avoid mistakes
    May 3, 2024 · Abstract. Taxonomy is the science of discovering, naming, describing, diagnosing, identifying, and classifying different kinds of taxa, ...Missing: ICN | Show results with:ICN
  79. [79]
    The Code Online | International Commission on Zoological ...
    The system of nomenclature in which a species, but no taxon of any other rank, is denoted by a combination of two names (a binomen, q.v.). zoological ...
  80. [80]
    How do we describe a new species? | Institute of Natural Sciences
    How do we describe a new species? · 1. Writing the Species Description · 2. Naming the New Species · 3. Designating the Type Specimen · 4. Peer Review and ...
  81. [81]
    The integrative future of taxonomy | Frontiers in Zoology | Full Text
    May 25, 2010 · Here we review perspectives for an integrative taxonomy that directly bear on what species are, how they can be discovered, and how much diversity is on Earth.
  82. [82]
    Pseudomonas fragariae sp. nov., a novel bacterial species causing ...
    Aug 14, 2024 · Pseudomonas fragariae sp. nov., a novel bacterial species causing leaf spots on strawberry (Fragaria×ananassa)
  83. [83]
    Adapting practices to accelerate the scientific description of ...
    Oct 1, 2025 · Researchers often delay the description of cryptic species until they can obtain DNA from the morphospecies holotype/paratype(s) or designate a ...
  84. [84]
    How to describe a cryptic species? Practical challenges of molecular ...
    Sep 27, 2013 · To describe cryptic species traditional lines of evidence in taxonomy need to be modified. DNA sequence information, for example, could even serve as the ...
  85. [85]
    Lumpers and Splitters - American Ornithological Society
    May 17, 2018 · Lumpers favor placing similar populations under one species, while splitters seek to identify distinct populations as separate species.
  86. [86]
    Lumping and splitting - Science
    Mar 23, 2018 · Lumpers prefer broader categories that include items that share important features despite some differences; splitters prefer narrower categories.
  87. [87]
    Taxonomic inflation: its influence on macroecology and conservation
    Species numbers are increasing rapidly. This is due mostly to taxonomic inflation, where known subspecies are raised to species as a result in a change in ...
  88. [88]
    Machine learning for image based species identification - Wäldchen
    Aug 13, 2018 · In this paper, we give a brief introduction into the state-of-the-art in machine learning techniques applicable for automated species identification.
  89. [89]
    Chihuahuan Meadowlark Overview, All About Birds, Cornell Lab of ...
    In 2022, the American Ornithological Society split Chihuahuan Meadowlark from Eastern Meadowlark based on genomic data and differences in vocalizations. It ...
  90. [90]
    Were Neanderthals and Homo sapiens 'good species'?
    Mar 1, 2023 · The likelihood that Homo sapiens and Neanderthals admixed has long been debated, mostly on the basis of phenotypic assessments alone.
  91. [91]
    Taxonomic Inflation and the Stability of Species Lists
    They suggest that as a consequence of taxonomic inflation, taxonomy suffers from great uncertainty and species lists change too often, compromising current ...Missing: counts | Show results with:counts
  92. [92]
    Taxonomic Keys - an overview | ScienceDirect Topics
    Taxonomic keys are tools for identifying organisms using questions with two choices, narrowing down possibilities to one, often using dichotomous keys.
  93. [93]
    iNaturalist accelerates biodiversity research - Oxford Academic
    Jul 28, 2025 · Abstract. Participatory citizen science is expanding, with iNaturalist emerging as one of the most widely used platforms globally.bibliometric analysis to... · iNaturalist usage is growing... · Future outlook and key...
  94. [94]
    Sympatric, parapatric or allopatric: the most important way to classify ...
    Jun 3, 2008 · The most common classification of modes of speciation begins with the spatial context in which divergence occurs: sympatric, parapatric or allopatric.
  95. [95]
    The secondary contact phase of allopatric speciation in Darwin's ...
