Evolution of Fishes PDF

Summary

This document details the evolution of bony fishes (Osteichthyes) and their diverse adaptations. It explores the early emergence of these fish in the Silurian period, and their subsequent diversification and adaptation to various environments.

Full Transcript

Osteichthyes (bony fishes) In the early to mid Silurian period, a group
of fishes with bony endoskeletons gave rise to over 90% of all living
fishes and all living tetrapods (four limbed animals). It was originally
believed that these were the only fish with bony skeletons, but it is
now known that other groups such as the ostracoderms, placoderms and
acanthodians also had bone. Bony fishes and tetrapods are united by the
presence of endochondral bone (bone which replaces cartilage during
development), the presence of lungs or a swim bladder derived from the
gut, as well as dental and cranial characteristics. The term
Osteichthyes is a convenient term, but does not represent a natural
group, and is therefore not usually recognised as a valid taxon. Fossils
of the earliest bony fishes show a bony operculum (gill cover) in common
with acanthians, showing a likely common ancestor. By the middle of the
Devonian, fishes had radiated into two main groups, the ray finned
fishes (class Actinopterygii) including modern bony fishes, and the
Sarcopterygii, (lobe finned fishes) which are represented today by only
eight fish-like vertebrates, the lungfishes and coelacanths, which is a
sister group to the land vertebrates. Several key adaptations
contributed to their success. The bony operculum and associated muscles
allow for more efficient respiration, and the progressively more
specialised jaw musculature and skeletal elements have produced many
effective feeding adaptations. Class Actinopterygii Ray finned fish
number almost 23,600 species. Earliest examples (paleoniscids) were
small, with large eyes, a heteroceral tail and thick interlocking
scales. These fishes had a single dorsal fin and numerous bony rays
derived from scales stacked end to end, and were very distinct from the
lobe finned fishes with which they shared the Devonian waters. The
paleoniscids were first seen as the ostracoderms. Placoderms and
acanthodians were declining, which suggests morphological
specialisations evolving in the actinopterygii gave them superiority
over the other forms of the period. From these earliest forms, two major
groups emerged. There were those with the most primitive characteristics
(chondrosteans) represented today only by sturgeons and paddlefishes.
These fishes show many similarities with their paleoniscid ancestors,
including the tail and scale forms. Unfortunately, they are considered
superior 'sport fish' and larger specimens are prized. The second major
group that emerged from the palaeoniscid was the neopterygians, which
appeared in the late Permian, radiating extensively throughout the
Mesozoic. One branch resulted in the emergence of the modern bony
fishes, the teleosts. There are two surviving genera of the early
neopterygians, the bowfins, and gars. Both may surface to gulp air,
filling their vasacularised swim bladder with air, which supplements the
oxygen obtained via the gills. Teleost diversity is extraordinary, with
the 23,600 (approximately) described species representing 96% of all
living fish species and about half of all vertebrate species. It has
also been estimated that between 5000 and 10,000 (or more) species have
yet to be described. Almost all of the new species discovered yearly
(averaging 200 species) are from tropical South America, or deep oceanic
habitats. Teleosts are incredibly diverse, ranging from 10mm adult
gobies to 17m oarfish They inhabit waters from 5200m above sea level
(Tibetan streams) to 8000m ocean depths, in temperatures from -2 C in
the Antarctic, to 44 C in hot springs, in complete darkness in caves,
from three times the salinity of normal sea water to fresh water and
swamps without oxygen, or, remarkably, making terrestrial journeys
(mudskippers). This huge range of forms is due to several morphological
trends. Light thin cycloid and ctenoid scales replaced the heavy dermal
armour of primitive ray finned fishes; some (eels and catfishes)
completely lack scales. The increased mobility and speed resulting from
the loss of heavy armour improved predator avoidance and feeding
efficiency. Most fish are protected by scales (overlapping bony plates
covering all or part of the body). Scales can be classified into four
types: placoid, cycloid, ctenoid, and ganoid. Ctenoid scales have small
points on the surface and are rough to the touch. These, and the smooth,
