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Biogeographic realm

A biogeographic realm is the broadest division of Earth's land surface, delineated by the distributional patterns of terrestrial and that reflect shared evolutionary histories, distinct species assemblages, and influences from , , and physical barriers such as , mountains, and deserts. These realms encompass unique biotas shaped by long-term and historical events like , resulting in high levels of and hotspots within each. The concept originated in the 19th century with naturalist , who in 1876 proposed six primary zoogeographic regions based on observations of distributions during his expeditions in and elsewhere, emphasizing barriers to dispersal as key to regional differentiation. Wallace's framework laid the foundation for modern , integrating ary theory with geography to explain why certain taxa, such as marsupials in , are confined to specific areas. Subsequent refinements, incorporating paleontological and genetic data, have expanded and adjusted these divisions. Contemporary classifications most commonly recognize eight major biogeographic realms: the Nearctic (North America north of Mexico), Palearctic (Europe, northern Asia, and North Africa), Neotropical (Central and South America), Afrotropical (sub-Saharan Africa and Madagascar), Indomalayan (southern Asia and Southeast Asia), Australasian (Australia, New Guinea, and nearby islands), Oceanian (Pacific islands), and Antarctic (Antarctica and southern islands). Each realm features characteristic biomes and taxa; for instance, the Australasian realm is renowned for its monotremes and marsupials, while the Neotropical realm hosts unparalleled tropical rainforest diversity. Recent phylogenetic analyses, such as those using data from over 21,000 vertebrate species, have proposed updates with 11 realms and 20 subregions to better account for evolutionary relationships. Biogeographic realms are essential for , as they highlight areas of unique vulnerable to threats like and , guiding strategies such as networks that align with natural evolutionary boundaries. They also inform ecological research by revealing patterns of , , and across global scales.

Definition and Significance

Definition

A biogeographic realm is the largest-scale division of Earth's surface, encompassing continent- or subcontinent-sized areas characterized by unifying features of , , , and , primarily delineated by the distributional patterns of terrestrial . These realms reflect long-term evolutionary histories shaped by , where distinct assemblages of have developed due to limited intermixing. The concept has been extended to aquatic environments, including freshwater and systems, where realms are defined similarly by patterns of organism distributions and high levels of endemicity among . Unlike smaller biogeographic units such as regions, provinces, or ecoregions, realms constitute the highest hierarchical level, integrating multiple lower-scale divisions that capture finer variations in composition and ecological processes. For instance, ecoregions—relatively large units of land or containing distinct assemblages of and communities—are nested within realms to provide a framework for analyzing patterns. This hierarchical structure allows realms to serve as broad containers for understanding macro-scale biotic similarities and differences across the planet. Realm boundaries are typically marked by significant physical barriers that impede organism dispersal, such as oceans, mountain ranges, or vast deserts, leading to pronounced differences in distributions. A classic example is Wallace's Line, a sharp biogeographic boundary in the Indonesian archipelago that separates the Oriental (Indomalayan) fauna, dominated by placental mammals, from the Australasian fauna, characterized by marsupials and monotremes, highlighting the role of deep marine straits as dispersal barriers.

Ecological and Conservation Importance

Biogeographic realms play a pivotal role in by delineating large-scale regions that encapsulate distinct evolutionary histories, where processes like adaptive radiations and biotic interchanges have profoundly shaped species assemblages and functional diversity. For instance, in the Neotropics, the Great American Biotic Interchange facilitated the replacement of native clades by northern immigrants, reducing diversification rates and altering community structures, while paleoclimate fluctuations in the Afrotropics drove shifts that continue to influence phylogenetic and trait-based patterns across tropical communities. These realm-specific legacies underscore the realms' importance in explaining hotspots, such as the and , where unique biotic interchanges and historical isolations foster high and ecological complexity, as evidenced by analyses of over 500 communities spanning multiple realms. In conservation, biogeographic realms provide a foundational framework for prioritizing actions, as articulated in Udvardy's 1975 classification system, which divides the world into eight realms and 203 provinces explicitly to guide the identification and protection of irreplaceable natural regions for preservation. The World Wildlife Fund's (WWF) initiative builds on this by nesting 867 ecoregions within eight realms and 14 biomes, enabling systematic assessments of status—such as critical/endangered or relatively stable—and targeting biologically outstanding areas for expansion and threat mitigation. Similarly, the International Union for Conservation of Nature (IUCN) integrates realms into Red List assessments by intersecting range maps with realm boundaries, facilitating evaluations of risks and distributions within unique biotic provinces to inform global and regional policy. Amid contemporary challenges, biogeographic realms are increasingly incorporated into models to predict dynamic shifts in boundaries driven by and sea-level rise, revealing potential homogenization of regional biotas. For vascular plants, ensemble models under project a decline in phylogenetic by up to 0.06 units by 2100, leading to redefined floristic realms—such as expansions in the —and greater vulnerability for deep-time realms like due to dispersal barriers. In marine systems, network-based projections for lanternfishes indicate subtropical realms expanding by 15.5 million km² by 2100 under high-emission scenarios, while southern realms contract by 11.2 million km², with temperature thresholds at 200 m depth acting as key climatic barriers that could trap species in isolated refugia.

