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The International Code of Phylogenetic Nomenclature, known as the PhyloCode for short, is a formal set of rules governing phylogenetic nomenclature. Its current version is specifically designed to regulate the naming of clades, leaving the governance of species names up to the rank-based nomenclature codes (ICN, ICNCP, ICNP, ICZN, ICVCN).

The PhyloCode is associated with the International Society for Phylogenetic Nomenclature (ISPN).[1] The companion volume, Phylonyms, establishes 300 taxon names under PhyloCode, serving as examples for those unfamiliar with the code.[2] RegNum is an associated online database for registered clade names.[3]

The PhyloCode regulates phylogenetic nomenclature by providing rules for deciding which associations of names and definitions are considered established,[4] which of those will be considered homonyms[5] or synonyms,[6] and which one of a set of synonyms or homonyms will be considered accepted (generally the one registered first; see below). The PhyloCode only governs the naming of clades,[7] not of paraphyletic or polyphyletic groups, and only allows the use of specimens, species, and apomorphies as specifiers (anchors).[8]

Phylogenetic nomenclature

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Main article: Phylogenetic nomenclature

Unlike rank-based nomenclatural codes (ICN, ICZN, ICNB), the PhyloCode does not require the use of ranks, although it does optionally allow their use.[9][10] The rank-based codes define taxa using a rank (such as genus, family, etc.) and, in many cases, a type specimen or type subtaxon. The exact content of a taxon, other than the type, is not specified by the rank-based codes.

In contrast, under phylogenetic nomenclature, the content of taxa are delimited using a definition that is based on phylogeny (i.e., ancestry and descent) and uses specifiers (e.g., species, specimens, apomorphies) to indicate actual organisms. The formula of the definition indicates an ancestor. The defined taxon, then, is that ancestor and all of its descendants. Thus, the content of a phylogenetically defined taxon relies on a phylogenetic hypothesis.

The following are examples of types of phylogenetic definition (capital letters indicate specifiers):[11]

  • Node-based: "the clade originating with the most recent common ancestor of A and B" or "the least inclusive clade containing A and B"
  • Branch-based: "the clade consisting of A and all organisms or species that share a more recent common ancestor with A than with Z" or "the most inclusive clade containing A but not Z." Another term for definitions of this sort is stem-based.
  • Apomorphy-based: "the clade originating with the first organism or species to possess apomorphy M inherited by A".

Other types of definition are possible as well, taking into account not only organisms' phylogenetic relations and apomorphies but also whether or not related organisms are extant.

The following table gives examples of phylogenetic definitions of clades that also have ranks in traditional nomenclature. When all the specifiers in a node-based definition are extant specimens or species, as in the following definition of Mammalia, a crown group is defined. (The traditional definition of Mammalia is less restrictive, including some fossil groups outside of the crown group.)[12]

Name Rank Type Possible phylogenetic definition
Tyrannosauridae Family Tyrannosaurus
Osborn 1905 		Least inclusive clade containing Tyrannosaurus rex Osborn 1905, Gorgosaurus libratus Lambe 1914, and Albertosaurus sarcophagus Osborn 1905
Mammalia Class N/A Clade originating with the most recent common ancestor of humans, Homo sapiens Linnaeus 1758, and platypuses, Ornithorhynchus anatinus Shaw 1799
Rodentia Order N/A Most inclusive clade containing the house mouse, Mus musculus Linnaeus 1758, but not the eastern cottontail, Sylvilagus floridanus Allen 1890
Neornithes
(Modern birds)[verification needed] 		Subclass N/A Clade originating with the most recent common ancestor of the extant members of the most inclusive clade containing the house sparrow Passer domesticus Linnaeus 1758 but not the dinosaur Stegosaurus armatus Marsh 1887
Tetrapoda Superclass N/A Clade originating with the earliest ancestor from which Homo sapiens Linnaeus 1758 inherited limbs with fingers or toes

Versions

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PhyloCode has gone through several revisions. As of November 2023, the current version is 6, released on the website on June 8, 2020.

Organization

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As with other nomenclatural codes, the rules of the PhyloCode are organized as articles, which in turn are organized as chapters. Each article may also contain notes, examples, and recommendations.