rounded cycloid scales are most common among modern fish species. Some,
less highly developed fishes, have tough ganoid scales, while sharks and
many rays have placoid scales, sharp and tooth-like. Changes in the fins
of teleosts have increased manoeuvrability, speed, and have allowed fins
to become specialised for other functions. The symmetrical shape of the
homocercal tails of most teleosts (pointed, round, truncate,
emarginated, forked and lunate) focus muscular effort on the tail
resulting in increased speed. The dorsal fin shifted from providing a
fixed keel to prevent rolling, to a flexible and highly specialised
structure in higher teleosts. The changes in the morphology of fins were
useful for camouflage, braking, streamlining, and social modification,
even acting as a prey lure in anglerfish, venom delivery in scorpion
fish, and the suctorial disc of shark suckers. The swim bladder changed
from a primarily a respiratory function to one of buoyancy. Teleost
taxonomy is complex; some of the orders of the more well-known forms are
given below. Order Notacanthiformes, (halosaurs, spiny eels), Order
Anguilliformes (true eels), Order Clupeiformes, (herrings, anchovies),
Order Cypriniformes, (barbs, carp, danios, goldfishes, loaches, minnows,
rasboras) Order Characiformes, (characins, pencilfishes, hatchetfishes,
piranhas, tetras). Order Gymnotiformes, (electric eels, knifefishes),
Order Siluriformes (catfishes), Order Salmoniformes, (salmon, trout),
Order Esociformes (pike), Order Stomiiformes, ( bristlemouths , marine
hatchetfishes), Order Aulopiformes (Bombay duck , lancetfishes), Order
Myctophiformes,( lanternfishes), Order Lampriformes ( oarfish, opah
ribbonfishes), Order Percopsiformes, ( cavefishes, trout-perches), Order
Batrachoidiformes,( toadfishes), Order Lophiiformes, (anglerfishes)
Order Gadiformes,( cods),Order Mugiliformes,(mullets), Order
Beloniformes ( flyingfishes), Order Cetomimiformes (whalefishes), Order
Cyprinodontiformes ( livebearers, killifishes),Order Zeiformes, (dories)
Order Gasterosteiformes ( sticklebacks, pipefishes, seahorses, Order
Tetraodontiformes ( filefishes, pufferfish), Order Pleuronectiformes, (
flatfishes), Order Scorpaeniformes (scorpionfishes, sculpins), and
finally Order Perciformes 40% of all fish including anabantids, bass,
cichlids, gobies, gouramis, mackerel, perches, scats, whiting, wrasses.
Class Sarcopterygii (lobe finned fishes) Lobe finned fishes today are
limited to eight species (six lungfish and two coelacanths); these are
the survivors of an abundant Devonian group. All early sarcopterygians
had lungs as well as gills and a heterocercal type tail. During the
Palaeozoic era, the tail became symmetrical, with medial dorsal and
ventral fins displaced posteriorly to form one continuous, flexible fin
around the tail, also known as a diphycercal tail. The strong
fleshy-paired lobed fins (pectoral and pelvic) may have been used much
as legs are in terrestrial vertebrates, to move along the bottom. They
had powerful jaws and skin covered in heavy scales. The Australian
Lungfish (Neoceratodus) is the living form most like its ancestor. It
can be up to 1.5m in length, and unlike the other lungfish, relies on
gill respiration, and cannot survive for long out of water. The African
lungfish, Protopterus, lives in streams and lakes that can dry out. When
this occurs, the fish burrows down into the mud at the beginning of the
dry season, and secretes copious slime, which mixes with the mud to form
a cocoon, in which it lives until the rains come. Rhipidistians
flourished in the late Palaeozoic era, before becoming extinct. They are
a very important group, because they include the ancestors of the
tetrapods. The Coelacanths also arose in the Devonian period, reaching
their peak in the Mesozoic era; it was previously thought they became
extinct at the end of the Mesozoic, 70 million years ago. In 1938, the
remains of a fish that resembled these long dead animals, was found in a
fisherman's net off South Africa. A population was found living at great
depth off the Comoro islands near Madagascar, and they were thought to
be the only living population. However, in 1998 a new species of
coelacanth was discovered near Sulawesi, Indonesia, 10,000km from the
Comoro islands. The 'modern' coelacanths are descendants of the Devonian
freshwater species, the tail is diphyceral, but possesses a small lobe
between the upper and lower caudal lobes, giving a three pronged
structure. Coelacanths are a deep metallic blue, with irregular white or
brassy flecks, which provide camouflage against the dark lava cave reefs