    Here, we report the establishment and persistence of a reproductively isolated population of Darwin's finches on the small Galápagos Island of Daphne Major in ...
  96. [96]
    Hybrid speciation in plants: new insights from molecular studies
    Nov 17, 2004 · In the genus Senecio (Asteraceae), for example, the native UK species S. vulgaris (tetraploid) has hybridised on at least two separate occasions ...
  97. [97]
    African cichlid fish: a model system in adaptive radiation research
    The African cichlid fish radiations are the most diverse extant animal radiations and provide a unique system to test predictions of speciation and adaptive ...
  98. [98]
    Natural selection in action during speciation - PMC - NIH
    A high Fst marker seen late in speciation or in a hybrid zone is more likely to be the result of genetic drift or a recent selective sweep within 1 species ...
  99. [99]
    Widespread genomic divergence during sympatric speciation - PNAS
    For example, the divergence observed throughout the Rhagoletis genome was clearly accentuated in some regions, such as those harboring chromosomal inversions.
  100. [100]
    Chronospecies' longevities, the origin of genera, and the ...
    Apr 8, 2016 · The survivorship curve reveals that all but a small fraction of established chronospecies have long durations relative to intervals of time ...
  101. [101]
    Contrasting signatures of genomic divergence during sympatric ...
    Oct 28, 2020 · Genomic studies on the early stages of speciation with gene flow have found that differentiation between incipient species is commonly ...
  102. [102]
    Horizontal Gene Transfer: From Evolutionary Flexibility to Disease ...
    May 18, 2020 · HGT Mechanisms in Prokaryotes. In nature, transformation, transduction, and conjugation are the principal mechanisms of HGT. Other mechanisms ...
  103. [103]
    Pathways for horizontal gene transfer in bacteria revealed by a ...
    Jul 17, 2020 · Plasmids can mediate horizontal gene transfer of antibiotic resistance, virulence genes, and other adaptive factors across bacterial populations.
  104. [104]
    Decoding genomic landscapes of introgression - ScienceDirect.com
    Jul 23, 2025 · Introgression: the phenomenon of transferring genetic material across genetically divergent lineages. Linkage disequilibrium (LD): the ...
  105. [105]
    Adaptive introgression: an untapped evolutionary mechanism for ...
    Jul 30, 2018 · A recently developed statistic, S*, uses linkage disequilibrium information to detect introgressed haplotypes when no information about the ...
  106. [106]
    Empirical Evidence That Complexity Limits Horizontal Gene Transfer
    2022), contributing 10–20% of the protein-coding genes to most bacterial genomes (Lawrence and Ochman 1998; Nakamura et al. 2004; Soucy et al.
  107. [107]
    Horizontal Gene Transfer Mediated Bacterial Antibiotic Resistance
    Horizontal gene transfer (HGT) allows bacteria to exchange their genetic materials (including antibiotic resistance genes, ARGs) among diverse species (Le Roux ...
  108. [108]
    What does it mean to have Neanderthal or Denisovan DNA?
    Jun 23, 2022 · The percentage of Neanderthal DNA in modern humans is zero or close to zero in people from African populations, and is about 1 to 2 percent in ...
  109. [109]
    Horizontal gene transfer potentiates adaptation by reducing ... - PNAS
    Oct 14, 2020 · We show that HGT can help antibiotic resistance genes establish at a low frequency in a population, even in the absence of the antibiotic. We ...
  110. [110]
    Speciation with gene flow via cycles of isolation and migration
    Gene flow is conventionally perceived as a homogenizing force that can reverse population divergence and block speciation (black line in Fig. 4e). This has been ...
  111. [111]
    Conservation - Population Loss, Habitat Destruction, Extinction
    Oct 29, 2025 · Some scientists use the term extirpation for local extinctions, reserving extinction to mean global extinction. In this section on factors ...