Table of contents

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Registration database

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Once implemented, the PhyloCode will be associated with a registration database, called RegNum, which will store all clade names and definitions that will be considered acceptable.[13] It is hoped that this will provide a publicly usable tool for associating clade names with definitions, which could then be associated with sets of subtaxa or specimens through phylogenetic tree databases (such as TreeBASE).

As currently planned, however, the most important use of RegNum will be the decision of which one of a number of synonyms or homonyms will be considered accepted: the one with the lowest registration number, except in cases of conservation.

History

[edit]

(Condensed from the PhyloCode's Preface.[14])

The PhyloCode grew out of a workshop at Harvard University in August 1998, where decisions were made about its scope and content. Many of the workshop participants, together with several other people who subsequently joined the project, served as an advisory group. In April 2000, a draft was made public on the web and comments were solicited from the scientific community.

A second workshop was held at Yale University in July 2002, at which some modifications were made in the rules and recommendations of the PhyloCode. Other revisions have been made from time to time as well.

The First International Phylogenetic Nomenclature Meeting, which took place from July 6, 2004, to July 9, 2004, in Paris, France, was attended by about 70 systematic and evolutionary biologists from 11 nations.[15] This was the first open, multi-day conference that focused entirely on phylogenetic nomenclature, and it provided the venue for the inauguration of a new association, the International Society for Phylogenetic Nomenclature (ISPN). The ISPN membership elects the Committee on Phylogenetic Nomenclature (CPN), which has taken over the role of the advisory group that oversaw the earlier stages of development of the PhyloCode.

The Second International Phylogenetic Nomenclature Meeting took place from June 28, 2006, to July 2, 2006, at Yale University (New Haven, Connecticut, U.S.).[16]

The Third International Phylogenetic Nomenclature Meeting took place from July 21, 2008, to July 22, 2008, at Dalhousie University (Halifax, Nova Scotia, Canada).[17]

The PhyloCode went into effect with the publication of the companion volume, Phylonyms, in 2020.[18]

Influences

[edit]

The theoretical foundation of the PhyloCode was developed in a series of papers by de Queiroz and Gauthier,[19][20][21] which was foreshadowed by earlier suggestions that a taxon name could be defined by reference to a part of a phylogenetic tree.[22][23]

Whenever possible, the writers of the PhyloCode used the draft BioCode,[24] which attempted to unify the rank-based approach into a single code, as a model. Thus, the organization of the PhyloCode, some of its terminology, and the wording of certain rules are derived from the BioCode. Other rules are derived from one or more of the rank-based codes, particularly the botanical[25][26][27] and zoological[28][29] codes. However, many rules in the PhyloCode have no counterpart in any code based on taxonomic ranks because of fundamental differences in the definitional foundations of the alternative systems. Note that the PhyloCode does not govern the names of species, whose rules of availability, typification, etc., remain regulated by the requisite traditional Code of Nomenclature.

Future

[edit]

The PhyloCode is controversial and has inspired considerable criticism from some taxonomists.[30] While inaugurated decades ago, the number of supporters for widespread adoption of the PhyloCode is still small, and the publication of PhyloCode literature stagnated in the mid-2010s,[31] before accelerating after publication of Phylonyms in 2020 and of the launch of the Bulletin of Phylogenetic Nomenclature, which is a journal dedicated to the publication of nomenclatural acts (especially definition of taxon names) valid under the PhyloCode.[32][33] To be valid under the PhyloCode, taxon names and associated definitions should be registered in the RegNum database.

A list of published critiques of the PhyloCode can be found on the ISPN's website, as can a list of rebuttals.

References

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Literature

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

PhyloCode

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The International Code of Phylogenetic Nomenclature, commonly known as the PhyloCode, is a formal set of principles, rules, and recommendations designed to govern the naming of biological taxa by explicit reference to their phylogenetic relationships, focusing on clades—groups consisting of a and all its descendants—while leaving names under existing rank-based codes. Unlike traditional Linnaean nomenclature, which assigns names based on hierarchical ranks such as , , and order, the PhyloCode emphasizes evolutionary relationships to promote stability in naming as phylogenetic knowledge advances, avoiding changes due to re-ranking or paraphyletic groupings. It is intended to complement, rather than replace, the (ICN), the (ICZN), and the International Code of Nomenclature of Prokaryotes (ICNP), allowing for concurrent use in . The PhyloCode was developed over more than two decades by a committee led by Kevin de Queiroz and Philip D. Cantino, with foundational ideas articulated as early as 1992, and it was first published in hard copy as version 6 in 2020 by CRC Press, following ratification by the International Society for Phylogenetic Nomenclature. Key features include requirements for phylogenetic definitions in clade names—such as specifying reference taxa and qualifiers like "crown clade" or "total clade"—and provisions for registering names to ensure permanence and traceability. Accompanying resources, such as the companion volume Phylonyms, provide nearly 300 pre-defined clade names across major lineages to facilitate adoption.

