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Transcript

The animals most familiar to us belong to phylum Chordata (Chorda -
cord), and humans share the characteristic that gives this group its
name, the notochord. All members of the phylum possess this structure,
although it can be restricted to early development.Its primary function
is to support and stiffen the body, providing support for muscles. The
structural plan of chordates share many features with invertebrate
groups, such as bilateral symmetry, anterior-posterior axis, coelom
(tube within a tube arrangement), metamerism, and cephalisation.
However, there is debate about the exact phylogeny relationships between
groups. Two possible lines have been proposed; the earlier speculation,
which focused on arthropod-annelid mollusc group (Protostomia branch) of
the invertebrates, has currently fallen out of favour. It is now
believed that only members of the echinoderm-hemichordate group
(Deuterosome branch) could be a sister group to the chordates. Reasons
for this theory include the possession of common characteristics such
as, radial embryonic cleavage, an anus derived from the first embryonic
opening (blastopore), and a mouth derived from an opening of secondary
origin. As a whole, there is more fundamental unity of plan throughout
all the organs and systems of this phylum than there is in many other
phyla. Ecologically, the chordates are amongst the most adaptable of all
organic forms, and are able to utilise almost every habitat. They
illustrate the basic evolutionary processes of the origin of new
structures, adaptive strategies, and adaptive radiation. Chordate
characteristics The five distinctive characteristics that set chordates
apart from all other phyla are notochord, dorsal tubular nerve cord,
pharyngeal pouches or slits endostyle and post anal tail. These
characteristics are always found at some embryonic stage, although they
may be altered or may disappear in later stages of the life cycle. All,
but pharyngeal pouches/slits are unique to chordates. Hemichordates also
possess these structures. The notochord is a flexible, rod-shaped
structure extending the length of the body; it is the first part of the
endoskeleton to appear in the embryo of all chordates. Notochord is an
axis for muscle attachment, and, as it can bend without shortening, it
permits adulatory movements of the body. It is composed of cells derived
from the mesoderm. In lower vertebrates, it persists throughout life as
the main axial support of the body, while in higher vertebrates it is
replaced by the vertebral column. The notochord is found on the ventral
surface of the neural tube. The dorsal tubular nerve cord is unique to
the chordates. In most invertebrate phyla that have nerve cords, it is
ventral to the alimentary canal and is solid. In chordates, the single
cord is dorsal to other alimentary canal, and is a tube. The anterior
end becomes enlarged to form a brain in most chordates. The hollow cord
is produced in the embryo by in folding of ectodermic cells on the
dorsal body surface above the notochord. In vertebrates, the nerve cord
passes thorough the protective neural larches of the vertebrae. A bony
or cartilaginous cranium surrounds the anterior brain. Pharyngeal slits
are openings that lead from the pharyngeal cavity to the outside. They
are formed by invagination of the endodermic lining of the pharynx
(pharyngeal pouches). The perforated pharynx evolved as a filter-feeding
device. Rows of beating cilia cause currents of water to flow through
the mouth, through the pharyngeal slits and out of the body through a
hole in the body wall called the atriopore. Small particles in the water
are trapped by the cilia in different parts of the mouth chamber and
separated into materials that the organism can eat. In primitive
chordates, the pharyngeal slits are used to strain water and filter out
food particles; in fish, they are modified for respiration. In tetrapod
(four footed) vertebrates, they give rise to several different
structures, including the Eustachian tube, middle ear cavity, tonsils
and parathyroid gland. The endostyle, or thyroid gland, was not
recognised as a chordate feature until recently. However, it (or its
derivative, the thyroid gland) is found in all chordates, but in no
other phyla. The end style, which is found in the pharyngeal floor,
secretes mucus, which traps small food particles brought into the
pharyngeal cavity. Some cells in the end style secrete iodinated
proteins. These cells are homologous with the iodine-based hormones
secreted by the thyroid gland of vertebrates. The post-anal tail,
together with somatic musculature and the stiffening notochord provide
motility for Laval tunicates and amphioxus. As a structure added to the
body behind the end of the digestive tract, the tail has clearly evolved
specifically for locomotion, efficiency is increased with the
introduction of fins. The tail is vestigial in humans (the coccyx, a
series of small vertebrae at the end of the spinal column, which is not
visible externally). However, most other mammals have a movable tail
that can perform locomotary, balance and communication functions,
depending on species. Phylogeny and evolution Since the time of Darwin,
zoologists have debated the question of chordate origins and
relationships. However, the fact that the earliest protochordates were
probably soft-bodied creatures, which were unlikely to have been
preserved as fossils, has meant that much has needed to be inferred from
living forms. Analysis of the early development of modern forms shows
they tend to be more evolutionary conserved than the differentiated
adult forms they become. Most early efforts to identify relationships
between the chordate groups are now recognised as based on similarities
related to analogy rather than homology. Analogous structures are those
that perform similar functions (e.g. wings of birds and insects).
