Chapter 15b Diversity of Animals PDF

Summary

This chapter from an introductory-level textbook covers the diversity of animals. It includes detailed descriptions and anatomical features of various animal phyla, such as mollusks and annelids.

Full Transcript

370 15 Diversity of Animals

FIGURE 15.23 (a) The chelicerae (first set of appendages, circled) are well developed in the Chelicerata, which includes scorpions (a) and
spiders (b). (credit a: modification of work by Kevin Walsh; credit b: modification of work by Marshal Hedin)

LINK TO LEARNING
Click through (http://openstax.org/l/arthropod2) this lesson on arthropods to explore interactive habitat maps and
more.

15.4 Mollusks and Annelids
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the unique anatomical features of mollusks
Describe the features of an animal classified in phylum Annelida

The mollusks are a diverse group (85,000 described species) of mostly marine species. They have a variety of forms,
ranging from large predatory squid and octopus, some of which show a high degree of intelligence, to small grazing
forms with elaborately sculpted and colored shells. The annelids traditionally include the oligochaetes, which
include the earthworms and leeches, the polychaetes, which are a marine group, and two other smaller classes.

The phyla Mollusca and Annelida belong to a clade called the Lophotrochozoa, which also includes the phylum
Nemertea, or ribbon worms (Figure 15.3). They are distinct from the Ecdysozoa (nematodes and arthropods) based
on evidence from analysis of their DNA, which has changed our views of the relationships among invertebrates.

Phylum Mollusca
Mollusca is the predominant phylum in marine environments, where it is estimated that 23 percent of all known
marine species belong to this phylum. It is the second most diverse phylum of animals with over 75,000 described
species. The name “mollusca” signifies a soft body, as the earliest descriptions of mollusks came from observations
of unshelled, soft-bodied cuttlefish (squid relatives). Although mollusk body forms vary, they share key
characteristics, such as a ventral, muscular foot that is typically used for locomotion; the visceral mass, which
contains most of the internal organs of the animal; and a dorsal mantle, which is a flap of tissue over the visceral
mass that creates a space called the mantle cavity. The mantle may or may not secrete a shell of calcium carbonate.
In addition, many mollusks have a scraping structure at the mouth, called a radula (Figure 15.24).

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 15.4 Mollusks and Annelids 371

The muscular foot varies in shape and function, depending on the type of mollusk (described below in the section on
mollusk diversity). It is a retractable as well as extendable organ, used for locomotion and anchorage. Mollusks are
eucoelomates, but the coelomic cavity is restricted to a cavity around the heart in adult animals. The mantle cavity,
formed inside the mantle, develops independently of the coelomic cavity. It is a multi-purpose space, housing the
gills, the anus, organs for sensing food particles in the water, and an outlet for gametes. Most mollusks have an open
circulatory system with a heart that circulates the hemolymph in open spaces around the organs. The octopuses and
squid are an exception to this and have a closed circulatory system with two hearts that move blood through the
gills and a third, systemic heart that pumps blood through the rest of the body.

VISUAL CONNECTION

FIGURE 15.24 There are many species and variations of mollusks; the gastropod mollusk anatomy is shown here, which shares many
characteristics common with other groups.

Which of the following statements about the anatomy of a mollusk is false?

a. Mollusks have a radula for scraping food.
b. Mollusks have ventral nerve cords.
c. The tissue beneath the shell is called the mantle.
d. The mantle cavity contains hemolymph.

Mollusk Diversity
This phylum is comprised of seven classes: Aplacophora, Monoplacophora, Polyplacophora, Bivalvia, Gastropoda,
Cephalopoda, and Scaphopoda.

Class Aplacophora (“bearing no plates”) includes worm-like animals living mostly on deep ocean bottoms. These
animals lack a shell but have aragonite spicules on their skin. Members of class Monoplacophora (“bearing one
plate”) have a single, cap-like shell enclosing the body. The monoplacophorans were believed extinct and only
known as fossils until the discovery of Neopilina galatheae in 1952. Today, scientists have identified nearly two
dozen living species.