Fundamentals of Phylogenetic Nomenclature

Definition and Principles

The , formally known as the International Code of , is a set of rules and recommendations designed to govern the naming of biological clades—monophyletic groups of organisms sharing a common ancestor—by explicitly referencing their phylogenetic relationships rather than Linnaean taxonomic ranks. This system applies to all clades, whether extant or extinct, and emphasizes unambiguous, stable that reflects evolutionary history derived from cladistic analyses. At its core, the PhyloCode operates on several foundational principles: all named taxa must be clades, ensuring as the basis for taxonomic groups; names are established through explicit phylogenetic definitions that anchor them to specific points in the , promoting stability regardless of future phylogenetic revisions; it is independent of rank-based hierarchies, allowing flexible without mandatory assignment to categories like or family; and it prioritizes evolutionary relationships over typological or morphological criteria alone. These principles enable the code to accommodate ongoing discoveries in without necessitating name changes due to shifts in perceived ranks or hierarchies. Clade naming under the PhyloCode employs three primary types of phylogenetic definitions to specify the content of a precisely. Node-based definitions identify a as the of specified taxa (or specimens) and all its descendants; for example, Aves can be defined as "the least inclusive containing Passer domesticus () and Struthio camelus ()," capturing the crown group of modern birds. Stem-based definitions designate a as all organisms sharing a more recent common ancestor with a specified internal specifier than with an external one, excluding certain branches; Aves, for instance, might be "the most inclusive containing Passer domesticus but not Alligator mississippiensis," encompassing birds and their extinct relatives closer to them than to crocodilians. Apomorphy-based definitions tie a to the first ancestor bearing a particular derived character (apomorphy) shared synapomorphically among specifiers; Aves could thus be "the clade stemming from the first to possess feathers synapomorphic with those in Passer domesticus." The PhyloCode emerged as a distinct framework separate from rank-based codes such as the (ICZN) and the International Code of Nomenclature for algae, fungi, and plants (ICN), which primarily govern and Linnaean ranks but struggle with the instability caused by phylogenetic rearrangements. By focusing solely on clades and using phylogeny-tied definitions, it allows names to remain stable amid new cladistic evidence, avoiding renamings triggered by rank adjustments that plague traditional systems. This separation enables concurrent use with ICZN and ICN for -level governance while providing a complementary tool for higher-level phylogenetic classification.

Comparison with Rank-Based Nomenclature

Rank-based nomenclature, as governed by codes such as the (ICZN) for and the International Code of Nomenclature for algae, fungi, and (ICN) for and fungi, organizes taxa into a hierarchical system using fixed ranks like kingdom, , class, order, , , and . These systems rely on type specimens or type taxa to fix the application of names, with priority determined by publication date, but they often lead to nomenclatural instability when new phylogenetic data reveal changes in relationships, necessitating rank adjustments that can cascade through the hierarchy and alter name applications. In contrast, the PhyloCode defines clade names explicitly through phylogenetic relationships using specifiers—such as species, specimens, or apomorphies—in node-based, stem-based, or apomorphy-based formulations, decoupling names from ranks and prioritizing monophyletic groups (clades) over hierarchical categorization. This approach enhances stability because a name's referent remains tied to the specified evolutionary hypothesis; for instance, if the tree topology shifts but the specifiers (e.g., the most recent common ancestor of two taxa) persist, the clade's composition adjusts without renaming. Rank-based systems, however, can require renaming or re-ranking when phylogenies evolve, as ranks must be assigned consistently across the hierarchy, potentially disrupting established names even if the core group remains unchanged. A key advantage of the PhyloCode lies in its flexibility for handling phylogenetic complexity, particularly by avoiding the classification of paraphyletic groups as formal taxa, which rank-based systems sometimes force to maintain hierarchical completeness and can misrepresent evolutionary history. For example, the Dinosauria, defined under as the consisting of the of Triceratops horridus and Passer domesticus and all of that ancestor's descendants, stably includes birds regardless of topological changes, whereas in rank-based systems, incorporating avian dinosaurs might prompt rank elevations for subgroups like Aves, leading to broader nomenclatural revisions without altering the name itself but affecting subordinate taxa. This rank-free structure allows naming at any scale without arbitrary constraints, promoting consistency in rapidly evolving fields. In the genomic era, where dense phylogenies from large-scale sequencing reveal numerous nested , rank-based 's limitations become pronounced, as assigning fixed ranks to this proliferation of monophyletic groups often involves subjective decisions that undermine universality and stability across studies. The PhyloCode mitigates this by permitting explicit definitions for any without rank imposition, facilitating integration of genomic data into without the arbitrariness of rank escalation or compression.