  112. [112]
    Gradations of Extinction - Arnold Arboretum
    May 12, 2025 · Extirpation, also local extinction, refers to the termination of a species within a chosen geographic area of study. While the species is still ...
  113. [113]
    [PDF] EEB 2208: TOPIC 5 EXTINCTION RATES - Chris Elphick
    A) DEFINITIONS. • Extinction = no members of a species remain alive. • Local extinction = gone from a particular area. • Extirpation = local extinction.
  114. [114]
    Extinction Over Time | Smithsonian National Museum of Natural ...
    The passenger pigeon is one of many hundreds of extinctions that have been caused by human activities in the past few centuries, such as: 1690 Dodo bird – ...Missing: overexploitation 96%
  115. [115]
    What is mass extinction and are we facing a sixth one?
    May 19, 2021 · This is known as the background rate of extinction. A mass extinction event is when species vanish much faster than they are replaced. This is ...
  116. [116]
    Mass extinctions - Understanding Evolution
    Extinctions occur continually, generating a “turnover” of the species living on Earth. This normal process is called background extinction. Sometimes, however, ...Missing: definition | Show results with:definition
  117. [117]
    Species extinction - Coastal Wiki
    Feb 23, 2024 · Extinction can be a natural occurrence caused by an unpredictable catastrophe, chronic environmental stress, or ecological interactions such as ...Missing: stochastic | Show results with:stochastic
  118. [118]
    Adaptation, extinction and global change - PMC - NIH
    We discuss three interlinked issues: the natural pace of environmental change and adaptation, the likelihood that a population will adapt to a potentially ...
  119. [119]
    Environmental Variation, Stochastic Extinction, and Competitive ...
    We reconcile these two perspectives by showing that in the presence of demographic stochasticity, environmental variation can increase the chance of extinction ...
  120. [120]
    Five drivers of the nature crisis - UNEP
    Sep 5, 2023 · Reducing air and water pollution and safely managing chemicals and waste is crucial to addressing the nature crisis. Direct exploitation of ...
  121. [121]
    The greatest threats to species - Conservation Biology - Wiley
    Mar 26, 2022 · ... overexploitation, invasive species/diseases/genes, pollution, and climate change. ... over potential habitat require roughly 57 and 460 ...
  122. [122]
    State of the World's Amphibians: A Roadmap for Action
    Mar 20, 2025 · 41% of amphibians are globally threatened with extinction, making them the most threatened vertebrate group. Salamanders are particularly at ...
  123. [123]
    Ongoing declines for the world's amphibians in the face of emerging ...
    Oct 4, 2023 · We find that amphibians are the most threatened vertebrate class (40.7% of species are globally threatened). The updated Red List Index shows ...Missing: background | Show results with:background
  124. [124]
    The world's species are playing musical chairs: how will it end?
    Aug 4, 2021 · ... current rates are 1,000 times the background level. One calculation estimates that, if high rates continue, then within 14,000 years, we ...
  125. [125]
    Dodo | Bird, History, Extinction, & Facts | Britannica
    The birds were first seen by Portuguese sailors about 1507 and were exterminated by humans and their introduced animals. The dodo was extinct by 1681, the ...
  126. [126]
    Overexploitation - Sam Noble Museum - The University of Oklahoma
    Extinction of the passenger pigeon seems to have influenced other species. The acorns of the north red oak were an important food source for the pigeon during ...<|separator|>
  127. [127]
    What caused Earth's biggest mass extinction?
    Dec 6, 2018 · Some 96 percent of marine species were wiped out during the "Great Dying," followed by millions of years when life had to multiply and diversify ...
  128. [128]
    No mass extinction for land plants at the Permian–Triassic transition
    Jan 23, 2019 · The end-Permian mass extinction was the most severe extinction event in the Phanerozoic, with an estimated loss of ca. 80–96% of species and ca.Missing: lost | Show results with:lost
  129. [129]
    Sciencespeak: Lazarus taxon | National Geographic
    Feb 2, 2015 · “Lazarus taxon” was originally coined for organisms – from a single species up to an entire group – that seem to disappear during one of Earth's ...