Animals in the class Polyplacophora (“bearing many plates”) are commonly known as “chitons” and bear an armor-
like, eight-plated shell (Figure 15.25). These animals have a broad, ventral foot that is adapted for attachment to
rocks and a mantle that extends beyond the shell in the form of a girdle. They breathe with ctenidia (gills) present
ventrally. These animals have a radula modified for scraping. A single pair of nephridia for excretion is present.
372 15 Diversity of Animals

FIGURE 15.25 This chiton from the class Polyplacophora has the eight-plated shell indicative of its class. (credit: Jerry Kirkhart)

Class Bivalvia (“two shells”) includes clams, oysters, mussels, scallops, and geoducks. They are found in marine and
freshwater habitats. As the name suggests, bivalves are enclosed in a pair of shells (or valves) that are hinged at the
dorsal side. The body is flattened on the sides. They feed by filtering particles from water and a radula is absent.
They exchange gases using a pair of ctenidia, and excretion and osmoregulation are carried out by a pair of
nephridia. In some species, the posterior edges of the mantle may fuse to form two siphons that inhale and exhale
water. Some bivalves like oysters and mussels have the unique ability to secrete and deposit a calcareous nacre or
“mother of pearl” around foreign particles that enter the mantle cavity. This property is commercially exploited to
produce pearls.

LINK TO LEARNING
Watch animations of clams (http://openstax.org/l/clams2) and mussels (http://openstax.org/l/mussels2) feeding to
understand more about bivalves.

Gastropods (“stomach foot”) include well-known mollusks like snails, slugs, conchs, sea hares, and sea butterflies.
Gastropods include shell-bearing species as well as species with a reduced shell. These animals are asymmetrical
and usually present a coiled shell (Figure 15.26).

FIGURE 15.26 (a) Like many gastropods, this snail has a stomach foot and a coiled shell. (b) This slug, which is also a gastropod, lacks a
shell. (credit a: modification of work by Murray Stevenson; credit b: modification of work by Rosendahl)

The visceral mass in the shelled species is characteristically twisted and the foot is modified for crawling. Most
gastropods bear a head with tentacles that support eyes. A complex radula is used to scrape food particles from the
substrate. The mantle cavity encloses the ctenidia as well as a pair of nephridia.

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 15.4 Mollusks and Annelids 373

The class Cephalopoda (“head foot” animals) includes octopuses, squids, cuttlefish, and nautilus. Cephalopods
include shelled and reduced-shell groups. They display vivid coloration, typically seen in squids and octopuses,
which is used for camouflage. The ability of some octopuses to rapidly adjust their colors to mimic a background
pattern or to startle a predator is one of the more awe-inspiring feats of these animals. All animals in this class are
predators and have beak-like jaws. All cephalopods have a well-developed nervous system, complex eyes, and a
closed circulatory system. The foot is lobed and developed into tentacles and a funnel, which is used for locomotion.
Suckers are present on the tentacles in octopuses and squid. Ctenidia are enclosed in a large mantle cavity and are
serviced by large blood vessels, each with its own heart.

Cephalopods (Figure 15.27) are able to move quickly via jet propulsion by contracting the mantle cavity to forcefully
eject a stream of water. Cephalopods have separate sexes, and the females of some species care for the eggs for an
extended period of time. Although the shell is much reduced and internal in squid and cuttlefish, and absent
altogether in octopus, nautilus live inside a spiral, multi-chambered shell that is filled with gas or water to regulate
buoyancy.