Historical Development

Origins and Influences

The development of the PhyloCode was profoundly influenced by the principles of , pioneered by Willi Hennig in his 1950 work Grundzüge einer Theorie der phylogenetischen Systematik (translated as Phylogenetic Systematics in 1966), which emphasized the reconstruction of evolutionary relationships through shared derived characters and the prioritization of monophyletic groups—clades consisting of an ancestor and all its descendants—over paraphyletic assemblages. Hennig's framework shifted from essentialist typology toward a phylogenetic approach, laying the groundwork for that directly ties names to evolutionary trees rather than fixed morphological types or hierarchical ranks. In the 1970s and 1980s, evolutionary biologists like and advanced critiques of traditional Linnaean , highlighting its incompatibility with Darwinian evolution due to the arbitrary nature of ranks, which fail to consistently reflect degrees of divergence or phylogenetic structure. , in his 1973 paper on the philosophical foundations of evolutionary classification, argued for systems that integrate adaptation and phylogeny without rigid rank assignments, proposing instead a focus on natural evolutionary lineages. Similarly, , in The Growth of Biological Thought (1982), described Linnaean ranks as a "vestige of pre-evolutionary thinking" that imposes artificial categories on the branching patterns of descent, advocating for classifications more aligned with phylogenetic branching than with typological hierarchies. These proposals underscored the need for a non-rank-based system to better accommodate the irregular branching of evolutionary trees. Symposia in the 1990s played a crucial role in raising awareness of the limitations of rank-based nomenclature and promoting phylogenetic alternatives, fostering discussions that directly informed the PhyloCode's conceptual foundations. For instance, the 1995 symposium "Translating Phylogenetic Analyses into Classification" in , organized by Richard Olmstead, explored how cladistic methods could reform taxonomic naming practices. Subsequent events, such as the 1996 Claremont symposium "The Linnean Hierarchy: Past, Present, and Future" and the 1999 symposium "Overview and Practical Implications of ," further galvanized support for rank-free approaches by demonstrating their utility in resolving nomenclature's disconnect from modern phylogenetic data. This conceptual shift from typology to phylogeny positioned the PhyloCode as a direct response to the widespread adoption of cladograms in during the late , where branching diagrams increasingly revealed the inadequacy of rank-based systems for capturing monophyletic relationships without distortion. Seminal works like de Queiroz and Gauthier's 1990 paper explicitly advocated phylogenetic definitions of names to ensure stability and relevance as cladistic analyses refined our understanding of evolutionary history, marking a transition toward that evolves with phylogenetic knowledge rather than constraining it.