  130. [130]
    De-extinction technology and its application to conservation
    Sep 24, 2025 · De-extinction is the notion that long-dead species can be brought back from extinction through modern genomic techniques and assisted ...2.1. Genome Engineering · 2.2. 1. Stem Cell... · 3.1. Genetic Rescue And...
  131. [131]
    De-Extinction - PMC - PubMed Central
    Nov 13, 2018 · De-extinction was introduced as a means to “undo” historic extinctions by restoring new versions of extinct species to their former habitats.
  132. [132]
    The “Evolutionarily Significant Unit” concept and its applicability in ...
    The Evolutionarily Significant Unit (ESU), conceptualised by Ryder (Citation1986) as a conservation unit below the species level, but theoretically applicable ...
  133. [133]
    Conservation genetics as a management tool: The five best ... - PNAS
    Dec 20, 2021 · The identification of evolutionary significant units (ESUs) has been used to determine which populations should be conserved separately. ESUs ...
  134. [134]
    IUCN Red List Categories and Criteria
    The IUCN Red List Categories and Criteria are a system for classifying species at high risk of global extinction.
  135. [135]
    IUCN Red List categories and criteria, version 3.1, second edition
    Jan 1, 2012 · The IUCN Red List Categories and Criteria are intended to be an easily and widely understood system for classifying species at high risk of global extinction.
  136. [136]
    22.2: Diversity Indices - Biology LibreTexts
    Oct 28, 2024 · The variation in species richness on each peak results in different alpha, gamma, and beta diversity values for each ecoregion. This variation ...
  137. [137]
    Measurements of biodiversity - Coastal Wiki
    Apr 4, 2025 · These three types of indices (richness, evenness, taxonomic) can be used on different spatial scales: Alpha diversity refers to diversity ...
  138. [138]
    A conceptual guide to measuring species diversity - Roswell - 2021
    Feb 9, 2021 · Three metrics of species diversity – species richness, the Shannon index and the Simpson index – are still widely used in ecology, ...Equalizing Samples · Diversity Metrics · Which Hill Diversity To Use?
  139. [139]
    Count cryptic species in biodiversity tally - Nature
    Jun 29, 2016 · Dijkstra notes that we have so far named only about 1.2 million of Earth's estimated 8.7 million or so eukaryotic species.
  140. [140]
    Estimating Global Biodiversity: The Role of Cryptic Insect Species
    Cryptic species have been widely documented in numerous groups of organisms, and may have important consequences for estimating global biodiversity (e.g., ...
  141. [141]
    The impact of taxonomic change on conservation: Does it kill, can it ...
    We found no evidence of a consistent effect of taxonomic change on conservation, although splitting taxa may tend to increase protection.Short Communication · Introduction · Taxonomy Protects
  142. [142]
    Taxonomy based on science is necessary for global conservation
    Mar 14, 2018 · The splitting of legally protected taxa may result in species not being included by name in conservation legislation or regulations, thereby ...
  143. [143]
    Captive Breeding - an overview | ScienceDirect Topics
    Captive breeding is a fundamental tool for the conservation of critically endangered species, as it allows a rapid population increase (breeding) or protection ...
  144. [144]
    How well can captive breeding programs conserve biodiversity? A ...
    Captive breeding programs are increasingly being initiated to prevent the imminent extinction of endangered species and/or populations.
  145. [145]
    Conserving evolutionarily distinct species is critical to safeguard ...
    Dec 17, 2021 · The premise is that evolutionarily distinct species represent uniquely divergent genomes and hence putatively unique feature diversity to ...
  146. [146]
    The PD Phylogenetic Diversity Framework: Linking Evolutionary ...