Historical Development

Early Concepts

The foundations of biogeographic realms trace back to early 19th-century observations on the distribution of plants, which provided a for understanding how environmental factors shape biotic patterns across continents. , during his expeditions in from 1799 to 1804, documented systematic variations in along altitudinal and latitudinal gradients, emphasizing the role of in determining plant assemblages. In his seminal 1807 work, Essai sur la géographie des plantes, co-authored with , Humboldt introduced the idea of plant geography as a , illustrating how temperature, humidity, and elevation create distinct zones of that correlate with geographic position. These observations laid the groundwork for later animal-based classifications, as they highlighted the non-uniform distribution of life forms and the influence of physical barriers on species ranges. Building on such phytogeographic insights, the mid-19th century saw the emergence of zoogeographic divisions focused on animal distributions, particularly birds, which offered clearer patterns due to their limited dispersal capabilities compared to . In 1858, English ornithologist Philip Lutley Sclater published "On the General Geographical Distribution of the Members of the Class Aves," proposing the first comprehensive division of the world's land surface into six major faunal regions: Palaearctic, Ethiopian (Aethiopian), , , Nearctic, and Neotropical. Sclater's system was derived from the distributions of bird families and genera, drawing on the known avifauna of the era (approximately 6,000-7,000 ), identifying regions where unique assemblages predominated, separated by barriers such as oceans and ranges that restricted faunal . This ornithological approach marked a pivotal shift toward empirical, taxon-specific , influencing subsequent frameworks by demonstrating that faunal similarities could delineate broad terrestrial provinces. Alfred Russel Wallace, independently developing similar ideas through his fieldwork in the Malay Archipelago, expanded Sclater's concepts in his 1876 two-volume treatise, The Geographical Distribution of Animals. Wallace refined the six-realm structure, integrating distributions of birds, mammals, and other vertebrates to argue for realms as primary zoogeographic units shaped by geological history, climate, and dispersal limitations. His earlier 1858 essay on species variation, co-presented with , hinted at evolutionary processes underlying distributions, but it was the 1876 work that formalized realms as dynamic zones reflecting past continental connections and s. For instance, Wallace emphasized the Australian realm's distinct marsupial-dominated as evidence of long-term , providing a mechanistic explanation for that built directly on Sclater's divisions while incorporating broader ecological insights.

20th Century Frameworks

In the mid-20th century, Philip J. Darlington advanced the understanding of biogeographic realms through his 1957 book Zoogeography: The Geographical Distribution of Animals, which built upon Alfred Russel Wallace's foundational scheme by integrating extensive data on and freshwater organisms. Darlington analyzed distribution patterns across diverse taxa, including and aquatic invertebrates, to refine realm boundaries and highlight faunal distinctness, particularly in tropical regions like the Neotropical and Ethiopian realms. His work confirmed the core structure of Wallace's six realms while adjusting divisions, such as emphasizing barriers in the Oriental realm based on insect dispersal limitations. A significant formalization occurred in 1975 when Miklos D.F. Udvardy proposed a standardized for the International Union for Conservation of Nature (IUCN), delineating eight biogeographic realms based on levels of at the family and levels for vertebrates, select , and . These realms—Nearctic, Palearctic, Neotropical, Afrotropical, Indomalayan, Australasian, Oceanian, and —recognized the Antarctic as a distinct entity due to its high and , differing from earlier schemes that subsumed it within others. Udvardy's system subdivided realms into 203 provinces to support conservation planning, prioritizing endemic taxa as indicators of historical biogeographic processes. Early 20th-century efforts to incorporate aquatic systems into these frameworks were tentative, primarily extending terrestrial concepts to freshwater through analyses of and distributions, as seen in Darlington's inclusion of freshwater to test integrity. Udvardy's explicitly encompassed terrestrial and freshwater lake , though systems remained largely separate, reflecting the era's focus on land-based barriers over . These initial extensions laid groundwork for later aquatic-specific delineations but were limited by incomplete distributional .