Key Events and Publications

The development of the PhyloCode began with informal discussions at a workshop held August 7–9, 1998, at Herbaria in , where 27 participants from five countries outlined its scope and content. An initial draft was prepared by Philip D. Cantino and Kevin de Queiroz and released publicly in April 2000 as a special publication in Systematic Biology. This draft established the foundational principles for , focusing on names defined by phylogenetic relationships rather than ranks. Subsequent iterations incorporated feedback from the , with drafts revised between 2004 and 2009 to refine rules on naming stability and applicability. A key milestone was the First International Phylogenetic Nomenclature Meeting, held July 6–9, 2004, at the Muséum National d'Histoire Naturelle in , which attracted about 70 participants and led to the formation of the International Society for Phylogenetic Nomenclature (ISPN) to oversee further development. These revisions addressed issues such as species naming and integration with existing codes, culminating in approvals by the Committee on Phylogenetic Nomenclature (CPN). The CPN approved key changes to the in 2007, including provisions for names and total definitions, marking significant steps in its formal development following the meeting. The code continued to evolve, with version 6 ratified by the CPN on January 20, 2019, and published on June 8, 2020, as a printed volume by . This edition, authored by Cantino and de Queiroz, provided a comprehensive set of rules and recommendations for phylogenetic naming. As of November 2025, version 6 remains the current edition, with no subsequent major updates. Key publications have documented these advancements, including the 2000 draft in Systematic Biology that introduced the code's core framework. The 2020 CRC Press book formalized version 6, emphasizing stability and explicit phylogenetic definitions. In 2023, Michel Laurin's The Advent of PhyloCode: The Continuing Evolution of Biological , published by , offered a historical of the code's development, including its controversies and role in modern .

Current Version and Structure

Overview of Version 6

Version 6 of the PhyloCode, the International Code of Phylogenetic Nomenclature, was authored by Philip D. Cantino and Kevin de Queiroz, listed alphabetically, and ratified on January 20, 2019, by the Committee on Phylogenetic Nomenclature (CPN) of the International Society for Phylogenetic Nomenclature (ISPN). The CPN members at the time of ratification included Sina M. Adl, Philip D. Cantino, Nico Cellinese, Kevin de Queiroz, James A. Doyle, Micah Dunthorn, Sean W. Graham, Marcos Cardozo Langer, Michel Laurin, Richard G. Olmstead, George Sangster, and Mirosław Wolsan. This version represents the culmination of iterative drafts developed since the late 1990s, building on feedback from workshops and advisory committees to refine rules for phylogenetic nomenclature. The code was first published in hardcopy form as a book by , an imprint of , on June 8, 2020, marking the initial printed edition after prior versions existed only electronically. As of November 2025, no major revisions have been issued. The electronic version remains available for free access, facilitating widespread use alongside the print edition. In scope, Version 6 governs the naming of clades—monophyletic groups of organisms—through explicit phylogenetic definitions, but explicitly defers regulation of species names to other codes such as the or the International Code of Nomenclature for algae, fungi, and plants. Names are established using specifiers, such as extant taxa, extinct specimens, or apomorphies, to anchor the clade's circumscription to a specified , promoting stability regardless of changes in . For example, a clade might be defined as the largest group including a particular extant and excluding another, ensuring the name persists as long as the phylogenetic relationships hold. The document opens with a Preamble outlining its purpose to provide a rank-free system for naming biological lineages, emphasizing principles like monophyly (requiring clades to include all descendants of a common ancestor) and nomenclatural stability (through unambiguous definitions and registration requirements). It is structured into two main divisions: Division I, which articulates the principles of phylogenetic nomenclature, including clarity, stability, uniqueness, and phylogenetic context; and Division II, which details rules for establishing and using names, including provisions for publication, registration in the RegNum database, and governance of clade names without reliance on Linnaean ranks or type specimens for higher taxa. This framework prioritizes conceptual clarity over hierarchical ranks, allowing nomenclature to evolve with phylogenetic knowledge without rigid categories.