Homologous structures share a common origin, but may look different, and
perform very different functions, e.g. the vertebrate pentadactyl limb.
Homologous structure reveals common ancestry, whilst analogous
structures do not. The Deuterostomia (echinoderms, hemichordates,
chordates) have their common origins in an ancient Precambrian ancestor.
Several lines of anatomical developmental and molecular evidence suggest
that, some time later, at the beginning of the Cambrian period, (570
million years ago) the first distinct chordates emerged from a line
related to echinoderms and hemichordates. Some theorists propose that
the Hemichordates are a sister group to the Chordates, citing pharyngeal
slits as a shared derived characteristic, others suggest chordates arose
from an extinct free-living echinoderm. While modern echinoderms have
little in physical appearance to link them to chordates, an evolutionary
relationship between the groups is obvious from the fossil record. One
group of fossil echinoderms, the Calcichorda, has been suggested as a
chordate ancestor. These small, non-symmetrical forms had a head, a
structure that looked homologous to pharyngeal slits, a post anal tail,
a notochord and muscle blocks. However, there are problems with this
hypothesis, as the mineral of the skeleton differs (calcium phosphate in
chordates and calcium carbonate in clavichordists) and this group was
alive in the Ordovician, a more recent age than that proposed for the
first chordates (fossil examples from early Cambrian). Despite the
uncertainty over the ancestral chordate form, two living protochordate
groups are descended from it. Subphylum Urochordata (Tunicata) The
Urochordata, (tail-chordates), contains about 2000 species. They are
commonly known as 'sea squirts.' They are found in all seas from near
shore to great depths; most are sessile, although a few species are free
swimming as adults. The older name of 'tunicate' refers to a usually
tough, non-living tunic or test that surrounds the animal and contains
cellulose. The body of an adult tunicate is highly specialised, being
essentially a sack with two siphons through which water enters and
exits. Water is filtered inside the sack-shaped body. However, all
tunicates have a larva that is free-swimming and exhibits all chordate
characteristics. This 'microscopic tadpole larva' will swim for some
time, before (in many tunicates); it eventually attaches to a hard
substrate, metamorphosing by losing its tail, its ability to move, and
its nervous system apart from a single ganglion. A few tunicates are
entirely pelagic (free swimming), known as salps, they typically have
barrel-shaped bodies and may be extremely abundant in the open ocean.
Urochordates have a sparse fossil record. Complete body fossils of
tunicates are rare, but tunicates in some families generate microscopic
spicules that may be preserved as microfossils. Examples of tunicate
spicules have occasionally been described from the Jurassic period.
Urochordata is divided into three classes; Ascidiacea, the most common
and well known, they may be solitary, compound, sharing the same test,
or colonial, Larvacea, which resemble the larval stages of Ascidiacea
and the Thaliacea (pelagic salps). Paedomorphosis and chordate larval
evolution The chordates have taken two paths in their early evolution,
one path leading to the sedentary urochordates, the other to the more
active, mobile cephalochordates and vertebrates discussed below. At the
time of its discovery in 1869, the tadpole larva of tunicates was
thought to be a descendant of an active free-swimming chordate ancestor.
An Englishman, Walter Garstang, proposed in 1928 that the ancestral
chordates were derived by retaining the larval active form of a tunicate
into adulthood, instead of progressing to the normal sessile form.
Evidence presented included the possession of notochord, hollow dorsal
nerve cord, pharyngeal slits, endostyle and post anal tail by the
larvae. Garstang proposed that a process he called paedomorphosis had
occurred, meaning that, at some point, the larvae failed to
metamorphose, but continued to develop gonads, reproducing in the larval
stage. This was a departure from previous ideas suggesting evolution
could occur in the larval stages of a life cycle. Paedomorphosis is
known in other animals, e.g. Axolotl, a salamander that retains its
juvenile gill bearing form throughout life. Modern evidence from
molecular studies provides additional support for this theory, showing
that sessile ascidians represent a derived body form, and that free-
swimming lardaceous are perhaps the most similar to ancestral chordates.