FIGURE 15.27 The (a) nautilus, (b) giant cuttlefish, (c) reef squid, and (d) blue-ring octopus are all members of the class Cephalopoda.
(credit a: modification of work by J. Baecker; credit b: modification of work by Adrian Mohedano; credit c: modification of work by Silke
Baron; credit d: modification of work by Angell Williams)

Members of the class Scaphopoda (“boat feet”) are known colloquially as “tusk shells” or “tooth shells.” Tooth
shells are open at both ends and usually lie buried in sand with the front opening exposed to water and the reduced
head end projecting from the back of the shell. Tooth shells have a radula and a foot modified into tentacles, each
with a bulbous end that catches and manipulates prey (Figure 15.28).
374 15 Diversity of Animals

FIGURE 15.28 Antalis vulgaris shows the classic Dentaliidae shape that gives these animals their common name of “tusk shell.” (credit:
Georges Jansoone)

Annelida
Phylum Annelida are segmented worms found in marine, terrestrial, and freshwater habitats, but the presence of
water or humidity is a critical factor for their survival in terrestrial habitats. The name of the phylum is derived from
the Latin word annellus, which means a small ring. Approximately 16,500 species have been described. The phylum
includes earthworms, polychaete worms, and leeches. Like mollusks, annelids exhibit protostomic development.

Annelids are bilaterally symmetrical and have a worm-like appearance. Their particular segmented body plan results
in repetition of internal and external features in each body segment. This type of body plan is called metamerism.
The evolutionary benefit of such a body plan is thought to be the capacity it allows for the evolution of independent
modifications in different segments that perform different functions. The overall body can then be divided into head,
body, and tail.

Physiological Processes of Annelida
The skin of annelids is protected by a cuticle that is thinner than the cuticle of the ecdysozoans and does not need to
be molted for growth. Chitinous hairlike extensions, anchored in the skin and projecting from the cuticle, called
chaetae, are present in every segment in most groups. The chaetae are a defining character of annelids. Polychaete
worms have paired, unjointed limbs called parapodia on each segment used for locomotion and breathing. Beneath
the cuticle there are two layers of muscle, one running around its circumference (circular) and one running the
length of the worm (longitudinal). Annelids have a true coelom in which organs are distributed and bathed in
coelomic fluid. Annelids possess a well-developed complete digestive system with specialized organs: mouth,
muscular pharynx, esophagus, and crop. A cross-sectional view of a body segment of an earthworm is shown in
Figure 15.29; each segment is limited by a membrane that divides the body cavity into compartments.

Annelids have a closed circulatory system with muscular pumping “hearts” in the anterior segments, dorsal and
ventral blood vessels that run the length of the body with connections in each segment, and capillaries that service
individual tissues. Gas exchange occurs across the moist body surface. Excretion is carried out by pairs of primitive
“kidneys” called metanephridia that consist of a convoluted tubule and an open, ciliated funnel present in every
segment. Annelids have a well-developed nervous system with two ventral nerve cords and a nerve ring of fused
ganglia present around the pharynx.

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 15.4 Mollusks and Annelids 375

FIGURE 15.29 In this schematic showing the basic anatomy of annelids, the digestive system is indicated in green, the nervous system is
indicated in yellow, and the circulatory system is indicated in red.

Annelids may be either monoecious with permanent gonads (as in earthworms and leeches) or dioecious with
temporary or seasonal gonads (as in polychaetes).

LINK TO LEARNING
This video and animation (http://openstax.org/l/annelid2) provides a close-up look at annelid anatomy.

Annelid Diversity
Phylum Annelida includes the classes Polychaeta and Clitellata (Figure 15.30); the latter contains subclasses
Oligochaeta, Hirudinoidea, and Branchiobdellida.

Earthworms are the most abundant members of the subclass Oligochaeta, distinguished by the presence of the
clitellum, a ring structure in the skin that secretes mucus to bind mating individuals and forms a protective cocoon
for the eggs. They also have a few, reduced chaetae (oligo- = “few”; -chaetae = “hairs”). The number and size of
chaetae is greatly diminished in oligochaetes as compared to the polychaetes (poly- = “many”; -chaetae = “hairs”).
The chaetae of polychaetes are also arranged within fleshy, flat, paired appendages on each segment called
parapodia.