Table of Contents and Key Articles

The PhyloCode version 6 is structured to provide a clear framework for , beginning with a that outlines the document's purpose and authorship, followed by a that introduces the foundational concepts and goals of the . The core content is divided into two main divisions: Division I, which articulates the principles of phylogenetic nomenclature, including clarity, stability, uniqueness, and phylogenetic context; and Division II, which contains the detailed rules organized into seven chapters (I-VII). This organization emphasizes the code's focus on naming monophyletic clades independently of Linnaean ranks, with rules designed to accommodate evolving phylogenetic hypotheses. Chapter I addresses taxa, covering Articles 1-3, which define the nature of taxa as sets of organisms, specify clades as monophyletic groups consisting of an ancestor and all its descendants, and establish the rank-independent hierarchical structure of biological diversity. Chapter II focuses on publication requirements in Articles 4-5, stipulating that names must appear in peer-reviewed works with durable archival copies, and explicitly allowing both electronic and print formats while defining the effective date of publication. Chapter III, in Articles 6-8, outlines the establishment of names, including criteria for validity such as phylogenetic definitions and the principle of priority based on registration rather than mere publication. Chapter IV, the most extensive section with Articles 9-21, governs clade names and includes rules for crafting phylogenetic definitions using specifiers (e.g., or specimens) to delimit unambiguously, as well as procedures for converting preexisting rank-based names into phylogenetic ones. Chapter V is concise, with Article 22 briefly noting that names are not governed by the PhyloCode but may be referenced in clade definitions, deferring to rank-based codes like the ICZN or ICN for their regulation. Chapter VI covers hybrids in Articles 23-24, providing rules for naming clades of hybrid origin, such as using multiplication signs (×) in binomial names for hybrid taxa. Finally, Chapter VII, in Article 25, addresses cultivated and artificial taxa, allowing phylogenetic names for such groups under specific conditions to reflect human-influenced . Among the pivotal articles, Article 9 mandates that all new names must be accompanied by phylogenetic definitions, which explicitly link the name to a clade via reference to specifiers and evolutionary criteria, ensuring stability amid phylogenetic revisions. Article 11 establishes priority for clade names based on the date of registration in the official database rather than the date of first publication, requiring the registration number to be cited in the original description to confer validity. Article 21 deals with polyphyletic names by permitting their redefinition or replacement if they fail to denote monophyletic s under current phylogenies, thereby promoting nomenclatural alignment with evidence-based classifications. Each article typically includes notes for clarification, examples to illustrate application, and recommendations for best practices. For instance, Article 10 provides an example of a node-based phylogenetic definition for the clade name "Metazoa" as "the smallest clade containing Homo sapiens Linnaeus 1758 and Drosophila melanogaster Meigen 1830," using two species specifiers to crown the clade at their most recent common ancestor. This example demonstrates how definitions can employ apomorphy-based, stem-based, or node-based formulations to adapt to varying levels of phylogenetic resolution.

Governance and Implementation

International Society for Phylogenetic Nomenclature

The International Society for Phylogenetic Nomenclature (ISPN) was established on July 8, 2004, during the First International Phylogenetic Nomenclature Meeting in , , as the successor to the informal Committee on formed in 1995 to advance the development of the PhyloCode. The society maintains open membership to anyone interested in , accessible via its website phylonames.org, with the goal of promoting this approach globally among biologists and systematists. The ISPN's structure centers on an elected , which includes officers such as the president, president-elect, past president, , and treasurer, along with members-at-large, and oversees two key : the Committee on (CPN) and the Registration Committee. The CPN serves as the executive body for nomenclatural matters, with its 12 members elected by the ISPN membership for staggered three-year terms, though elections occur annually; results from the 2024 election, including new and committee appointments, are publicly available on the society's . The society publishes the Bulletin of Phylogenetic Nomenclature, a peer-reviewed journal that disseminates new phylogenetic names, emendations, and scholarly discussions on . Among its core responsibilities, the ISPN, through the CPN, ratifies versions of the —such as version 6 in 2019—resolves disputes over name applications and interpretations, and organizes periodic international meetings to foster advancements in . Current leadership includes President Mieczysław Wolsan, President-Elect Michel Laurin, Past-President Pamela Soltis, Secretary Wendy Clement, Treasurer Nico Cellinese, and key figures like Kevin de Queiroz, a longtime CPN member and co-author of the .

