Fact-checked by Grok 2 weeks ago

Anamniotes

Anamniotes are a paraphyletic group of vertebrates characterized by the absence of an —a fluid-filled that surrounds the in amniotes—during embryonic . This group encompasses all non-amniote vertebrates, including cyclostomes (such as lampreys and ), jawed fishes (chondrichthyans and osteichthyans), and amphibians (lissamphibians). Unlike amniotes, which include reptiles, , and mammals, anamniotes typically require environments for , as their eggs lack protective extra-embryonic membranes and are laid in water to prevent . Key characteristics of anamniotes include a reliance on gill-based or in early life stages, with somites primarily composed of tissue and minimal sclerotome development, reflecting their evolutionary adaptations to aquatic or semi-aquatic lifestyles. and waste removal in their embryos occur primarily through across thin membranes in moist environments, and many species exhibit larval stages that are morphologically distinct from adults, such as tadpoles in amphibians. These traits distinguish anamniotes from the more terrestrially adapted amniotes, which evolved waterproof eggs enabling away from water. Evolutionarily, anamniotes represent an ancestral grade from which amniotes diverged during the late era, specifically in the period, with the earliest evidence dating to approximately million years ago (as of 2025 discoveries), when amphibian-like tetrapods transitioned to fully terrestrial via the of the amniotic . As a paraphyletic assemblage, anamniotes do not form a single but include all lineages basal to Amniota, highlighting their role as a foundational group in diversification from aquatic origins to complex terrestrial ecosystems.

Definition and Overview

Definition

Anamniotes are a paraphyletic group of vertebrates characterized by the absence of the extraembryonic membranes—, , and —during embryonic development. These structures, present in amniotes, protect the and facilitate and waste storage within a self-contained environment. Without them, anamniote embryos are vulnerable to , necessitating in aquatic or consistently moist habitats to ensure successful development. The term "anamniote" originates from the Greek prefix "an-," meaning "without," combined with "amnion," the innermost membrane enveloping the fetus in higher vertebrates, derived from the Greek word for a fetal membrane. This nomenclature highlights the defining reproductive limitation relative to amniotes, which evolved these membranes to support terrestrial egg-laying. The scope of anamniotes includes all vertebrates outside the amniote clade, encompassing cyclostomes (lampreys and hagfish), jawed fishes (chondrichthyans and osteichthyans), and amphibians (lissamphibians).

Distinction from Amniotes

The primary distinction between anamniotes and lies in their reproductive strategies, particularly the structure and deposition of eggs. Anamniotes, encompassing fishes and amphibians, typically lay eggs in aquatic environments or utilize followed by oviposition without the protective extraembryonic membranes that define amniote reproduction. In contrast, —reptiles, , and mammals—produce amniotic eggs equipped with a leathery or calcified shell and internal membranes, enabling fully terrestrial development independent of external water sources. This difference underscores the evolutionary shift from water-dependent reproduction in anamniotes to land-adapted strategies in . Developmentally, anamniote embryos face significant constraints due to the absence of key extraembryonic structures, such as the , which in encloses the in a protective, fluid-filled sac. Without these membranes, anamniote rely on surrounding for essential through across permeable membranes and for the dilution and removal of metabolic wastes, limiting size and hatching success to moist or submerged conditions. , however, benefit from internalized support systems—the for waste storage and respiration, and the for gas permeability—allowing prolonged in a stable, self-sustained environment that mitigates and osmotic . Evolutionarily, these reproductive and developmental differences highlight the basal position of anamniotes as vertebrates adapted primarily to or semi-aquatic niches, where environmental water availability dictates life cycles. The emergence of the amniotic in amniotes is traditionally estimated at 312–340 million years ago based on the earliest known fossils, but recent evidence from trackways dated to approximately 355 million years ago suggests an earlier origin. This transition not only expanded ecological opportunities but also marked a profound divide in independence from water-bound constraints.