Subphylum Cephalochordata (Amphioxus) Cephalochordates have about 25
living species inhabiting shallow tropical and temperate oceans. Known
as lancelets or as amphioxus (from the Greek for both \[ends\] pointed,
(in reference to their shape), cephalochordates are small, (5cm 7cm
long) eel-like animals that spend much of their time buried in sand.
However, because of their remarkable morphology, they have proved
crucial in understanding the morphology and evolution of the chordates.
Cephalochordates have all the typical chordate features, although they
lack features found in true vertebrates: the brain being very small and
poorly developed, with poorly developed sense organs, and there are no
true vertebrae. Water is taken in through the mouth, drawn in by the
beating of cilia located on the wheel organ, a set of ridges lying
inside the mouth. The oral cirri first filter the water (slender
projections, which surround the opening of the mouth). It then passes
through gill slits enclosed by folds of the body wall, which form a body
cavity (the atrium). Food particles in the water are trapped by mucus,
while water passes through the slits and out of the atrium through the
atriopore, located towards the posterior end. The rest of the digestive
system is fairly simple: a pouch or hepatic caecum secretes digestive
enzymes; actual digestion takes place in a specialised part of the
intestine known as the iliocolonic ring. Cephalochordates have a
well-developed circulatory system and a simple excretory system composed
of paired nephridia. Sexes are separate, with both sexes having multiple
paired gonads. Eggs are fertilised externally, developing into
free-swimming, fish-like larvae. Since cephalochordates have no hard
parts, their fossil record is extremely sparse. However, fossil
cephalochordates have been found predating the origin of the
vertebrates. These fossils show that the chordate lineage appeared very
early in the known history of the animal kingdom, and they strengthened
the case for an origin of true vertebrates from a cephalochordate-like
ancestor. Due to the lack of a defined head, it is thought that
amphioxus resembles the ancestor that developed into the vertebrates,
rather than the vertebrate ancestor itself. According to an article
published in the New Scientist in 2008 amphioxus may be extremely common
in shallow sandy environments: at Discovery Bay, Jamaica, up to 5000
individuals per square metre of sand have been reported. In some parts
of the world, amphioxus is eaten by humans or by domestic animals; they
are important food items in some parts of Asia, where they are
commercially harvested. This example remains a popular one and still
supports current research. Subphylum Vertebrata (Craniata) The third
subphylum of chordates is a large and very diverse group, it shares the
chordate features already mentioned with the other two subphyla but, in
addition, members have a number of novel features. The alternative name
of the group, 'Craniata', refers to the possession of a cranium, a bony
or cartilaginous braincase; all (apart from some jawless fishes) also
have vertebrae. The earliest vertebrates were larger than animals in the
other subphyla, and considerably more active. Increased speed and
mobility were benefits of modifications of the skeleton and muscles. The
greater size and activity levels also required specialised structures
for obtaining and digesting food, and other adaptations designed to
maintain a high metabolic rate. Physiology Vertebrates have
modifications to the respiratory, digestive, circulatory, excretory and
reproductive systems needed to meet their increased metabolic
requirements. The simply modified (for feeding) pharynx in early
chordates is modified in the first larger predatory vertebrates into a
muscular structure that actively pumps water. With the origin of highly
visualised gills, the function changed to primarily being used for
gaseous exchange. Changes to the digestive tract included a change from
movement by ciliary action to muscular action, and the addition of
accessory digestive glands, e.g. liver and pancreas, which were needed
to utilise the higher volume of food needed. A ventral, chambered heart
and erythrocytes (red blood cells) with haemoglobin improved
transportation of nutrients, gases and other substances. Protochordates
have no distinct kidneys, but the vertebrates have paired glomeruli
kidneys that remove metabolic waste products, as well as regulating body
fluids and salts (ions). Muscular-skeletal modifications Vertebrates
possess an endoskeleton formed of cartilage or bone. Growing within the
body, it has the advantage of allowing almost unlimited body size. The
endoskeleton is thought to have initially been formed of cartilage,
which later developed into bone. Cartilage, with its fast growth rate
and flexibility forms the first skeleton of all embryonic vertebrates.