Registration Database and Procedures

The registration database for the PhyloCode, known as RegNum, is maintained under the auspices of the International Society for Phylogenetic Nomenclature (ISPN) and accessible via the website phyloregnum.org. This electronic repository stores all names and their associated phylogenetic definitions established under the code, ensuring a centralized and searchable record to prevent duplication and facilitate access. Since version 4 of the PhyloCode, submission of new names has required electronic entry through the RegNum web interface, a process that generates a for each entry. Under Article 8 of the PhyloCode, a clade name is established only upon both publication in a peer-reviewed outlet and successful registration in RegNum. The required submission data includes the proposed name, its type (e.g., node-based or stem-based), the phylogenetic definition, a list of internal and external specifiers (such as species or specimens), the reference phylogeny, contact information for the author(s), and eventual bibliographic details of the publication. Upon initial submission—often prior to or concurrent with publication—a temporary registration number is issued immediately, alerting submitters to potential conflicts like homonyms; this becomes a permanent RegNum (e.g., RegNum 123) once the full publication reference is confirmed post-acceptance. Authors are encouraged to register promptly after acceptance to secure the name without delay. Priority for names applying to the same is determined by the date of establishment, defined as the date (Article 5), provided that registration is completed, with earlier-established names taking precedence over later ones (Article 12). Unlike traditional s where priority might hinge solely on , the PhyloCode's mandatory registration ties establishment to both elements, though the chronological date remains the key criterion unless overridden by conservation (Article 15). Although the PhyloCode applies prospectively and is not retroactive to pre-existing names, previously proposed phylogenetic definitions can be formally registered to establish them under the , subject to review for compliance (as outlined in associated guidelines). For example, in a 2023 phylogenetic classification of the plant family Cornaceae, multiple names—including those circumscribing subgroups within Cornales—were registered in RegNum, assigning unique identifiers that link the definitions to genomic and morphological data for ongoing research. This integration enhances the stability and discoverability of phylogenetically defined taxa across biological disciplines.

Adoption and Impact

Current Usage and Examples

The PhyloCode has seen growing application in phylogenomics, particularly for defining clades in complex evolutionary studies. A notable example is the 2022 classification of the plant family Cornaceae, where genomic data from multiple sources informed a PhyloCode-based nomenclature for subclades such as Nyssoideae, emphasizing phylogenetic relationships over traditional ranks. Similarly, in 2024, researchers applied phylogenetic nomenclature under the PhyloCode to revise the taxonomy of Notosuchia, a diverse clade of Mesozoic crocodyliforms, providing explicit definitions for several internal subclades in the Bulletin of Phylogenetic Nomenclature. Adoption of the PhyloCode is most prominent in and , where it facilitates stable naming amid shifting phylogenetic hypotheses. In , the Cornaceae study exemplifies its use for integrating large-scale genomic datasets into definitions. In , it has been employed for clades, such as the 2021 formalization of 76 ornithischian names using node- and stem-based definitions to reflect their evolutionary positions within Dinosauria. The International Committee on of Viruses (ICTV) incorporates phylogenetic elements in its by using evolutionary relationships, such as sequence similarity, to classify viral lineages, while retaining a rank-based framework. A 2024 scientometric highlights the expanding influence of the PhyloCode up to , documenting over 280 publications referencing it from 1990 to , with a marked uptick in citations since 2020—particularly in molecular journals—indicating broader integration into contemporary taxonomic research. Subsequent developments include the 2024 The Advent of PhyloCode by Michel Laurin, which explores its , advantages, and ongoing adoption in biological . In 2025, the Bulletin of Phylogenetic published a proposal to uniquely distinguish established names under the PhyloCode from names. Specific examples include the 2019 registration of a node-based for Eukaryota, specifying the crown as the most recent common of specified eukaryotic lineages and all its descendants, which has been applied in protist and microbial phylogenies. In avian studies, stem-based definitions under the PhyloCode have been used for Archosauria, defining it as the originating with the last common of crocodilians and birds and all taxa sharing a more recent common with that than with lepidosaurs, as seen in recent revisions of bird higher-level .

Advantages and Criticisms

One key advantage of the PhyloCode is its enhanced nomenclatural stability, as clade names are tied directly to phylogenetic hypotheses rather than hierarchical ranks, ensuring that names remain applicable even as classifications evolve without requiring widespread renaming. This approach locks names to phylogeny, reducing disruptions from rank-based adjustments and promoting consistency across taxonomic levels. Additionally, the PhyloCode offers flexibility for incorporating new phylogenetic data without the constraints of predefined ranks, allowing taxonomists to name clades at any level without artificial hierarchies. It also encourages the formulation of explicit, testable hypotheses about evolutionary relationships, as definitions must specify phylogenetic criteria that can be evaluated against emerging evidence from phylogenies. These features represent a logical evolution from cladistic principles, aligning nomenclature more closely with modern . Criticisms of the PhyloCode center on potential instability arising when phylogenetic specifiers—such as reference taxa or apomorphies—become invalid due to new discoveries, which could necessitate redefinition or renaming of clades. Traditional taxonomists have expressed resistance owing to the steep learning curve and heavy reliance on centralized databases like RegNum for name registration and validation, which may hinder adoption in resource-limited settings. A prominent early critique argued that the system is "fatally flawed" for disregarding type specimens, which provide a anchor in rank-based codes, leading to subjective and unstable . Further controversies include challenges in handling polyphyletic groups, where the PhyloCode's strict requirement may complicate naming non-clade assemblages that have practical utility in fields like conservation. Ongoing debates highlight persistent concerns over stability, with analyses showing that while the PhyloCode faces for potential flux in name applicability, it has gained assimilation in eukaryotic and microbial through practical applications. Institutional resistance remains notable, particularly in established taxonomic communities accustomed to rank-based systems, though targeted examples of usage in specific clades demonstrate growing in niche areas. Looking ahead, the PhyloCode's future may involve partial through hybrid models that integrate its phylogenetic definitions with elements of rank-based codes, balancing with continuity to address ongoing critiques.