Key Characteristics

Reproductive Adaptations

Anamniotes, lacking the amniotic membranes that enable terrestrial egg development in amniotes, exhibit reproductive strategies that are predominantly tied to aquatic or moist environments to ensure successful fertilization and embryonic survival. In most fishes and amphibians, external fertilization predominates, where females release eggs into water and males simultaneously discharge sperm over them, facilitating fusion in a hydrated medium. This process produces vast quantities of gametes to compensate for high mortality rates, but the eggs are unshelled and gelatinous, rendering them highly susceptible to desiccation if not submerged, thus confining reproduction to aquatic habitats. Certain anamniote groups have evolved internal fertilization as an adaptation to enhance reproductive efficiency in variable environments, though their offspring still lack amniotic protection and often require moisture. Cartilaginous fishes, such as sharks and rays, utilize specialized pelvic claspers in males to deposit sperm directly into the female's reproductive tract, leading to either egg-laying in leathery cases or viviparity, ranging from aplacental (yolk-dependent) to forms with limited maternal nutrient provision via placental-like structures. Similarly, caecilians, a limbless amphibian order, employ an eversible phallodeum for internal fertilization, resulting in either oviparity with gelatinous eggs laid in moist burrows or viviparity in some species, where embryos receive limited nourishment from uterine secretions but not through a complex placental interface. Additionally, internal fertilization has evolved in some bony fishes, such as live-bearing species in the family Poeciliidae, where sperm is transferred via gonopodia and embryos develop internally within the female. These mechanisms allow limited independence from open water compared to external fertilization but do not fully liberate anamniotes from desiccation risks, in contrast to the shelled, terrestrial-capable eggs of amniotes. Amphibians further demonstrate reproductive adaptations through distinct larval stages that bridge and terrestrial phases, optimizing in water-dependent early life. In frogs and toads, for instance, eggs hatch into tadpoles—free-living larvae with gills, tails for propulsion, and herbivorous or filter-feeding mouthparts suited to pond or ecosystems—allowing growth and organ maturation before into air-breathing adults. This larval period, regulated by , serves as an evolutionary compromise for transitioning between habitats, enabling juveniles to exploit abundant resources while avoiding the vulnerabilities of direct . Salamanders exhibit similar gilled larvae in many cases, though some bypass the free-living stage via direct in moist terrestrial nests guarded by parents.

Structural and Physiological Features

Anamniotes display a range of structures tailored to their aquatic or semi-aquatic habitats, emphasizing protection, , and . In fishes, the is typically covered by scales that overlap to form a protective barrier, minimizing influx in freshwater or efflux in ones, thus aiding . A mucous layer secreted by epidermal glands further enhances this impermeability while preventing invasion and reducing friction during swimming. Amphibians, by contrast, possess thin, glandular that is highly permeable to and gases, enabling where up to 50% of oxygen uptake occurs directly through the in many , a necessity for their moist-dependent . This permeability, supported by mucus-producing glands, maintains hydration but limits prolonged terrestrial exposure. Respiratory adaptations in anamniotes prioritize efficient oxygen extraction from water, with gills serving as the primary organ in fishes and amphibian larvae. Fish gills facilitate countercurrent exchange, allowing nearly complete oxygen diffusion from water to blood across thin lamellae, supporting high metabolic demands in oxygenated aquatic environments. In adult amphibians, lungs supplement gill-independent respiration, but their simple, sac-like structure provides lower efficiency on land due to limited surface area and reliance on buccal pumping, often complemented by cutaneous exchange for up to 90% of carbon dioxide release in some species. Certain fishes, such as lungfish, possess paired lungs derived from the swim bladder that enable aerial breathing in hypoxic waters, though these organs are less effective outside submersion due to inadequate vascularization for sustained terrestrial use. Circulatory systems in anamniotes reflect their respiratory demands, with fishes featuring a single-circuit via a two-chambered heart that directs deoxygenated blood sequentially to gills and then the , optimizing oxygen loading but limiting for distant tissues. Amphibians exhibit a three-chambered heart with partial ventricular separation, enabling a dual pulmocutaneous circuit that mixes oxygenated blood from lungs and with deoxygenated systemic return, sufficient for variable aquatic-terrestrial transitions but less efficient than fully separated systems. These configurations support moderate metabolic rates without the high-pressure demands of terrestrial life. Skeletal features in anamniotes emphasize lightness for in water, with fishes exhibiting either cartilaginous endoskeletons, as in , or bony endoskeletons, as in , both reducing density to facilitate and energy-efficient locomotion. skeletons, while more ossified, retain lightweight elements like elongated limb bones adapted for flexible movement in viscous media, aiding semi-aquatic propulsion. The lack of amniotic support structures underscores their physiological tether to moist environments for overall .