The subclass Hirudinoidea includes leeches. Significant differences between leeches and other annelids include the
development of suckers at the anterior and posterior ends, and the absence of chaetae. Additionally, the
segmentation of the body wall may not correspond to internal segmentation of the coelomic cavity. This adaptation
may allow leeches to swell when ingesting blood from host vertebrates. The subclass Branchiobdellida includes
about 150 species that show similarity to leeches as well as oligochaetes. All species are obligate symbionts,
meaning that they can only survive associated with their host, mainly with freshwater crayfish. They feed on the
algae that grows on the carapace of the crayfish.
376 15 Diversity of Animals

FIGURE 15.30 The (a) earthworm and (b) leech are both annelids. (credit a: modification of work by "schizoform"/Flickr; credit b:
modification of work by "Sarah G..."/Flickr)

15.5 Echinoderms and Chordates
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the distinguishing characteristics of echinoderms
Describe the distinguishing characteristics of chordates

Deuterostomes include the phyla Echinodermata and Chordata (which includes the vertebrates) and two smaller
phyla. Deuterostomes share similar patterns of early development.

Echinoderms
Echinodermata are named for their spiny skin (from the Greek “echinos” meaning “spiny” and “dermos” meaning
5
“skin”). The phylum includes about 7,000 described living species, such as sea stars, sea cucumbers, sea urchins,
sand dollars, and brittle stars. Echinodermata are exclusively marine.

Adult echinoderms exhibit pentaradial symmetry and have a calcareous endoskeleton made of ossicles (Figure
15.31), although the early larval stages of all echinoderms have bilateral symmetry. The endoskeleton is developed
by epidermal cells, which may also possess pigment cells, giving vivid colors to these animals, as well as cells laden
with toxins. These animals have a true coelom, a portion of which is modified into a unique circulatory system called
a water vascular system. An interesting feature of these animals is their power to regenerate, even when over 75
percent of their body mass is lost.

Physiological Processes of Echinoderms
Echinoderms have a unique system for gas exchange, nutrient circulation, and locomotion called the water vascular
system. The system consists of a central ring canal and radial canals extending along each arm. Water circulates
through these structures allowing for gas, nutrient, and waste exchange. A structure on top of the body, called the
madreporite, regulates the amount of water in the water vascular system. “Tube feet,” which protrude through
openings in the endoskeleton, may be expanded or contracted using the hydrostatic pressure in the system. The
system allows for slow movement, but a great deal of power, as witnessed when the tube feet latch on to opposite
halves of a bivalve mollusk, like a clam, and slowly, but surely pull the shells apart, exposing the flesh within.

5 “Number of Living Species in Australia and the World,” A.D. Chapman, Australia Biodiversity Information Services, last modified August
26, 2010, http://www.environment.gov.au/biodiversity/abrs/publications/other/species-numbers/2009/03-exec-summary.html.

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 15.5 Echinoderms and Chordates 377

FIGURE 15.31 This diagram shows the anatomy of a sea star.

The echinoderm nervous system has a nerve ring at the center and five radial nerves extending outward along the
arms. There is no centralized nervous control. Echinoderms have separate sexes and release their gametes into the
water where fertilization takes place. Echinoderms may also reproduce asexually through regeneration from body
parts.

Echinoderm Diversity
This phylum is divided into five classes: Asteroidea (sea stars), Ophiuroidea (brittle stars), Echinoidea (sea urchins
and sand dollars), Crinoidea (sea lilies or feather stars), and Holothuroidea (sea cucumbers) (Figure 15.32).

Perhaps the best-known echinoderms are members of the class Asteroidea, or sea stars. They come in a large
variety of shapes, colors, and sizes, with more than 1,800 species known. The characteristics of sea stars that set
them apart from other echinoderm classes include thick arms that extend from a central disk where organs
penetrate into the arms. Sea stars use their tube feet not only for gripping surfaces but also for grasping prey. Sea
stars have two stomachs, one of which they can evert through their mouths to secrete digestive juices into or onto
prey before ingestion. This process can essentially liquefy the prey and make digestion easier.