Modern Advances

In the early 2000s, the World Wildlife Fund (WWF) advanced biogeographic realm delineations through its initiative, which identified 238 priority ecoregions across terrestrial, freshwater, and marine systems, organized within eight terrestrial and freshwater realms: Nearctic, Palearctic, Afrotropical, Indomalayan, Australasian, Oceanian, , and Neotropical. These realms were refined by integrating vegetation types, climate zones, and regional expert analyses to better capture evolutionary histories and biodiversity patterns, moving beyond earlier frameworks like Udvardy's by emphasizing representation of all 30 biomes within each realm. The system prioritized conservation efforts on ecoregions exhibiting high , , and unique ecological phenomena, such as the in the Afrotropical realm, to safeguard global biodiversity hotspots. Since the 2010s, molecular and phylogenetic methods have revolutionized realm boundary assessments by incorporating genetic data to reveal finer-scale evolutionary relationships and dispersal histories. , utilizing standardized gene fragments like for animals or ITS for fungi, has enabled rapid identification and detection of cryptic , facilitating reassessments of realm transitions through large-scale metabarcoding surveys. Cladistic analyses, enhanced by phylogenetic β-diversity metrics on over 21,000 vertebrate , have redefined the number of realms to 11 (with 20 regions) by quantifying turnover in evolutionary lineages, identifying transitional zones like the Saharo-Arabian as areas of biotic overlap rather than sharp barriers. For instance, (eDNA) metabarcoding has incorporated microbial data, revealing consistent biogeographic boundaries across prokaryotes, micro-eukaryotes, and metazoans in realms, thus extending realm concepts to underrepresented microbial domains and challenging traditional faunal-based delineations. In the 2020s, studies integrating models and human impacts have highlighted dynamic shifts in biogeographic realms driven by , with projections of reduced phylogenetic leading to biotic homogenization by 2100. These analyses predict range contractions for endemic and expansions of generalists, blurring realm boundaries through altered dispersal patterns and habitat suitability. In the , within the Neotropical realm, biotic homogenization is evident as warming exacerbates effects, reducing microbial and in floodplains and promoting uniform communities less resilient to further perturbations. As of 2025, taxon-specific regionalizations, such as a 19-region scheme for based on phylogenetic dissimilarity, further refine global patterns, while recent studies project homogenization of floristic regions by 2100 under warming scenarios. Such integrations underscore the need for adaptive strategies that account for realm flux under scenarios of 1.5–4°C warming.