Taxonomy and Phylogeny

Major Groups

Anamniotes encompass a diverse array of vertebrates that lack the amniotic egg characteristic of amniotes, forming a paraphyletic group that includes jawless fishes, cartilaginous fishes, bony fishes, and amphibians. These major taxonomic divisions highlight the of aquatic and semi-aquatic vertebrates adapted to various environments through distinct skeletal, reproductive, and fin structures. The , or jawless fishes, represent the most basal extant group of vertebrates and include the lampreys and hagfishes. Lampreys are often parasitic, attaching to host fishes with a suctorial disc and rasping mouth to feed on blood and tissues, while hagfishes are primarily that burrow into decaying carcasses and produce copious as a defense mechanism. Both groups possess cartilaginous skeletons, lack true jaws, and have no paired fins, relying instead on a continuous fold for locomotion; their persists as a primary axial support throughout life. Chondrichthyes, the cartilaginous fishes, comprise , rays, skates, and chimaeras, distinguished by their lightweight cartilaginous endoskeletons that enhance and agility in marine habitats. These fishes are covered in placoid scales, small tooth-like dermal denticles that reduce drag and contribute to a rough texture, and they exhibit via claspers in males, leading to either egg-laying or live birth in many species. The bony fishes, or , are divided into two subclasses: (ray-finned fishes) and (lobe-finned fishes), both featuring ossified skeletons, swim bladders for buoyancy, and bony gill covers. dominate modern aquatic ecosystems, encompassing over 30,000 species including teleosts such as , , and , characterized by fins supported by flexible lepidotrichia rays that allow precise maneuvering. , though less diverse today with only a few living representatives like coelacanths and lungfishes, possess fleshy lobe-like fins with internal bones that foreshadowed the limb structure in . Lissamphibia includes all modern amphibians, subdivided into three orders: (frogs and toads), (salamanders and newts), and Gymnophiona (caecilians). These limbless or limbed tetrapods share moist, permeable skin for and typically exhibit a biphasic with larval stages and terrestrial or semi- adults, though some show direct development without free-living larvae. Anurans are adapted for jumping with elongated hindlimbs, caudates retain tails and exhibit regenerative abilities, and gymnophiones are burrowing worm-like forms with reduced eyes and sensory tentacles.

Evolutionary Relationships

Anamniota represents a rather than a monophyletic within vertebrates, comprising all non- lineages that diverged basal to the origin of Amniota, including cyclostomes, fishes, and amphibians, but excluding the of reptiles, birds, and mammals. This paraphyly arises because amniotes evolved from within the lineage, rendering anamniotes a sequential series of branches leading to more derived terrestrial adaptations, without forming an exclusive common ancestor shared only among themselves. In the broader vertebrate phylogeny, key nodes establish the basal positioning of anamniotes. Cyclostomes (lampreys and hagfishes) form a monophyletic to gnathostomes ( vertebrates), supported by molecular evidence from reconstructions showing shared ancestral tetraploidization events but distinct subsequent chromosomal fusions unique to gnathostomes. Within gnathostomes, chondrichthyans (cartilaginous fishes) and osteichthyans (bony fishes) diverge as monophyletic , with fossil and molecular data indicating their split around 423 million years ago, positioning chondrichthyans as the basal gnathostome branch relative to the osteichthyan radiation. Sarcopterygians, a subgroup of osteichthyans, represent the lineage leading to tetrapods, with tetrapodomorph sarcopterygians giving rise to limbed vertebrates, including amphibians as the basal tetrapod group. Lissamphibia, the crown-group amphibians encompassing modern frogs, salamanders, and , exhibits strong supported by both molecular and morphological evidence. Molecular analyses of complete mitochondrial genomes reveal high bootstrap support for lissamphibian unity, with frogs and salamanders () as sisters to caecilians, rejecting alternative polyphyletic arrangements. Morphologically, shared derived traits such as pedicellate teeth and bifold tongue structure reinforce this , with phylogenetic placements favoring origins within temnospondyl dissorophoids as stem relatives, though lepospondyl affinities remain debated in some fossil-inclusive trees. These relationships underscore the nested position of lissamphibians within sarcopterygian-derived tetrapods, bridging aquatic anamniote grades to amniote innovations.