they inhabit. Young are born fully formed after hatching internally from
eggs 9 cm in diameter, the largest among bony fishes. Part 3: tetrapods,
the move to land Adaptations for living on land is a major theme for the
rest of the vertebrate groups, these animals form a diverse group called
tetrapods. Amphibians and amniotes (including reptiles, birds and
mammals) represent two major branches of tetrapod evolution. The
movement from water to land is perhaps the most dramatic evolutionary
event known, as it involves the invasion of a physically hazardous
environment. Life evolved in water, animals are mostly made of water,
and all cellular activities occur in water. Tetrapods were not the first
living organisms to solve these problems. Vascular plants, pulmonate
snails and tracheae arthropods preceded vertebrates to the land, and
winged insects were diversifying at approximately the same time
vertebrates moved into terrestrial environments. The invasion of the
land required modification of almost every body system. Aquatic and
terrestrial vertebrates retain many basic structural land functional
similarities, however, the transitional stages between the two forms is
most clearly seen in the amphibians, which undergo the change in each
individual life history. There are several important physical
differences that animals must deal with in order to move from water to
air. These include oxygen content, density temperature regulation, and
habitat diversity. Air is at least 20% higher in oxygen than water, and
diffuses much more rapidly in air than water. Consequently, terrestrial
animals can obtain oxygen more easily than aquatic ones, once the
necessary adaptations have occurred. As air is 1000 times less buoyant
than water, and is 50 times less viscous, problems arise, as it provides
less bodily support than water. Terrestrial animals needed to have
stronger limbs and remodel their skeletons to deal with the increased
effects of gravity. Air fluctuates in temperature to a much greater
extent, experiencing harsh and unpredictable cycles of freezing and
thawing with the often accompanying flood and drought. Terrestrial
animals, thus, need to have behavioural land physiological adaptations
to protect themselves from thermal extremes. The most important
strategy, which solved this problem is homoeothermy (regulated constant
body temperature) developed in birds and mammals. Despite these quite
profound problems, the move to land had many benefits, from the increase
in the number of available habitats, from forest (polar, temperate and
tropical) grasslands, deserts, alpine, swamps, heathland, oceanic
islands and Polar regions. Early evolution of terrestrial vertebrates
The Devonian period, beginning 400 million years ago, was characterised
by mild temperature and alternating drought and floods. During this era,
some primarily aquatic vertebrates evolved two features that were vital
for permitting subsequent terrestrial evolution - limbs and lungs.
Devonian freshwater habitats were unstable, with periods of drying,
flood and stagnant water. Only those fishes able to acquire oxygen from
the air could survive these unpredictable conditions. Gills were
unsuitable for these conditions, as in air the gill filaments collapse,
dry, and lose the functioning capabilities. Virtually all freshwater
fish that survived this period (including the lungfish and coelacanths)
had a type of lung that developed as an outgrowth of the pharynx.
Improving vascularity and surrounding it with a rich capillary network
filled with arterial blood enhanced the efficiency of the air-filled
cavity. Oxygenated blood returned directly to the heart by a pulmonary
vein to form a complete pulmonary circuit. Thus, the double circulation
characteristic of all tetrapods originated, a systematic circulation
serving the body, and a pulmonary circulation supplying the lungs.
Vertebrate limbs also evolved during the Devonian period. An examination
of the bony elements of the paired lobed fins of sarcopterygians shows
they broadly resemble the equivalent limbs of amphibians. The fins have
long, ray-like dermal bones (lepidotrichia) that characterise the limbs
as fins, but they also contain a well-developed endochondral or internal
skeleton, such as appendicular bones (humerus and femur) that articulate
with the pectoral and pelvic girdles, respectively. The diagram shows a
comparison of the limb bones of a crossopterygian fish (right) and the
limb bones of an early amphibian (left). r = radius u = ulna h = humerus
Until recently, it was thought that early tetrapods had five 'fingers
and toes', the pentadactyl arrangement found in most living tetrapods.