Delineation Criteria

Barriers and Dispersal Patterns

Biogeographic realms are primarily delineated by barriers that impede the movement of organisms, leading to distinct evolutionary trajectories within isolated regions. Vicariance, a key process in this delineation, occurs when a continuous population is fragmented by geological events, preventing and promoting . A seminal example is the breakup of the , which began around 180 million years ago and separated ancestral landmasses, thereby isolating biotas that evolved into the distinct faunas of modern realms such as the Australasian. This vicariance event, driven by , created insurmountable barriers like expanding ocean basins, fundamentally shaping realm boundaries by halting dispersal across vast distances. In addition to vicariance, dispersal barriers—physical or environmental features that resist organism movement—further define realm edges by limiting colonization opportunities. The exemplifies such a barrier, spanning over 9 million square kilometers and acting as a formidable arid expanse that separates the to the south from the Palearctic to the north, restricting the exchange of terrestrial due to extreme aridity and temperature fluctuations. This barrier has acted as a major divide during arid phases over millions of years, though pluvial periods with ancient watercourses enabled greater connectivity; only occasional crossings occur during dry periods by highly mobile or adapted taxa, reinforcing the biotic discontinuity between these realms. Similarly, mountain ranges and large rivers can serve as barriers, but deserts like the highlight how climatic extremes enforce isolation on continental scales. Dispersal mechanisms, conversely, influence how organisms overcome or skirt barriers, thereby modulating realm boundaries through facilitated movement. Ocean currents play a pivotal role in marine and coastal dispersal, transporting larvae and propagules across realms; for instance, the Indo-Pacific's equatorial currents enable that blurs boundaries in some tropical marine areas while reinforcing others through directed flow patterns. acts as a primary for airborne dispersal, carrying seeds, spores, and small over long distances, often across oceanic gaps to shape island realms, though its efficacy diminishes with stronger physical barriers. , particularly in birds and large mammals, allows seasonal or periodic crossings of barriers, such as migratory birds traversing the , which can introduce but rarely erodes deep-seated realm distinctions due to limited establishment success. A notable case of a marine dispersal barrier is Wallace's Line, a deep-water boundary in the Indo-Australian Archipelago where strong currents and ocean depths inhibit faunal exchange between the Oriental and Australasian realms, resulting in abrupt transitions from Asian placental mammals to marsupials. This line, identified through patterns of species replacement, underscores how hydrodynamic forces can sustain biogeographic despite proximity. Collectively, these barriers and mechanisms contribute to patterns like isolation by distance, where genetic differentiation increases with geographic separation due to restricted dispersal, providing a quantitative framework for understanding realm cohesion without invoking complex equations. Such processes ultimately foster as an outcome of prolonged .

Endemism and Species Distributions

Endemism serves as a primary indicator for delineating biogeographic realms, where regions are characterized by assemblages of with high levels of ; the of endemic compared with total is substantial (34–88%) across realms. In analyses of distributions, realms are identified when phylogenetic turnover reveals distinct evolutionary histories, with metrics such as the proportion of restricted to a given area helping to validate boundaries; for instance, studies of amphibians, , and mammals show variable endemic proportions that emphasize the role of in fostering unique biotas. For , high in vascular is commonly used to confirm realm integrity, as seen in global assessments where realms encompass areas with substantial portions of their not occurring elsewhere. These metrics prioritize taxonomic groups like mammals, , and due to their well-documented distributions and sensitivity to historical barriers. Species distribution patterns further refine realm delineation through assessments of congruence across taxa, where boundaries are supported if similar limits emerge for flora and fauna, indicating shared evolutionary processes. Congruence is quantitatively evaluated using similarity indices, such as the Sørensen coefficient, which measures overlap in species composition between regions; high similarity (corresponding to low beta-diversity) across disparate groups like vertebrates and plants reinforces realm validity by demonstrating consistent distributional discontinuities. Physical barriers contribute to these patterns by promoting allopatric speciation, but biotic evidence from endemism provides the diagnostic confirmation. Modern delineation increasingly relies on biodiversity databases like the (GBIF), which since 2001 has enabled large-scale mapping of occurrences to compute and congruence metrics at global scales. GBIF data, encompassing millions of georeferenced records for , mammals, birds, and other taxa, facilitate spatial analyses that identify realms through overlaid distribution models, ensuring empirical validation over qualitative assessments.

Terrestrial Biogeographic Realms

Udvardy System

The Udvardy System, developed by Miklós D. F. Udvardy in 1975 under the auspices of the International Union for Conservation of Nature (IUCN), provides a of terrestrial tailored for conservation planning. It establishes eight biogeographic realms as the highest level of division, each encompassing biotas shaped by long-term evolutionary isolation and dispersal barriers. These realms are: Nearctic (encompassing north of ), Palearctic (Eurasia north of the and ), Afrotropical (), Indomalayan (South and south of the ), Australasian (Australia, , and surrounding islands), Oceanian (Pacific islands excluding ), (continental , nearby subantarctic islands, and ), and Neotropical (Central and ). Boundaries between realms are primarily determined by patterns of distributions, with emphasis on and mammals as indicators of broader affinities due to their well-documented ranges and sensitivity to historical barriers like oceans, mountains, and deserts. Udvardy's methodology integrates zoogeographic traditions from , using endemism thresholds to define units: realms exhibit high overall at generic and familial levels, with transitions occurring where shared taxa drop to transitional zones of 20–50% in major groups. The system divides the realms into 203 provinces, defined as areas with at least 50% endemic families or 20% endemic genera, often aligned with dominant biomes such as tropical rainforests or temperate grasslands. This structure allows for finer-scale analysis while maintaining global comparability. A key aspect is the separation of the Holarctic superregion into distinct Nearctic and Palearctic realms, justified by post-Pleistocene climatic divergences despite historical faunal exchanges via the . The system's strengths include its practicality for , enabling the systematic selection of protected areas to represent global biotic diversity across realms and provinces. However, limitations arise from its pre-molecular foundation, relying on morphological and distributional data that may not reflect contemporary phylogenetic insights, and its vertebrate-centric approach, which could underrepresent patterns in or .