Evolutionary History

Origins and Early Development

The earliest anamniotes trace their origins to the late Cambrian period, approximately 500 million years ago, with the appearance of jawless vertebrates such as , which possessed tooth-like phosphatic elements and represented an early innovation in vertebrate mineralized structures. These primitive forms were eel-like and likely filter-fed in marine environments, marking the initial diversification of vertebrates from chordate ancestors. By the period around 480 million years ago, ostracoderms emerged as a diverse group of armored jawless fishes, characterized by heavy bony head shields composed of , dentine, and , which provided protection against predators while lacking paired fins or . Ostracoderms, including orders like and Cephalaspidomorphi, evolved filter-feeding adaptations and thrived in shallow marine and freshwater habitats, exemplifying the foundational role of anamniotes in vertebrate evolution. The period (419–358 million years ago), often termed the "Age of Fishes," witnessed a major radiation of anamniotic lineages with the rise of vertebrates, or gnathostomes, beginning in the around 419 million years ago. Placoderms, the earliest fishes, featured primitive derived from arches and robust dermal armor, enabling predatory lifestyles in and freshwater ecosystems; notable examples include the massive Dunkleosteus, which reached lengths of up to 10 meters. Concurrently, acanthodians—small, shark-like fishes with spiny fins and lightweight scales—diversified rapidly, adapting to a range of ecological niches through enhanced maneuverability and sensory capabilities. This " explosion" of jawed anamniotes, driven by innovations in predation and locomotion, significantly increased diversity and ecological impact. A critical phase in anamniote development occurred in the Late Devonian, around 375 million years ago, as lobe-finned fishes (sarcopterygians) evolved limb-like fins for navigating shallow, vegetated waters. Species such as , a predatory fish from the Miguasha Formation in , exhibited robust pectoral and pelvic fins supported by bony elements homologous to limbs, including a humerus-like that facilitated and in marginal habitats. These adaptations, including strengthened fin skeletons and improved lung-like swim bladders for air gulping, positioned lobe-finned anamniotes as direct precursors to early tetrapods without crossing into fully terrestrial forms.

Transition to Amniotic Vertebrates

The period, spanning approximately 359 to 299 million years ago, continued the evolution of anamniote tetrapods from Late forms like , which remained largely aquatic, relying on fish-like traits such as an anterior and paddle-like limbs for swimming in shallow waters. Over this era, however, selective pressures drove the development of semi-terrestrial adaptations in some lineages, including stronger limb girdles and improved , allowing limited forays onto swampy land environments amid the period's vast . These changes represented incremental steps toward terrestriality but still tethered reproduction to moist habitats. The defining transition to amniotic vertebrates occurred with the evolution of the amniotic egg, a shelled structure enclosing protective extraembryonic membranes that prevented and enabled development on dry land. This innovation likely arose in reptiliomorph stem groups during the early , with evidence from tracks dating to approximately 356 million years ago and body fossils around 312 million years ago, from lineages distinct from the temnospondyl and lepospondyl clades that gave rise to modern amphibians. By the onset of the Permian period approximately 299 million years ago, the amniotic egg facilitated fully independent terrestrial reproduction, decisively shifting ecological dominance from water-dependent anamniotes to more versatile amniotes. Environmental pressures, particularly the aridification following the around 305 million years ago, accelerated the decline of anamniote amphibians by diminishing habitats crucial for their larval stages and egg-laying. This climatic shift, coupled with competition from more adaptable forms, favored reptiliomorphs that possessed proto-amniotic traits, paving the way for the radiation of true amniotes and effectively ending anamniote prevalence on land. Living amphibians today represent relics of these transitional anamniote groups.

Diversity and Ecology

Modern Representatives

Anamniotes are represented today primarily by the vast diversity of fishes—including jawless cyclostomes such as lampreys and —and the more limited but ecologically significant amphibians, which together illustrate the persistence of non-amniotic reproductive strategies in modern vertebrates. Fishes encompass over 36,000 described as of 2025, with ray-finned teleosts () comprising the majority and dominating both freshwater and marine ecosystems through their and morphological innovations. Cyclostomes, numbering around 120 , exhibit unique ecological roles, such as the parasitic feeding of lampreys on fishes and the scavenging behavior of in deep-sea environments. These teleosts exhibit remarkable behavioral adaptations, such as the anadromous of like Oncorhynchus spp., which hatch in freshwater, mature in the ocean, and return to natal rivers to , supporting nutrient cycling across ecosystems. In contrast, lungfishes such as Protopterus spp. demonstrate survival strategies like , burrowing into mud cocoons during seasonal droughts to endure prolonged periods without water by reducing metabolic rates and relying on air-breathing. Amphibians number approximately 8,973 described species as of late 2025, with frogs and toads (Anura) forming the largest group and showcasing extreme physiological tolerances to environmental stressors. For instance, the wood frog (Rana sylvatica) can survive freezing temperatures where up to 70% of its body water turns to ice, halting heart function and breathing while protecting vital organs through cryoprotectant accumulation like glucose. , a limbless order, are specialized burrowing forms adapted to subterranean life, featuring reinforced skulls and annulated bodies that facilitate forceful wedging through soil in tropical habitats. Despite their biodiversity, many anamniote species face severe conservation challenges, with habitat loss and degradation affecting the majority of threatened populations across both groups. In amphibians, the chytrid fungus (Batrachochytrium dendrobatidis) has driven declines in over 500 species and contributed to at least 90 extinctions, exacerbating vulnerabilities in moist environments. For fishes, overfishing has depleted stocks in key species, leading to an 81% decline in global migratory freshwater populations over the past 50 years, while habitat fragmentation from dams and pollution further imperils their survival. Overall, around 41% of amphibian species and 26% of freshwater fish species are now threatened with extinction, underscoring the urgent need for targeted protection.