The endoskeleton of living hagfishes, lampreys, sharks (and related
groups) is composed of cartilage, even in some 'bony' fish such as
sturgeon, the skeleton is largely cartilaginous. Bone is thought to have
conferred an adaptive advantage in several ways. The presence of bone in
the skin of ostracoderms and other ancient fishes would have provided
protection from predators. The structural strength of bone is superior
to cartilage, making it ideal for muscle attachment in areas of high
mechanical stress. One interesting idea about the development from
cartilage to bone is the function of mineral regulation. Phosphorus and
calcium are needed for many physiological processes, and are in high
demand in animals with high metabolic rates; bone provides a reservoir
of these important substances. It is surprising to note that many
vertebrates also possess an exoskeleton, although it is highly modified
in many forms. Some of the primate fishes were covered in bony, dermal
armour, which is modified into scales in most advanced forms. Many of
the bones encasing the brain of advanced vertebrates develop from tissue
that originates from the embryonic dermis. The majority of vertebrates
are further protected with keratinised structures derived from the
epidermis, e.g. reptilian scales, hair, feathers, claws, nails and horn.
Nervous and sensory systems When the ancestral vertebrates developed
from filter feeders to active predation, new sensory, motor and
integrative systems were essential for successful food capture. The
anterior end of the nerve cord became enlarged as a tripartite brain
(forebrain, midbrain and hindbrain), which is protected by a
cartilaginous or bony cranium. Paired sense organs, designed for
distance perception evolved, including eyes (with lenses and inverted
retinas) pressure receptors (paired inner ears for equilibrium and audio
reception) chemical reception (taste and olfactory), lateral line
receptors for water vibrations, and chemoreceptors to detect the
electrical currents of prospective prey. Development of the vertebrate's
head and sense organs is largely the result of two unique vertebrate
embryonic innovations, the neural crest and epidermal placodes. The
neural crest is a group of ectodermal cells lying along the length of
the embryonic neural tube, which gives rise to many different
structures, including the cranium, pharyngeal skeleton, teeth dentine,
some cranial nerves and ganglia, Schwann cells, and some endocrine
glands. The epidermal placodes are plate- like ectodermal thickenings
either side of the neural tube, which gives rise to the olfactory,
epithelium, lens of the eye, inner ear, epithelium, some ganglia and
cranial nerves, lateral line mechanoreceptors and electroreceptors,
which induce the formation of taste buds. In summary, all vertebrates
possess the five chordate features plus: endoskeleton (particularly the
cranium and in most a vertebral column), muscular pharynx, muscular
digestive tract, ventral hart with erythrocytes containing haemoglobin,
paired glomeruli kidneys, tripartite brain, paired specialised sense
organs, endocrine system of ductless glands and a well- developed
coelom, divided into a pericardial cavity and a pleuroperitoneal cavity.
Sexes are nearly always separate; gonads have ducts, which either
discharge into a cloaca or an opening near the anus. Most have two pairs
of appendages, supported by limb girdles and an appendicular skeleton.
The earliest vertebrates The earliest known vertebrate fossils (until
recently) were armoured jawless fishes called ostracoderms, from the
late Cambrian and Ordovician deposits. However, in 1999 research
discovered two fishlike vertebrates from the early Cambrian (about 530
million years ago). They possess some features of vertebrates such as a
heart, cranium and fin rays, but there is a lack of evidence for
mineralised tissues, which may explain the extreme rarity of fossils
prior to the late Cambrian. The earliest ostracoderms (termed
herterostracans) were armoured with bone in the dermis, but lacked
paired fins, so important to later groups for stability. Slit mouths may
have enabled them to filter feed (or maybe prey on small animals) whilst
propelling them close to the bottom; movement would have probably been
too imprecise to enable free, pelagic swimming. Without ever-evolving
paired fins or jaws, these animals flourished for 150 million years,
becoming extinct at the end of the Devonian period. Coexisting with the
heterostracans, the osteostracans had the additional advantage of having
paired pectoral fins, and are thought to be similar to modern lampreys.