WWF / Global 200 System

The 's () system, introduced in 2001, provides a hierarchical framework for terrestrial biogeographic classification aimed at guiding global conservation efforts by identifying priority areas of exceptional . This system delineates eight biogeographic realms—Nearctic, Palearctic, Afrotropical, Indomalayan, Australasian, Oceanian, Antarctic, and Neotropical—nested within 14 major biomes, such as , temperate broadleaf forests, tropical and subtropical grasslands, and . Within this structure, 867 terrestrial ecoregions are mapped, each defined as relatively large units of land containing a distinct assemblage of , communities, and environmental conditions that differ from adjacent units. A core component of the system is the , a subset of 142 priority terrestrial ecoregions selected for their representation of unique biological diversity, based on criteria including , , taxonomic uniqueness, and global rarity of habitats. These priorities were determined through analyses of patterns and representation gaps across the realms and biomes, ensuring that targets a balanced sample of Earth's variety without exhaustive listing of all ecoregions. For instance, the , the largest by area, encompasses diverse biomes from Arctic tundra in northern to Mediterranean woodlands in and temperate coniferous forests across , highlighting the system's integration of climatic and evolutionary factors to capture broad ecological variation. While primarily terrestrial, the framework incorporates complementary freshwater data to inform holistic conservation planning, recognizing interconnected ecosystems within realms. The ecoregions have directly influenced the designation of protected areas, including numerous World Heritage sites and national parks that align with these priorities to safeguard representative . Post-2001, the system underwent minor revisions in 2017, refining ecoregion boundaries and reducing the total to 846 based on updated biogeographic data and habitat integrity assessments, enhancing its utility for modern conservation strategies like the Project. These adjustments incorporated advances in and modeling while preserving the original realm and biome structure.

Morrone's Kingdoms

In 2015, Juan J. Morrone proposed a revised biogeographical regionalisation of the world, employing a cladistic framework rooted in historical to delineate major terrestrial units as kingdoms. This approach emphasizes phylogenetic relationships and vicariance events over purely ecological or dispersal-based criteria, recognizing three kingdoms derived from the fragmentation of ancient supercontinents such as and . Morrone's system identifies the Holarctic kingdom, comprising the Nearctic and Palearctic regions, which share a common evolutionary history tied to northern Laurasian landmasses; the Holotropical kingdom, encompassing the Neotropical, Afrotropical (Ethiopian), and Indomalayan (Oriental) regions, reflecting biotic connections from eastern ; and the Austral kingdom, including the Australian, , Cape, and Andean regions, linked to western Gondwanan origins. These kingdoms emerge from track analysis of distributions, where generalized tracks—overlapping ranges of multiple taxa—reveal historical components rather than isolated . For instance, the Neotropical region's high in groups like marsupials and underscores its distinct phylogenetic trajectory within the Holotropical kingdom. The methodology integrates panbiogeography, pioneered by Léon Croizat, with vicariance , constructing area cladograms from area cladograms to hypothesize ancestral areas and dispersal barriers. This contrasts with earlier schemes by prioritizing congruent patterns across taxa, such as angiosperm and insect distributions, to infer kingdom-level hierarchies without relying on subjective barriers like Wallace's Line. Morrone's analysis draws on prior cladistic studies, including those on southern South American biota, to validate tracks spanning continents. Compared to conventional systems like Miklos Udvardy's eight realms, Morrone's kingdoms consolidate units based on shared evolutionary histories; for example, the Indomalayan region merges into the Holotropical kingdom with the Afrotropical and Neotropical, recognizing their Gondwanan ties despite modern geographic separation, rather than treating them as discrete entities. This phylogenetic emphasis reduces fragmentation, incorporating transition zones—such as the Madro-Tropical between Nearctic and Neotropical—to capture biotic overlap without inflating the hierarchy. The scheme thus prioritizes historical connectivity, like trans-Pacific tracks in the Austral kingdom, over conservation-focused ecoregions.