Habitats and Adaptations

Anamniotes, comprising fishes and amphibians, predominantly occupy aquatic and semi-aquatic environments due to their physiological dependence on water for respiration, , and reproduction. Fishes, the most diverse group, thrive in oceans, rivers, and lakes worldwide, where adaptations such as —darker dorsal coloration blending with the ocean floor from above and lighter ventral surfaces matching the sky from below—provide against predators. Additionally, many bony fishes possess a , a gas-filled organ that adjusts to maintain neutral floatation without constant , enabling efficient energy use in varied water depths. Amphibians exhibit semi-terrestrial lifestyles, often confined to riparian zones near , , and wetlands that offer high and access to breeding sites. These habitats mitigate the risk of through permeable skin, with behavioral adaptations like nocturnal activity reducing exposure to daytime and while facilitating moisture retention. Such reliance on moist environments underscores their physiological constraints, tying reproductive strategies closely to nearby water bodies for egg-laying and larval development. Anamniotes display a global distribution spanning extreme climates, from polar to tropical regions, supported by specialized adaptations. In polar waters, notothenioid fishes survive subzero temperatures through antifreeze glycoproteins in their blood, which bind to ice crystals to prevent internal freezing and allow dominance in the . Conversely, in tropical settings like the , poison dart frogs inhabit humid leaf litter and vegetation, where their vibrant aposematic coloration warns predators of skin toxins derived from diet, aiding survival in predator-rich, moist ecosystems. These examples illustrate how anamniotes' ecological niches are shaped by environmental pressures and physiological limits.