The anaspids were more streamlined, and existed in many different forms
during the Silurian and Devonian periods. The jawless forms are called
collectively agnathans, (superclass Agnatha) contrasting with all jawed
vertebrates being gnathostomes (superclass Gnathostomata). The origin of
jaws was one of the most important events in vertebrate evolution, as
they allow predation on large and active forms of prey, not available to
jawless vertebrates, and they permit manipulation of objects. Evidence
shows that jaws arose thorough modifications of the first or second of
the serially repeated, cartilaginous gill arches. The mandibular arch
may have first become enlarged to assist in gill ventilation. Later the
anterior gill arches hinged and bent forward into the characteristic
position of the vertebrate jaw. An additional feature of all
gnathostomes is the presence of paired pectoral and pelvic fins or
limbs, although pectoral fins seem to have appeared before pectoral
appendages. These are likely to have originated as stabilisers to
correct yaw, pitch and roll during active swimming. Early vertebrates
such as the anaspids had intermediate 'paired flaps'. Amongst the first
jawed vertebrates were the heavily armoured placoderms, which first
appeared in the early Silurian period. They evolved into a large variety
of forms. They were armoured with diamond shaped scales, or with plates
of bone. All appeared to have become extinct by the end of the Devonian,
and there are no known living descendents. Contemporaries of these
animals were the acanthodians, another group of early-jawed fishes
characterised by fins with large spines. It is thought they gave rise to
modern day bony fishes, which dominate the world's waters today. Part 2:
the fishes In common usage, the word 'fish' applies to many different
aquatic organisms, from cnidarians (jellyfish) and echinoderms
(starfish) to molluscs (shellfish) and crustaceans (crayfish). However,
we will consider 'fish' to mean an aquatic vertebrate with gills, limbs,
and usually a skin covered in dermal scales. The term 'fish' even in
this context is not a taxonomic group but is used for convenience. Fish
are of ancient ancestry, having descended form an unknown free-swimming
protochordate ancestor. Superclass Agnatha Living jawless fishes number
about 106 species divided into two classes, the Myxini (hagfish, 65
species) and Cephalaspidomorphi (lampreys, 41 species) and the extinct
class of Ostracodermi. All these forms are either scavengers or
parasites. Members of living classes lack (as well as jaws) internal
ossification (including no or only rudimentary vertebrae), scales and
paired fins, they have pore-like gill openings and an eel-like body
form. In other respects, the groups are very distinct, with hagfishes
being the more primitive animals; lampreys are closer in form to
gnathostomes than hagfish. Hagfish have no paired appendages, stomachs,
cerebellum and are almost completely blind. Being scavengers and
predators, they are quickly attracted to food by keenly developed senses
of smell and touch. A hagfish enters a dead or dying animal via an
orifice or by digging inside. For extra leverage, it can tie itself in a
knot, pressing the knot against the carcass. They are known for their
copious production of slime, and, if disturbed, they exude a milky
substance, which when mixed with seawater makes the animal so slippery
it is impossible to grasp. Unlike any other vertebrate the body fluids
of a hagfish are in osmotic equilibrium with seawater. As in most marine
invertebrates, they also have three additional accessory hearts in
addition to the main heart positioned behind the gills. Reproduction in
the hagfish is poorly understood, although in some species females
outnumber males 100 to 1. There is no larva stage. Lampreys have one or
two pairs of dorsal fins, but no paired appendages. Their sucker like
mouth is used either to maintain position in a fast flowing current, or
to attach to larger animals to feed. All breed in fresh water, even
those species which normally reside in marine habitats. Adults die soon
after spawning, eggs hatch into small larvae, which resemble the
protochordate Amphioxus. The larvae live as suspension feeders, growing
for 3-7 years. After metamorphosis into the adult form, parasitic forms
live for up to three years feeding on fish body fluids. Non-parasitic
forms do not feed when adults, they metamorphose, then breed and die in
the space of a few months. Superclass Gnathostomata (jawed fishes) Class
Chonrichthyes (cartilaginous fishes) There are nearly 850 living species
in this class. They are an ancient, compact and highly developed group.
This group is smaller and less diverse than bony fishes, but their
impressive array of well-developed sense organs, powerful jaws, swimming
musculature and predatory habits have made them a very successful and
long-lived group. Distinctive features of the class are a cartilaginous
skeleton, although calcification may be extensive, bone is absent. This
is a curious evolutionary feature, as the class is derived from
ancestors who had well-developed bone. All but 28 species are marine
species. With the exception of whales, sharks are the largest living
vertebrates, some reaching 12m in length. All chondrichthyans have
internal fertilisation, but maternal support of the embryo is highly
variable. Many lay large, yolky eggs immediately after fertilisation
(termed oviparous). Some oviparous sharks and rays deposit eggs in a
horny capsule (mermaid's purse), which has tendrils that wrap around the
first firm object it encounters. Embryos are nourished from the yolk for
a long period (average six to nine months, one species up to two years),
before hatching into tiny replicas of adults. Many sharks retain embryos
within their reproductive tract for development. Some are ovoviviparous
(young are retained, but are nourished by a yolk sack until born).
Others are true viviparous species, with the embryo receiving
nourishment from the maternal bloodstream through a placenta, in the
form of nutritive secretions 'uterine milk' produced by the mother.