LINK TO LEARNING
View this video (http://openstax.org/l/echinoderm2) to explore a sea star’s body plan up close, watch one move
across the sea floor, and see it devour a mussel.

Brittle stars have long, thin arms that do not contain any organs. Sea urchins and sand dollars do not have arms but
are hemispherical or flattened with five rows of tube feet, which help them in slow movement. Sea lilies and feather
stars are stalked suspension feeders. Sea cucumbers are soft-bodied and elongate with five rows of tube feet and a
series of tube feet around the mouth that are modified into tentacles used in feeding.
378 15 Diversity of Animals

FIGURE 15.32 Different members of Echinodermata include the (a) sea star in class Asteroidea, (b) the brittle star in class Ophiuroidea, (c)
the sea urchins of class Echinoidea, (d) the sea lilies belonging to class Crinoidea, and (e) sea cucumbers representing class Holothuroidea.
(credit a: modification of work by Adrian Pingstone; credit b: modification of work by Joshua Ganderson; credit c: modification of work by
Samuel Chow; credit d: modification of work by Sarah Depper; credit e: modification of work by Ed Bierman)

Chordates
The majority of species in the phylum Chordata are found in the subphylum Vertebrata, which include many species
with which we are familiar. The vertebrates contain more than 60,000 described species, divided into major
groupings of the lampreys, fishes, amphibians, reptiles, birds, and mammals.

Animals in the phylum Chordata share four key features that appear at some stage of their development: a
notochord, a dorsal hollow nerve cord, pharyngeal slits, and a post-anal tail (Figure 15.33). In certain groups, some
of these traits are present only during embryonic development.

The chordates are named for the notochord, which is a flexible, rod-shaped structure that is found in the embryonic
stage of all chordates and in the adult stage of some chordate species. It is located between the digestive tube and
the nerve cord, and provides skeletal support through the length of the body. In some chordates, the notochord acts
as the primary axial support of the body throughout the animal’s lifetime. In vertebrates, the notochord is present
during embryonic development, at which time it induces the development of the neural tube and serves as a support
for the developing embryonic body. The notochord, however, is not found in the postnatal stage of vertebrates; at
this point, it has been replaced by the vertebral column (the spine).

The dorsal hollow nerve cord is derived from ectoderm that sinks below the surface of the skin and rolls into a
hollow tube during development. In chordates, it is located dorsally to the notochord. In contrast, other animal
phyla possess solid nerve cords that are located either ventrally or laterally. The nerve cord found in most chordate
embryos develops into the brain and spinal cord, which compose the central nervous system.

Pharyngeal slits are openings in the pharynx, the region just posterior to the mouth, that extend to the outside
environment. In organisms that live in aquatic environments, pharyngeal slits allow for the exit of water that enters
the mouth during feeding. Some invertebrate chordates use the pharyngeal slits to filter food from the water that
enters the mouth. In fishes, the pharyngeal slits are modified into gill supports, and in jawed fishes, jaw supports. In
tetrapods, the slits are further modified into components of the ear and tonsils, since there is no longer any need for
gill supports in these air-breathing animals. Tetrapod means “four-footed,” and this group includes amphibians,
reptiles, birds, and mammals. (Birds are considered tetrapods because they evolved from tetrapod ancestors.)

The post-anal tail is a posterior elongation of the body extending beyond the anus. The tail contains skeletal

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 15.5 Echinoderms and Chordates 379

elements and muscles, which provide a source of locomotion in aquatic species, such as fishes. In some terrestrial
vertebrates, the tail may also function in balance, locomotion, courting, and signaling when danger is near. In many
species, the tail is absent or reduced; for example, in apes, including humans, it is present in the embryo, but
reduced in size and nonfunctional in adults.

VISUAL CONNECTION

FIGURE 15.33 In chordates, four common features appear at some point in development: a notochord, a dorsal hollow nerve cord,
pharyngeal slits, and a post-anal tail. The anatomy of a cephalochordate shown here illustrates all of these features.