References

  1. [1]
    Anamniotes - an overview | ScienceDirect Topics
    Anamniotes refer to a group of vertebrates, including fish and amphibians, that do not possess an amnion during embryonic development.
  2. [2]
    Anamniotes - EPFL Graph Search
    Instead, they consistute an evolutionary grade (a paraphyletic group), ancestral to living tetrapods such as lissamphibians (modern amphibians) and amniotes ( ...
  3. [3]
    Anamniote - Definition and Examples - Biology Online Dictionary
    Jun 1, 2023 · The anamniotes are a group comprised of fishes and amphibians. They are vertebrates that do not belong to the clade Amniota.Missing: characteristics | Show results with:characteristics
  4. [4]
    29.3C: Evolution of Amniotes - Biology LibreTexts
    Nov 22, 2024 · The first amniotes evolved from their amphibian ancestors approximately 340 million years ago during the Carboniferous period.
  5. [5]
    Different solutions lead to similar life history traits across the great ...
    Feb 8, 2021 · ... anamniotes. Other than that ... Amniotes developed a triumvirate of extraembryonic membranes: the amnion, the allantois, and the chorion.
  6. [6]
    Brave New Propagules: Terrestrial Embryos in Anamniotic Eggs
    Apr 19, 2013 · Hatching for terrestrial anamniotes typically requires the appropriate level of development, submergence in water, and an additional ...
  7. [7]
    Amnion - Etymology, Origin & Meaning
    ### Etymology of 'Amnion'
  8. [8]
    ANAMNIOTE definition in American English - Collins Dictionary
    any of the vertebrates of the group Anamnia (Anamniota), comprising the cyclostomes, fishes, and amphibians, characterized by the absence of an amnion ...
  9. [9]
    The evolutionary origin of visual and somatosensory representation ...
    Mar 16, 2020 · ... anamniotes, such as amphibians, fish and cyclostomes (including lampreys), which diverged much earlier, were historically thought to process ...
  10. [10]
    [PDF] The Amniotes: “Reptiles”, birds, and mammals - Utexas
    The amniotic egg allowed tetrapods to become completely terrestrial. In an amniotic egg, a membrane called the amnion surrounds the embryo and creates a fluid- ...
  11. [11]
    Amniotic Egg - GEOL431 - Vertebrate Paleobiology
    An air-breathing egg characterized by a shell and extraembryonic membranes. These enclosed the amniote embryo in a private pond during its development.
  12. [12]
    Extended embryo retention and viviparity in the first amniotes - Nature
    Jun 12, 2023 · The amniotic egg with its complex fetal membranes was a key innovation in vertebrate evolution that enabled the great diversification of ...
  13. [13]
    From cyst to tubule: innovations in vertebrate spermatogenesis - PMC
    Many anamniotes undergo external fertilization in water, producing large numbers of eggs and sperms in a well‐timed manner. Thus, sexual difference in their ...
  14. [14]
    [PDF] Phylogeny and Evolutionary History of the Amniote Egg
    Jan 7, 2021 · Today, the conjoint occurrence of amnion, chorion, allantois, and cellular yolk sac is considered a com- plex and highly integrated ...
  15. [15]
    Egg predators improve the hatching success of salamander eggs - NIH
    Aug 22, 2023 · Previous studies show that these jelly layers provide eggs with protection against egg predators, egg pathogens, and desiccation. However, few ...
  16. [16]
    Animals: Vertebrates | Organismal Biology
    Cartilaginous skeletons appear in the cartilaginous fish (Chondrichthyes). Cartilaginous fish are living jawed fishes (gnathostomes) that possess paired ...<|separator|>
  17. [17]
    [PDF] Caecilian viviparity and amniote origins.
    These analyses confirm the long-held view (e.g. Dunn, 1942) that the primitive reproductive mode in caecilians is oviparity, with eggs hatching into free-living.
  18. [18]
    [PDF] The diversity and evolution of Amphibia
    Gymnophiona (Caecilians). Characteristics: •Degenerate Eyes (covered with skin or bone). •Internal Fertilization (phallodeum). •Left lung reduced or absent.
  19. [19]
    Amphibian Management and Laboratory Care - NCBI - NIH
    As the tadpoles grow, they should be continually thinned or given more medium so that near metamorphosis there are only four to six tadpoles/liter. The embryos ...
  20. [20]
    Effects of hydroperiod duration on developmental plasticity in tiger ...
    One example of developmental plasticity is the adaptation of tadpoles to temporary changes in their environment (Newman, 1992). Amphibians usually choose to ...
  21. [21]
    WFS 550 Fish Physiology - Osmoregulation/Gill Function
    Fish can resist this osmotic movement by having a relatively impermeable body covering, skin and scales help in this regard, however, the epithelial membrane of ...
  22. [22]
    Circular 919/FA005: Stress—Its Role in Fish Disease
    It is also important for osmoregulation. Scales and skin function as a physical barrier that protects the fish against injury. When these are damaged, a window ...
  23. [23]
    Biology 2e, Biological Diversity, Vertebrates, Amphibians
    The most important characteristic of extant amphibians is a moist, permeable skin used for cutaneous respiration, although lungs are found in the adults of many ...
  24. [24]
    Amphibians – Biology - UH Pressbooks
    The most important characteristic of extant amphibians is a moist, permeable skin used for cutaneous respiration. The fossil record provides evidence of ...
  25. [25]
    [PDF] The Multifunctional Fish Gill: Dominant Site of Gas Exchange ...