Tiger shark embryos receive additional nutrition by eating eggs and
siblings. Prolonged retention of embryos in elasmobranches was an
important innovation, contributing to their success; however, there is
no parental care of young. Subclass Elasmobranchii This is a subclass
within the Chondrichthyes (cartilaginous fishes) that includes the
sharks (Euselachii) and the skates and rays (Batoidei). The other
subclass within Chondrichthyes, according to traditional
classifications, is the Holocephali (chimaeras, or ratfish). It is
probable that both groups arose independently, during the Silurian or
Early Devonian, from a group of extinct armoured fishes, the Placodermi.
The elasmobranches are distinguished by separate gill openings, and
sensory electro receptors (ampullae of Lorenzini) in the head region.
Elasmobranchii have the following characteristics: o o o A variably
calcified cartilaginous endoskeleton Placoid scales (tooth-like dermal
structure, which reduces water turbulence when swimming) Urea-retention
mechanism (in order to maintain a similar osmotic pressure with the
environment, which prevents water loss into the concentrated marine
solution, they retain nitrogenous compounds in their extra cellular
fluid, causing the blood salt concentration to be higher than the
surrounding water) o o Clasper organs in the male for internal
fertilisation (the medial part of the pelvic fin in males is specialised
for internal fertilisation) The absence of an air (swim) bladder. Order
Carchardiniformes (ground sharks) are often found in coastal waters, and
range from tiger and bull sharks to the more unusual forms such as
hammerheads. There are over 270 species, which are characterised by the
presence of a nictitating membrane over the eye, two dorsal fins, an
anal fin, and five-gill slits. Order Lamniformes contain several large
pelagic forms dangerous to humans including Great Whites and mako
sharks. The order also contains the extinct Megalodon shark, thought to
have grown as large as 16m (52ft) long, and weighed 48 tons. It is
thought to have preyed on whales. Characteristics of the order include:
two dorsal fins, an anal fin, five gill slits, eyes without nictitating
membrane, and mouth extending behind the eyes. Order Squaliformes
contains dogfish and their relatives; they have two dorsal fins, no anal
fin, no nictitating membrane and five gill slits. Order Rajiformes (also
called Batiodea) is the group of rays (sawfish rays, electric rays,
stingrays, eagle rays and devil rays). Batoids are flat-bodied, and like
other elasmobranches, are species of cartilaginous marine fish. Like all
sharks, they have slot-like body openings (gill slits) that lead from
the gills to the outside environment. Most members of this group are
adapted for bottom dwelling. Gill slits lie under the pectoral fins on
the underside, whereas in other orders, they are on the sides of the
head. Most batoids have a flat, disk-like body, with the exception of
the guitarfish and sawfish, while most sharks have a streamlined body.
Many species of batoid have developed their pectoral fins into broad
flat wing-like appendages. The eyes and spiracles (where water is taken
in by the gills to prevent clogging with the substratum) are located on
top of the head. This group has developed some novel defence mechanisms.
Stingrays have a slender, whip-like tail armed with one or more
saw-edged spines with venom glands at the base. Electric rays are
sluggish fish with large electrical organs on each side of the head.
Each organ is composed of vertical stacks of disc-like cells, connected
in parallel, so that when all cells discharge simultaneously, a high
amperage current is produced that flows into the surrounding water,
causing a useful deterrent to predators, and stunning prey.
Interestingly, electric rays were used by the ancient Egyptians for a
form of electrotherapy in the treatment of ailments such as arthritis
and gout. Subclass Holocephali (Chimaeras) Members of this small
subclass are known as ratfish, rabbit fish, spook fish and ghost fish,
and are remnants of a line that diverged from shark lineage at least 360
million years ago. Fossil examples, dating from the Devonian, were
prolific in the Cretaceous and early Tertiary and have now declined to
the 31 species known today. Chimaeras live in temperate ocean floors and
grow up to two metres long. Like other members of the class,
Chondrichthyes, chimaeras have a skeleton constructed of cartilage.
Their skin is smooth and lacks scales, and their colour ranges from
black to brownish grey. Anatomically, chimaeras have several features in
common with the elasmobranches, but also have several unique
characteristics. Instead of a toothed mouth, jaws bear large flat
plates. The upper jaw is fused to the cranium, a most usual fish
feature. They eat seaweed, molluscs, echinoderms, crustaceans and fish,
an unusually mixed diet for a specialised grinding dentition. For
defence, most chimaeras have a venomous spine located in front of the
dorsal fin.