However, there is fossil evidence to suggest that the very first
tetrapods had many multiple digits, more like the crossopterygian fish,
the five-digit arrangement stabilised soon afterwards. It is thought
that, due to seasonal droughts, individuals that were able to flop or
pull themselves to a deeper neighbouring pool survived, and that those
with fleshy fins had the greater ability to do this, circumstances,
which directly support Darwin's theory of survival of the fittest.
Unfortunately, fossils found recently have contradicted this very
plausible explanation. This new evidence suggests that one of the
earliest known tetrapods (Acanthostega) was a fully aquatic animal. A
consensus among zoologists is now emerging that tetrapods evolved their
limbs underwater, and subsequently moved onto land. The evidence points
to lobe finned fishes as the closest relatives of tetrapods. In
taxonomic terms they are sister groups. Both lobe finned fishes and
early tetrapods such as Acanthostega and Ichthyostega share several
characteristics of their skull, teeth and pectoral girdle. Ichthyostega
represents an early offshoot of tetrapod phylogeny that possessed
several adaptations (in addition to jointed limbs), which equipped it
for life on land. These adaptations included stronger vertebrae and
associated muscles to support the body in air, new muscles to elevate
the head, strengthened shoulder and hip girdles, protective rib cage,
modified ear structure for detecting airborne sounds, foreshortening of
the skull, and lengthening of the snout which improved olfactory powers
for detecting air borne odours. Yet, Ichthyostega still strongly
resembled aquatic forms, as it retained a tail complete with fin rays,
and had opercula (gill covers) bones. Radiation of the tetrapods The
Devonian era was followed by the Carboniferous period, characterised by
a warm, wet climate producing a swampy environment filled with mosses
and ferns. Tetrapods radiated quickly into a variety of forms, feeding
on the abundant insects and aquatic invertebrates. The exact
relationships between the various groups of this period are still
unclear, and have been revised many times. One group, the Lissamphibia,
(which contains the modern amphibians) is distinguished by generally
having only four digits on the forelimb. The lissamphibia diversified to
produce the ancestors of the three major groups of modern amphibians,
the Anura (frogs) Urodela or Caudata (salamanders) and Apoda or
Gymnophiona (caecilians). Amphibians extended their adaptations to
living in water during this period, including becoming flatter to move
through shallow water. Early salamanders had weak limbs, and developed a
tail useful for swimming. Even anurans, which are now largely
terrestrial as adults, developed specialised hind limbs with webbing,
which is better suited for swimming than walking on land. The adaptation
of amphibians of being able to absorb oxygen via their skin in damp
environments was very useful in the swampy carboniferous environment,
but caused a significant desiccation problem for descendants in drier
environments. Two additional groups of carboniferous and Permian
tetrapods (lepospondyls and anthracosuars) are thought (by skull
structure) to be closer to amniotes than the group containing the
lissamphibia (known as the temnospondyls). These two groups are thought
to be the animals whose descendants became the higher vertebrate groups.
Modern amphibians The three living amphibian orders contain more than
4200 species. Most share terrestrial adaptations, including skeletal
strengthening, a shift in specialised sense organs from the ancestral
lateral line system to senses of smell and hearing. However, they still
largely remain bound to an aquatic environment as they require water to
reproduce, they lay eggs without casings (so at risk of desiccation),
which hatch into gill bearing larvae. A metamorphosis then occurs in
which gills are lost and the lungs, which are present throughout larval
life, take over. As is common with animals, there are exceptions to this
pattern with some salamanders (axolotls) retaining the larval form
throughout life. Others live entirely on land, having no aquatic larval
form. Some frogs have also developed a terrestrial habit by eliminating
the larval stage. Completely terrestrial amphibians may lay eggs under
rocks or logs, in flooded tree holes or in pockets on a parent's back.