    Regardless of lineage, the majority of fish species uses the gill as the primary site of aquatic respiration. Aerial- breathing species may use the gill, swim ...
  26. [26]
    UNM scientists detail progressive organization of immune efficiency ...
    Sep 24, 2015 · Lungfish are unique because they breathe with structures like lungs as well as gills. More importantly, lungfish represent the transition of ...
  27. [27]
    Animal Circulatory Systems | Organismal Biology
    The circulatory system is the primary method used to transport nutrients and gases through most animal bodies.
  28. [28]
    Overview of the Circulatory System - OpenEd CUNY
    (b) Amphibians have two circulatory routes: one for oxygenation of the blood through the lungs and skin, and the other to take oxygen to the rest of the body.
  29. [29]
    [PDF] Fish Anatomy Skeleton
    Their skeletons are composed mainly of cartilage, which offers several benefits: Lightweight: Cartilage is less dense than bone, allowing these fish to remain.
  30. [30]
    Vertebrate Zoology Lab V- Tetrapoda & Amphibia - Faculty Web Pages
    What modifications in the skeleton of a frog do you observe that might be considered adaptations for jumping? If you were using the frog and salamander as part ...
  31. [31]
    [PDF] Indeterminate Growth: Could It Represent the Ancestral Condition?
    A phylogenetic/evolutionary perspective is important to understanding patterns of growth and their modifications; research on anamniotes (fishes and amphibians ...
  32. [32]
    The rise of predation in Jurassic lampreys - PMC - PubMed Central
    Oct 31, 2023 · They are characterized by their peculiar feeding behavior of eating blood or cutting off tissues from the hosts or prey to which they firmly ...
  33. [33]
    Fossil and jawless vertebrates - GEOL431 - Vertebrate Paleobiology
    They lacked jaws, or even the keratinous structures that hagfish and lampreys use to process food. The implication was that they were suspension or deposit- ...
  34. [34]
    [PDF] Chondrichthyes: Cartilaginous Fishes Superclass Gnathostomata
    Chondrichthyes are cartilaginous fishes, part of the jawed vertebrates, with a cartilaginous skeleton, placoid scales, and teeth not fused to jaws.
  35. [35]
    Expanding your fish vocabulary - UF/IFAS Extension Charlotte County
    Jun 18, 2018 · Unlike most bony fishes that mass spawn, sharks and rays reproduce through internal fertilization. Many sharks and rays give live birth. In ...
  36. [36]
    Major groups of bony fishes - Earthguide
    The major groups of bony fishes are ray-fins (with flexible rays) and lobe-fins (with fins radiating from a stalk). Ray-fins have bone skeletons, unlike sharks.
  37. [37]
    [PDF] Classification of the Major Taxa of Fish - UC Berkeley MCB
    internal fertilization. •! most ... Sharks, Rays, and Skates. •! one of the two groups ... larger as the fish grows, placoid scales stay the same size.
  38. [38]
    [PDF] Amphibian Characteristics, Taxonomy, and Evolution Goal of the ...
    Subclass: Lissamphibia. Orders: •Anura (frogs). •Caudata (salamanders). •Gymnophiona (caecilians). (amphibios: “double life”). Amphibia Characteristics. 1 ...Missing: dual | Show results with:dual
  39. [39]
    [PDF] THE AMPHIBIAN TREE OF LIFE - University of Richmond
    Feb 18, 1991 · ... AMPHIBIAN TREE OF LIFE. INTRODUCTION. Amphibians (caecilians, frogs, and sala- manders) are a conspicuous component of the world's vertebrate ...
  40. [40]
    The origin and early phylogenetic history of jawed vertebrates - PMC
    Nov 17, 2015 · Morphological and molecular data unambiguously indicate that chondrichthyans and osteichthyans are each monophyletic sister taxa.
  41. [41]
    Reconstruction of proto-vertebrate, proto-cyclostome and ... - Nature
    Jul 23, 2021 · We reconstruct high-resolution proto-vertebrate, proto-cyclostome and proto-gnathostome genomes. Our reconstructions resolve key questions regarding the early ...Missing: nodes | Show results with:nodes
  42. [42]
    On the origin of and phylogenetic relationships among living ... - NIH
    Of course, molecular data cannot directly assess the monophyly of Lissamphibia because it also includes fossil groups. However, as indicated by our molecular ...Figure 1 · Sequence Alignment And... · Figure 2
  43. [43]
    Stem caecilian from the Triassic of Colorado sheds light on ... - PNAS
    Jun 19, 2017 · Although molecular (8–12) and morphological (4, 5) studies support that caecilians belong to a monophyletic Lissamphibia that descended from a ...Stem Caecilian From The... · Holotype · Phylogenetic Relationships
  44. [44]
    Jawless Vertebrates - Digital Atlas of Ancient Life
    May 29, 2020 · Figure showing a phylogeny of cyclostomes and other vertebrate groups. Phylogenetic relationship of cyclostomes to other vertebrates ...Missing: key | Show results with:key
  45. [45]
    Gnathostomes: Jawed Fishes - OpenEd CUNY
    This clade arose approximately 370 million years ago in the early or middle Devonian. They are thought to be descended from the placoderms, which had ...
  46. [46]
    Eusthenopteron foordi (Fossil Lobe-finned Fish) - Digimorph
    Oct 8, 2007 · Eusthenopteron lived during the earlier part of the Late Devonian period, about 370 million years ago. Eusthenopteron's fame rests partly on ...
  47. [47]
    The humerus of Eusthenopteron: a puzzling organization presaging ...
    Eusthenopteron occurs abundantly at the 380 Myr-old locality of Miguasha, Quebec, Canada (Frasnian, Late Devonian [19]). The abundance of fossil material makes ...