    The PD phylogenetic diversity measure provides a way to measure biodiversity at the level of features. PD assumes an evolutionary model in which shared features ...The Pd Phylogenetic... · Phylogenetic Conservation... · Introduction
  147. [147]
    Factsheet: Giant Panda | WWF
    Mar 8, 2006 · By conserving the giant panda and its habitat, many other species will also be conserved - as will water resources that are essential for the ...
  148. [148]
    Coral reefs | UNEP - UN Environment Programme
    Jan 20, 2025 · Coral reefs cover less than 1 per cent of the seafloor, but they support at least 25 per cent of marine species · Coral reefs are the most ...Missing: hotspots | Show results with:hotspots
  149. [149]
    Post-2020 global biodiversity framework - resource | IUCN
    Estimates based on the IUCN Red List of Threatened Species™ tell us that one million species are currently threatened with extinction, but modelling ...
  150. [150]
    Can the world save a million species from extinction? - Nature
    Dec 8, 2022 · One-quarter of all plant and animal species are threatened with extinction owing to factors such as climate change and pollution.
  151. [151]
    Aristotle
    ### Summary of Aristotle's Views on Species, Scala Naturae, and Classification
  152. [152]
    The Medieval Problem of Universals
    Sep 10, 2000 · The medieval problem of universals is a logical, and historical, continuation of the ancient problem generated by Plato's (428–348 BCE) theory.
  153. [153]
    Darwinian evolution in the light of genomics - PMC - PubMed Central
    INTRODUCTION. Charles Darwin's book On the Origin of Species that appeared in London in 1859 (1) was the first plausible, detailed account of biological ...
  154. [154]
    Darwin and the Nature of Species (SUNY Press 2007) - Academia.edu
    And so again and again in the Origin we see Darwin assert that there is no essential or fundamental distinction between species and varieties. For example ...
  155. [155]
    Modern Synthesis - an overview | ScienceDirect Topics
    The modern synthesis is defined as the integration of natural selection and genetic variation to explain the evolution of biological organization, emphasizing ...
  156. [156]
    Biological Species and Speciation—Mayr's First Synthesis
    Ernst Mayr's early interests in evolution and genetics (pp. 26–29, 45) led to his decisive contributions to the modern synthesis of the late 1930s and 1940s ...
  157. [157]
    Willi Hennig and the Rise of Cladistics - ResearchGate
    While evolutionary systematics represents an important chapter in the recent history of biology, the rise of cladistics in the 1970s and 1980s argues for ...
  158. [158]
    Advances in Time Estimation Methods for Molecular Data
    Feb 16, 2016 · In the first generation approaches (1960s–1980s), a strict molecular clock was assumed to date divergences. In the second generation ...
  159. [159]
    The Discovery of the Double Helix, 1951-1953 | Francis Crick
    Watson and Crick developed their ideas about genetic replication in a second article in Nature, published on May 30, 1953. The two had shown that in DNA ...
  160. [160]
    Majority of divergence between closely related DNA samples is due ...
    The first part of the paper summarizes the results for samples of chimp DNA compared with the human genome sequence. ... sequence in the other species DNA ...
  161. [161]
    [PDF] AN ALTERNATIVE TO PHYLETIC GRADUALISM
    The interpretation supported by Eldredge and Gould is that allopatric speciation in smaJI, peripheral populations automatically results in "gaps" in the fossil ...
  162. [162]
    Pluralism in Species Concepts: Dividing Nature at its Diverse Joints
    The paper outlines the current discussion on the species problem: what actually is a species and how do we recognize such an entity in nature? Six of the.
  163. [163]
    From Integrative Taxonomy to Species Description: One Step Beyond
    Integrative taxonomy was formally introduced in 2005 as a comprehensive framework to delimit and describe taxa by integrating information from different types ...
  164. [164]
    Towards a Dynamic Interaction Network of Life to unify and expand ...
    May 29, 2018 · Since the living world evolves as a dynamic network of interactions, we argue that evolutionary biology could become a science of evolving ...