Despite these adaptations, even the exclusively terrestrial species
still rely on moisture, as there skin is thin, requiring moisture to
prevent desiccation. Amphibians also require moderately cool and
constant temperatures, as they are exothermic (have the same body
temperature as the environment). Order Gymnophiona (caecilians),
consists of about 160 species of elongated, limbless, burrowing
creatures. Their habitats are the tropical rainforests of South America,
with a few species in Africa and South East Asia. They have vertebrae,
long ribs, and a terminal anus; eyes are small, with most species being
blind as adults. They have special sensory tentacles on the snout, which
they use to locate their prey of worms and other invertebrates
underground. Fertilisation is internal, males have a protrusible
copulatory organ, and eggs are laid in moist ground near water. Larvae
may be aquatic or larval development is completed within the egg. In
some species, eggs are guarded in folds of the body; viviparity is
common, with embryos obtaining nourishment by eating the wall of the
oviduct. Order Caudata (Salamanders) are the tailed amphibians, with
approximately 360 species that can be found in almost all northern
temperate regions, being particularly abundant in North America. They
are also found in tropical central and northern South America.
Salamander are typically small, most are under 15cm long, although an
aquatic Japanese species can grow up to 1.5m long. Most salamanders have
limbs at right angles to their body, with fore and hind limbs of equal
size, although in some burrowing forms, limbs are rudimentary or absent.
They are carnivorous both when larvae and adult, preying on worms, small
arthropods and molluscs. Most are only attracted to moving prey. Like
other amphibians they are exothermic, and have a low metabolic rate.
Some species have an entirely aquatic life cycle, although most are
metamorphic, having aquatic larvae and terrestrial adult forms that live
in moist environments under logs and stones. Fertilisation is usually
internal, normally after the female picks up a packet of sperm
(spermatophore) that has been deposited on the substratum. The male
deposits the spermatophore, then leads the following female over it,
tilting her front end up by arching his tail so her vent contacts the
spermatophore. Aquatic species lay eggs in clusters or strings in water.
Eggs hatch to produce a 'tadpole' with external gills and a fin-like
tail. Completely terrestrial species lay eggs under logs, or in moist
earth. Many species guard eggs, and they have direct development,
bypassing the larval stage. Order Anura (frogs and toads) This group is
first known in the fossil record from the Jurassic period, 150 million
years ago, and today the order Anura contains 5250 species in 33
families, of which the Leptodactylidae (1100 spp.), Hylidae (800 spp.)
and Ranidae (750 spp.) are the richest in species. About 88% of
amphibian species are frogs. The use of the common names 'frog' and
'toad' has no taxonomic justification. From a taxonomic perspective, all
members of the order, Anura, are frogs, but only members of the family,
Bufonidae, are considered 'true toads'. The use of the term 'frog' in
common names usually refers to species that are aquatic or semi-aquatic
with smooth and/or moist skins, and the term 'toad' generally refers to
species that tend to be terrestrial with dry, warty skin. Frogs and
toads are broadly classified into three suborders: Archaeobatrachia,
which includes four families of primitive frogs; Mesobatrachia, which
includes five families of evolutionary intermediate frogs; and
Neobatrachia, by far the largest group, which contains the remaining 24
families of 'modern' frogs, including the most common species throughout
the world. This classification is based on such morphological features
as the number of vertebrae, the structure of the pectoral girdle, and
the morphology of tadpoles. While this classification is largely
accepted, relationships amongst families of frogs are still debated.
Future studies of molecular genetics should soon provide further
insights into the evolutionary relationships amongst frog families The
morphology of frogs is unique among amphibians. Compared with the other
two groups of amphibians, frogs are unusual, as they lack tails as
adults and legs are more suited to jumping than walking. The physiology
of frogs is similar to other amphibians, because oxygen can pass through
their highly permeable skin; this makes frogs susceptible to many toxins
in the environment, some of which can similarly dissolve in the layer of
water and be passed into their bloodstream. This may be a reason for the
decline in frog populations. Widespread population crashes and mass
localised extinction have been noted since the 1980s all over the world.
These declines are perceived as one of the most critical threats to
global biodiversity, and several causes are believed to be involved,
including habitat destruction/modification, over-exploitation,
pollution, pesticide use, introduced species, climate change, increased
ultraviolet-B radiation (UV-B) and disease. However, many of the causes
of amphibian declines are poorly understood. Many characteristics are
not shared by all of the approximately 5250 described frog species.