  48. [48]
    Digital volumetric modeling reveals unique body plan ...
    Jun 20, 2025 · Our results show that Ichthyostega possessed a uniquely 'robust' body plan, combining traits typical of both 'fishes' (anterior center-of-mass) and 'tetrapods'.
  49. [49]
    The origin and early evolutionary history of amniotes - ScienceDirect
    Recent phylogenetic analyses of Paleozoic tetrapods have yielded startling new insights into the origin and early evolutionary history of amniotes.
  50. [50]
    Evolution of Body Size, Cope's Rule and the Origin of Amniotes
    The study suggests a substantial size increase before the origin of amniotes, with a possible early appearance of the amniotic egg during the Visean or ...Methods · Results · References · References of Appendix 2
  51. [51]
    Rainforest collapse in prehistoric times changed the course of ...
    Feb 6, 2018 · New research that reveals how the collapse initially caused the number of species to fall, affecting water-loving amphibians the most.
  52. [52]
    Physical and environmental drivers of Paleozoic tetrapod dispersal ...
    Dec 6, 2018 · Two episodes of reduced dispersal are observed: in the late Carboniferous in amphibians and at the end of the Guadalupian in amniotes. Both ...
  53. [53]
    Did genome duplication drive the origin of teleosts? A comparative ...
    Aug 8, 2009 · With approximately 28,872 species, teleost fishes constitute the dominant radiation of vertebrates on our planet [1]. One common explanation for ...
  54. [54]
    Teleost Fish: Habitat, Diversity & Reproduction - Basic Biology
    Dec 20, 2015 · They are the most advanced of all fishes and are dominant in both marine and freshwater habitats. Teleost fish species are found throughout ...
  55. [55]
    Salmon Are Anadromous Fish. What Does That Mean? - IFLScience
    May 9, 2025 · Anadromous fish, like salmon, migrate from freshwater to the ocean, then return to freshwater to spawn. Salmon begin in freshwater streams and ...
  56. [56]
    Aestivation and brain of the African lungfish Protopterus annectens
    Jul 1, 2014 · Aestivation comprises three phases: induction, maintenance, and arousal. During the induction phase, the aestivating lungfish detects ...
  57. [57]
    AmphibiaWeb Species Lists
    The total number of amphibian species is currently 8,973 (Nov 12, 2025) . Anura (frogs and toads) # families: 57 # genera: 503 # species: 7915. Allophrynidae (3)
  58. [58]
    Wood frog adaptations to overwintering in Alaska: new limits to ...
    Jun 15, 2014 · Wood frogs in Interior Alaska survive freezing to extreme limits and durations compared with those described in animals collected in southern Canada or the ...INTRODUCTION · RESULTS · DISCUSSION · MATERIALS AND METHODS
  59. [59]
    The Amazing Caecilians - Tetrapod Zoology
    Oct 25, 2022 · They are predominantly fossorial (adapted for burrowing), although some are aquatic or semiaquatic and some terrestrial species have aquatic ...
  60. [60]
    Ongoing declines for the world's amphibians in the face of emerging ...
    Oct 4, 2023 · ... species, bringing the number of amphibians on the IUCN Red List to 8,011 (39.9% increase from 2004; covering 92.9% of 8,615 described species).
  61. [61]
    Biodiversity is decimated by the cascading effects of the amphibian ...
    Jul 21, 2022 · A recent global assessment documented that Bd has influenced the decline of at least 500 amphibian species, including the extinction of 90 species.
  62. [62]
    What Is Overfishing? | World Wildlife Fund
    Overfishing significantly depletes ocean wildlife populations. Here, learn its causes and consequences, plus how sustainable fishing helps.
  63. [63]
    Global migratory freshwater fish populations plummet by 81%: Report
    Jul 8, 2024 · Habitat loss, degradation and overfishing are the main threats to migratory fish, which are crucial for food security, livelihoods and ...
  64. [64]
    State of the World's Amphibians: A Roadmap for Action
    Mar 20, 2025 · Amphibians are the most endangered vertebrate group, with 41% of species facing the threat of extinction. The report not only identifies which ...
  65. [65]
    Freshwater fish highlight escalating climate impacts on species - IUCN
    Dec 11, 2023 · A new assessment finds that 25% of freshwater fish are at risk of extinction, and at least 17% of threatened freshwater fish species are ...
  66. [66]
    [PDF] Fishes of New York - NY.Gov
    Most fish exhibit countershading, an adaptation that makes them difficult for predators to see. By having dark coloration on the top half of their bodies, they ...
  67. [67]
    Living in Water Chapter 4 - TPWD
    The more gas (oxygen) it contains, the higher a fish will suspend or float in the water. Some species of fish can also use their swim bladder to make sounds ...
  68. [68]
    Amphibian Biology and Husbandry
    Amphibians are ectotherms, and their skin is permeable to water, ions, and respiratory gases. Most species are secretive and, in many cases, nocturnal. The ...
  69. [69]
    Adaptation of Proteins to the Cold in Antarctic Fish - NIH
    Abstract. The evolution of antifreeze glycoproteins has enabled notothenioid fish to flourish in the freezing waters of the Southern Ocean.
  70. [70]
    Poison frogs | Smithsonian's National Zoo and Conservation Biology ...
    They live in wet, tropical forests in Central and South America where their diet contributes to the toxins they secrete through their skin.Missing: Amazon adaptations