Which of the following statements about common features of chordates is true?

a. The dorsal hollow nerve cord is part of the chordate central nervous system.
b. In vertebrate fishes, the pharyngeal slits become the gills.
c. Humans are not chordates because humans do not have a tail.
d. Vertebrates do not have a notochord at any point in their development; instead, they have a vertebral column.

Invertebrate Chordates
In addition to the vertebrates, the phylum Chordata contains two clades of invertebrates: Urochordata (tunicates)
and Cephalochordata (lancelets). Members of these groups possess the four distinctive features of chordates at
some point during their development.

The tunicates (Figure 15.34) are also called sea squirts. The name tunicate derives from the cellulose-like
carbohydrate material, called the tunic, which covers the outer body. Although tunicates are classified as chordates,
the adult forms are much modified in body plan and do not have a notochord, a dorsal hollow nerve cord, or a post-
anal tail, although they do have pharyngeal slits. The larval form possesses all four structures. Most tunicates are
hermaphrodites. Tunicate larvae hatch from eggs inside the adult tunicate’s body. After hatching, a tunicate larva
swims for a few days until it finds a suitable surface on which it can attach, usually in a dark or shaded location. It
then attaches by the head to the substrate and undergoes metamorphosis into the adult form, at which point the
notochord, nerve cord, and tail disappear.

FIGURE 15.34 (a) This photograph shows a colony of the tunicate Botrylloides violaceus. In the (b) larval stage, the tunicate can swim
freely until it attaches to a substrate to become (c) an adult. (credit a: modification of work by Dr. Dwayne Meadows, NOAA/NMFS/OPR)
380 15 Diversity of Animals

Most tunicates live a sessile existence in shallow ocean waters and are suspension feeders. The primary foods of
tunicates are plankton and detritus. Seawater enters the tunicate’s body through its incurrent siphon. Suspended
material is filtered out of this water by a mucus net (pharyngeal slits) and is passed into the intestine through the
action of cilia. The anus empties into the excurrent siphon, which expels wastes and water.

Lancelets possess a notochord, dorsal hollow nerve cord, pharyngeal slits, and a post-anal tail in the adult stage
(Figure 15.35). The notochord extends into the head, which gives the subphylum its name (Cephalochordata).
Extinct fossils of this subphylum date to the middle of the Cambrian period (540–488 mya).The living forms, the
lancelets, are named for their blade-like shape. Lancelets are only a few centimeters long and are usually found
buried in sand at the bottom of warm temperate and tropical seas. Like tunicates, they are suspension feeders.

FIGURE 15.35 Adult lancelets retain the four key features of chordates: a notochord, a dorsal hollow nerve cord, pharyngeal slits, and a
post-anal tail.

15.6 Vertebrates
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the difference between jawless and jawed fishes
Explain the main characteristics of amphibians, reptiles, and birds
Describe the derived characteristics in birds that facilitate flight
Name and describe the distinguishing features of the three main groups of mammals
Describe the derived features that distinguish primates from other animals

Vertebrates are among the most recognizable organisms of the animal kingdom (Figure 15.36). More than 62,000
vertebrate species have been identified. The vertebrate species now living represent only a small portion of the
vertebrates that have existed. The best-known extinct vertebrates are the dinosaurs, a unique group of reptiles,
reaching sizes not seen before or since in terrestrial animals. They were the dominant terrestrial animals for 150
million years, until they died out near the end of the Cretaceous period in a mass extinction. A great deal is known
about the anatomy of the dinosaurs, given the preservation of their skeletal elements in the fossil record.