Freshwater Biogeographic Realms

WWF Classification

The 's () Freshwater Ecoregions of the World (FEOW) framework delineates 426 freshwater ecoregions across the globe, grouped into 12 major habitat types that encompass diverse aquatic systems such as large lakes, tropical and subtropical rivers and complexes, xeric freshwaters and endorheic basins, and polar freshwaters. These ecoregions are organized into biogeographic realms that largely parallel the WWF's terrestrial realms, such as the , which exhibits exceptionally high levels of fish in Amazonian river basins due to historical isolation and evolutionary divergence. This structure highlights the distinct biogeographic patterns of freshwater , independent of but complementary to terrestrial classifications. The foundational methodology for FEOW, detailed in the 2008 publication Freshwater Ecoregions of the World: A New Map of Biogeographic Units for Freshwater Biodiversity Conservation, relies primarily on the distributions and compositions of over 13,400 described species, supplemented by data on amphibians, reptiles, , crocodiles, and select invertebrates to capture ecological and evolutionary processes. While the ecoregion boundaries established in 2008 have remained the standard, subsequent updates to have expanded coverage; for example, a 2025 dataset aligns distributions for 23,130 freshwater-dependent vertebrate to the FEOW framework. boundaries were delineated by aligning with major catchments and hydrological features, incorporating expert assessments from over 200 scientists and regional databases, while adjusting for historical biogeographic events like river capture and drainage evolution. This approach emphasizes the integrity of basins as fundamental units for freshwater ecosystems, recognizing that aquatic habitats are shaped by longitudinal within basins rather than terrestrial landforms alone. A distinctive feature of the FEOW framework is its explicit consideration of hydrological connectivity and barriers, such as how facilitate species dispersal while waterfalls, , and catchment divides promote isolation and ; for instance, more than 6,900 —over half of the global total—are endemic to a single , underscoring the framework's role in identifying priority areas for conservation amid threats like . By integrating these elements, FEOW provides a tool for global-scale freshwater assessment and protection, revealing hotspots like the Neotropical where endemism drives unique evolutionary histories.

Alignment with Terrestrial Systems

Freshwater biogeographic realms frequently exhibit congruence with terrestrial realms, reflecting shared evolutionary histories shaped by , climate, and dispersal barriers. In the , for instance, riverine fish communities in savanna-draining basins, such as those of the and rivers, mirror the distribution patterns of terrestrial mammals and plants, with high levels of in both systems driven by similar historical isolation events. This alignment is evident in the WWF's Freshwater Ecoregions of the World framework, where approximately 79% of high-biodiversity freshwater catchments overlap with terrestrial hotspots, particularly in tropical regions, allowing for co-evolved assemblages of aquatic and riparian species. However, such congruence is not universal; endorheic basins, like the in the Nearctic or the in the Palearctic, create discrepancies by confining freshwater taxa to isolated, evaporative systems that foster unique disconnected from adjacent terrestrial biomes, which span open landscapes. Divergences between freshwater and terrestrial realms are pronounced in regions influenced by historical glaciation and modern pressures. In the , post-Ice Age recolonization from southern refugia led to rapid radiations of lineages, such as ciscoes (Coregonus spp.) and deepwater sculpins in the , resulting in lacustrine patterns that deviate from the broader terrestrial biome's continuity across unglaciated lowlands. Human activities exacerbate these mismatches; dams fragment longitudinal connectivity in rivers, blocking migratory and altering and flows that once synchronized and terrestrial ecosystems, as observed in basins like the where impoundments have decoupled riparian vegetation from downstream habitats. These patterns of alignment and divergence have critical implications, emphasizing the value of integrated strategies that span both realms to preserve interconnected . In transboundary river basins, such as the or , coordinated governance frameworks facilitate holistic protection by addressing shared threats like across political boundaries. Incorporating freshwater priorities into terrestrial reserve planning can substantially enhance aquatic outcomes—for example, doubling benefits for tropical fish species while incurring only a 1% loss in terrestrial coverage—thereby promoting resilient ecosystems amid ongoing environmental changes.