References

  1. http://phylonames.org/code/
  2. https://www.taylorfrancis.com/books/mono/10.1201/9780429446320/international-code-phylogenetic-nomenclature-phylocode-kevin-de-queiroz-philip-cantino
  3. https://www.floridamuseum.ufl.edu/science/phylocode-system-for-naming-organisms/
  4. https://academic.oup.com/sysbio/article/55/1/160/2842921
  5. https://www.routledge.com/Phylonyms-A-Companion-to-the-PhyloCode/deQueiroz-Cantino-Gauthier/p/book/9781138332935
  6. http://phylonames.org/documents/PhyloCode.pdf
  7. http://phylocode.org/preface.html
  8. https://www.tandfonline.com/doi/abs/10.1080/02724634.1999.10011123
  9. https://academic.oup.com/sysbio/article/56/6/1011/1652123
  10. http://phylonames.org/code/preface
  11. https://www.researchgate.net/publication/265143174_PhyloCode_A_Phylogenetic_Code_of_Biological_Nomenclature_Version_4c
  12. http://phylonames.org/documents
  13. https://onlinelibrary.wiley.com/doi/abs/10.1111/j.0300-3256.2004.00176.x
  14. https://www.routledge.com/The-Advent-of-PhyloCode-The-Continuing-Evolution-of-Biological-Nomenclature/Laurin/p/book/9780367552886
  15. https://api.pageplace.de/preview/DT0400.9780429821363_A38969334/preview-9780429821363_A38969334.pdf
  16. https://www.researchgate.net/publication/343557908_Phylocode
  17. http://phylonames.org/code/divisions/1
  18. https://www.routledge.com/International-Code-of-Phylogenetic-Nomenclature-PhyloCode/deQueiroz-Cantino/p/book/9781138332829
  19. https://www.phylonames.org/code/
  20. http://phylonames.org/about
  21. http://phylonames.org/pdf/ispn_bylaws.pdf
  22. http://phylonames.org/news
  23. https://mapress.com/bpn
  24. http://phylonames.org/code
  25. http://phylonames.org/code/appendices/a/
  26. https://www.phyloregnum.org/
  27. http://phylonames.org/documents/PhyloCode4c.pdf
  28. http://phylonames.org/code/articles/8
  29. https://www.biotaxa.org/bpn/article/view/bpn.1.2.1
  30. http://phylonames.org/code/articles/12
  31. https://mapress.com/bpn/article/view/50995
  32. https://www.floridamuseum.ufl.edu/regnum/
  33. https://www.mapress.com/bpn/article/view/bpn.1.3.2
  34. https://ictv.global/about/taxonomy
  35. https://www.scielo.br/j/aabc/a/nhHQ8wwQhWgzFTSSMhLM5Qn/?lang=en
  36. https://www.taylorfrancis.com/books/mono/10.1201/9781003092827/advent-phylocode-michel-laurin
  37. https://mapress.com/bpn/article/view/52852/bpn.2.1.1
  38. https://www.americanscientist.org/article/attacks-on-taxonomy
  39. https://onlinelibrary.wiley.com/doi/10.1111/zsc.12625
  40. https://ojs.ethnobiology.org/index.php/ebl/article/view/1968/1071
  41. https://link.springer.com/article/10.1663/0006-8101%282003%29069%5B0111:TPIFFA%5D2.0.CO%3B2
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