However, some general characteristics distinguish them from other
amphibians. Frogs are usually well suited to jumping, with long hind
legs and elongated ankle bones. They have a short vertebral column, with
no more than ten free vertebrae, followed by a fused tailbone (urostyle
or coccyx), typically resulting in a tailless phenotype. Frogs range in
size from 10mm (Brachycephalus didactylus of Brazil and
Eleutherodactylus iberia of Cuba) to 300mm (goliath frog, Conraua
goliath, of Cameroon). The skin hangs loosely on the body, because of
the lack of loose connective tissue. Skin texture varies from smooth to
warty or folded. Frogs have three eyelid membranes: one is transparent
to protect the eyes underwater, and two vary from translucent to opaque.
Frogs have a tympanum on each side of the head, which is involved in
hearing and, in some species, is covered by skin. Most frogs have teeth
(maxillary teeth), consisting of a ridge of very small cone teeth around
the upper edge of the jaw. They may also have vomerine teeth on the roof
of their mouth. There are no teeth on the lower jaw, and food is usually
swallowed whole. True toads do not possess teeth. Their aquatic
reproductive habits and water permeable skin prevent them from being too
far from moist environments, and the exothermic temperature regulation
prevents them from occupying polar and sub polar environments.
Camouflage is a common defensive mechanism, although many frogs are also
nocturnal to reduce predation and dessciation. Some species can alter
their skin colour, although it is usually restricted to shades of one or
two colours. For example, White\'s tree frog varies in shades of green
and brown. Some species change colour between night and day, and light
and moisture stimulate the pigmented skin cells and cause them to expand
or contract. Many frogs contain mild toxins making them distasteful to
potential predators. All toads have large poison glands (parotid
glands), behind the eyes on the top of the head. The chemical makeup of
toxins in frogs varies from irritants to hallucinogens, convulsants,
nerve poisons, and vasoconstrictors. Many predators of frogs have
adapted to tolerate high levels of these poisons. Poisonous frogs tend
to advertise their toxicity with bright colours, an adaptive strategy
known as aposematism. When mature, Anurans usually assemble at a water
source (pond or stream) to breed. Many return to the bodies of water
where they were born, often resulting in annual migrations involving
thousands of frogs. Once at the breeding ground, male frogs call to
attract a mate, the call is species specific, attracting only females of
that species. The male and female frogs then undergo amplexus. This
involves the male mounting the female and gripping her tightly.
Fertilisation is external. The female releases her eggs, which the male
frog covers with a sperm solution. The eggs then swell and develop a
protective coating. The eggs are typically brown or black, with a clear,
gelatine-like covering. Most temperate species of frogs reproduce
between late autumn and early spring. Water temperatures at this time of
year are relatively low (4-10 Celsius) so this helps the developing
tadpoles, because dissolved oxygen concentrations in the water are
highest at cold temperatures. More importantly, reproducing early in the
season ensures that appropriate food is available to the developing
frogs at the right time. It is estimated that up to 20% of amphibian
species may care for their young in one way or another, and there is a
great diversity in parental behaviours. Some species of poison dart frog
lay eggs on the forest floor and protect them, guarding the eggs from
predation and keeping them moist with their own urine. After hatching, a
parent (the sex depends upon the species) will move them, on its back,
to a water-holding plant. The parent then feeds them by laying
unfertilised eggs in the 'pool' until the young metamorphose. Other
frogs carry the eggs and tadpoles on their hind legs or back (Alytes
spp.) or protect their offspring inside their own bodies (Assa
darlingtoni). It has pouches along its side in which the tadpoles reside
until metamorphosis. Female gastric-brooding frogs (Rheobatrachus)
swallow their tadpoles, which then develop in the stomach. However,
despite all the incredible adaptations of the animals described in this
module, they are all still tied to water, at least to reproduce. Eggs
and adult skin have little or no protection against very hot, very cold
or dry conditions, which has greatly restricted them to moist
warm/temperate environments. The evolution of species, which have
overcome these problems, will be dealt with in the next module,
particularly the evolution of the amniote egg, reptiles and birds.