Marine Biogeographic Realms

Marine Ecoregions of the World (MEOW)

The Marine Ecoregions of the World (MEOW) framework, developed collaboratively by The Nature Conservancy and the World Wildlife Fund in 2007, provides a standardized biogeographic classification for coastal and continental shelf marine environments worldwide. This system addresses a critical gap in marine conservation by offering a nested hierarchy of bioregional units—12 realms, 62 provinces, and 232 ecoregions—designed to capture patterns of species and community distributions across approximately 7.5% of the global ocean surface area (continental shelves and coastal waters). Unlike broader oceanic classifications, MEOW focuses exclusively on near-shore and shelf habitats, emphasizing areas of high biodiversity and human impact to support targeted conservation efforts. The classification is grounded in the distributions of both pelagic (open-water) and benthic (seafloor) species, reflecting evolutionary histories, dispersal barriers, and ecological processes that shape . For instance, the Temperate realm encompasses diverse habitats such as forests along the coasts of and , divided into the and Agulhas provinces, where upwelling-driven productivity supports unique assemblages of , , and macroalgae. Realms represent the broadest level of distinction, often separated by major oceanographic features like currents or continental barriers, while provinces and ecoregions delineate finer-scale variations in species composition and environmental drivers. This structure enables comparisons of across scales, highlighting areas of and ecological uniqueness. MEOW's methodology involved a rigorous, iterative process of regional expert workshops, drawing on more than 230 datasets encompassing oceanographic parameters (e.g., , , currents), geological features (e.g., , types), and biological records (e.g., ranges, rates). Participants, including over 150 scientists and practitioners, refined boundaries through , prioritizing of faunal discontinuities over arbitrary geographic divisions. The specifically targets waters from the surface to 200 meters depth, aligning with the and continental shelves where most coastal and fisheries occur, while excluding deeper oceanic realms. This depth limit ensures focus on ecosystems most accessible to human activities and interventions. In practice, has become a foundational tool for global planning, facilitating gap analyses to identify underrepresented ecoregions in networks and guiding the prioritization of marine (MPAs) for representativeness and connectivity. For example, it underpins assessments of MPA coverage, revealing that only about 0.5% of shelf areas were protected at the time of its development, and supports systematic planning in regions like the Coral Triangle. Subsequent applications have extended its utility to evaluating cumulative human impacts and ecosystem vulnerability, including integrations with climate models to enhance MPA designs for long-term resilience against environmental changes such as ocean warming and acidification. The framework remains the most widely adopted for coastal marine bioregionalization, with minor boundary refinements proposed in working notes but no major structural revisions to date.

Recent Global Proposals

In 2017, a comprehensive analysis of over 65,000 species distributions from the Ocean Biodiversity Information System (OBIS) database identified 30 distinct marine biogeographic realms through , comprising 18 continental-shelf realms and 12 offshore deep-sea realms. This integrated coastal, pelagic, and benthic environments, revealing distinct patterns such as separate and Atlantic deep-sea realms driven by barriers like landmasses, gradients, depth, and temperature. Building on earlier frameworks like the Marine Ecoregions of the World (MEOW), it emphasized species endemicity, with an average of 42% of species unique to these realms. Advances in the 2020s have incorporated environmental DNA (eDNA) sampling and satellite remote sensing to refine these realms, particularly by addressing undersampled areas like polar and abyssal zones. A global eDNA survey of 936 samples across oceans, including remote polar regions and deep waters, expanded known distributions for 445 fish species, revealing previously undetected presences in high-latitude and offshore habitats that challenge static boundary assumptions. Satellite data, such as chlorophyll-a imagery from sensors like Sentinel-3, has enabled modeling of dynamic environmental gradients, supporting time-varying boundary delineations influenced by currents and seasonal shifts. These integrations highlight potential realm shifts due to climate-driven changes, such as poleward migrations in response to warming. In 2025, a proposed worldwide geographical scheme introduced standardized polygons for recording marine biota distributions, complementing existing realm frameworks to improve data consistency and coverage. A key challenge in defining marine realms remains the broader dispersal capabilities of pelagic and deep-sea species, resulting in fewer and larger realms compared to the more fragmented terrestrial systems. This leads to lower endemicity rates in open-ocean environments, complicating conservation efforts amid ongoing environmental variability.