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 15.6 Vertebrates 381

FIGURE 15.36 Examples of critically endangered vertebrate species include (a) the Siberian tiger (Panthera tigris altaica), (b) the
Panamanian golden frog (Atelopus zeteki), and (c) the Philippine eagle (Pithecophaga jefferyi). (credit a: modification of work by Dave Pape;
credit b: modification of work by Brian Gratwicke; credit c: modification of work by "cuatrok77"/Flickr)

Fishes
Modern fishes include an estimated 31,000 species. Fishes were the earliest vertebrates, and jawless fishes were
the earliest of these. Jawless fishes—the present day hagfishes and lampreys—have a distinct cranium and complex
sense organs including eyes, distinguishing them from the invertebrate chordates. The jawed fishes evolved later
and are extraordinarily diverse today. Fishes are active feeders, rather than sessile, suspension feeders.

Jawless Fishes
Jawless fishes are craniates (which includes all the chordate groups except the tunicates and lancelets) that
represent an ancient vertebrate lineage that arose over one half-billion years ago. Some of the earliest jawless
fishes were the ostracoderms (which translates as “shell-skin”). Ostracoderms, now extinct, were vertebrate fishes
encased in bony armor, unlike present-day jawless fishes, which lack bone in their scales.

The clade Myxini includes 67 species of hagfishes. Hagfishes are eel-like scavengers that live on the ocean floor
and feed on dead invertebrates, other fishes, and marine mammals (Figure 15.37a). Hagfishes are entirely marine
and are found in oceans around the world except for the polar regions. A unique feature of these animals is the slime
glands beneath the skin that are able to release an extraordinary amount of mucus through surface pores. This
mucus may allow the hagfish to escape from the grip of predators. Hagfish are known to enter the bodies of dead or
dying organisms to devour them from the inside.

FIGURE 15.37 (a) Pacific hagfishes are scavengers that live on the ocean floor. (b) These parasitic sea lampreys attach to their lake trout
host by suction and use their rough tongues to rasp away flesh in order to feed on the trout’s blood. (credit a: modification of work by Linda
Snook, NOAA/CBNMS; credit b: modification of work by USGS)

The skeleton of a hagfish is composed of cartilage, which includes a cartilaginous notochord, which runs the length
of the body, and a skull. This notochord provides support to the fish’s body. Although they are craniates, hagfishes
are not vertebrates, since they do not replace the notochord with a vertebral column during development, as do the
vertebrates.

The clade Petromyzontidae includes approximately 40 species of lampreys. Lampreys are similar to hagfishes in
size and shape; however, lampreys have a brain case and incomplete vertebrae. Lampreys lack paired appendages
382 15 Diversity of Animals

and bone, as do the hagfishes. As adults, lampreys are characterized by a toothed, funnel-like sucking mouth. Some
species are parasitic as adults, attaching to and feeding on the body fluids of fish (Figure 15.37b). Most species are
free-living.

Lampreys live primarily in coastal and fresh waters and have a worldwide temperate region distribution. All species
spawn in fresh waters. Eggs are fertilized externally, and the larvae are distinctly different from the adult form,
spending 3 to 15 years as suspension feeders. Once they attain sexual maturity, the adults reproduce and die within
days. Lampreys have a notochord as adults.

Jawed Fishes
Gnathostomes or “jaw-mouths” are vertebrates that have jaws and include both cartilaginous and bony fishes. One
of the most significant developments in early vertebrate evolution was the origin of the jaw, which is a hinged
structure attached to the cranium that allows an animal to grasp and tear its food. The evolution of jaws allowed
early gnathostomes to exploit food resources that were unavailable to jawless fishes.

The clade Chondrichthyes, the cartilaginous fishes, is diverse, consisting of sharks (Figure 15.38a), rays, and
skates, together with sawfishes and a few dozen species of fishes called chimaeras, or ghost sharks. Chondrichthyes
have paired fins and a skeleton made of cartilage. This clade arose approximately 370 million years ago in the
middle Devonian. They are thought to have descended from an extinct group that had a skeleton made of bone;
thus, the cartilaginous skeleton of Chondrichthyes is a later development. Parts of the shark skeleton are
strengthened by granules of calcium carbonate, but this is not the same as bone.

Most cartilaginous fishes live in marine habitats, with a few species living in fresh water for some or all of their lives.
Most sharks are carnivores that feed on live prey, either swallowing it whole or using their jaws and teeth to tear it
into smaller pieces. Shark teeth likely evolved from the jagged scales that cover their skin. Some species of sharks
and rays are suspension feeders that feed on plankton.

FIGURE 15.38 (a) This hammerhead shark is an example of a predatory cartilaginous fish. (b) This stingray blends into the sandy bottom of
the ocean floor when it is feeding or awaiting prey. (credit a: modification of work by Masashi Sugawara; credit b: modification of work by
"Sailn1"/Flickr)

Sharks have well-developed sense organs that aid them in locating prey, including a keen sense of smell and
electroreception, the latter being perhaps the most sensitive of any animal. Organs called ampullae of Lorenzini
allow sharks to detect the electromagnetic fields that are produced by all living things, including their prey.
Electroreception has only been observed in aquatic or amphibious animals. Sharks, together with most fishes, also
have a sense organ called the lateral line, which is used to detect movement and vibration in the surrounding water,
and a sense that is often considered homologous to “hearing” in terrestrial vertebrates. The lateral line is visible as
a darker stripe that runs along the length of the fish’s body.

Sharks reproduce sexually and eggs are fertilized internally. Most species are ovoviviparous, that is, the fertilized
egg is retained in the oviduct of the mother’s body, and the embryo is nourished by the egg yolk. The eggs hatch in
the uterus and young are born alive and fully functional. Some species of sharks are oviparous: They lay eggs that
hatch outside of the mother’s body. Embryos are protected by a shark egg case or “mermaid’s purse” that has the
consistency of leather. The shark egg case has tentacles that snag in seaweed and give the newborn shark cover. A
few species of sharks are viviparous, that is, the young develop within the mother’s body, and she gives live birth.

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 15.6 Vertebrates 383

Rays and skates include more than 500 species and are closely related to sharks. They can be distinguished from
sharks by their flattened bodies, pectoral fins that are enlarged and fused to the head, and gill slits on their ventral
surface (Figure 15.38b). Like sharks, rays and skates have a cartilaginous skeleton. Most species are marine and live
on the sea floor, with nearly a worldwide distribution.

Bony Fishes
Members of the clade Osteichthyes, or bony fishes, are characterized by a bony skeleton. The vast majority of
present-day fishes belong to this group, which consists of approximately 30,000 species, making it the largest class
of vertebrates in existence today.

Nearly all bony fishes have an ossified skeleton with specialized bone cells (osteocytes) that produce and maintain a
calcium phosphate matrix. This characteristic has only reverted in a few groups of Osteichthyes, such as sturgeons
and paddlefish, which have primarily cartilaginous skeletons. The skin of bony fishes is often covered in overlapping
scales, and glands in the skin secrete mucus that reduces drag when swimming and aids the fish in osmoregulation.
Like sharks, bony fishes have a lateral line system that detects vibrations in water. Unlike sharks, some bony fish
depend on their eyesight to locate prey. Bony fish are also unusual in possessing taste cells in the head and trunk
region of the body that allow them to detect extremely small concentrations of molecules in the water.

All bony fishes, like the cartilaginous fishes, use gills to breathe. Water is drawn over gills that are located in
chambers covered and ventilated by a protective, muscular flap called the operculum. Unlike sharks, bony fishes
have a swim bladder, a gas-filled organ that helps to control the buoyancy of the fish. Bony fishes are further
divided into two clades with living members: Actinopterygii (ray-finned fishes) and Sarcopterygii (lobe-finned
fishes).

The ray-finned fishes include many familiar fishes—tuna, bass, trout, and salmon (Figure 15.39a), among others.
Ray-finned fishes are named for the form of their fins—webs of skin supported by bony spines called rays. In
contrast, the fins of lobe-finned fishes are fleshy and supported by bone (Figure 15.39b). Living members of lobe-
finned fishes include the less familiar lungfishes and coelacanth.

FIGURE 15.39 The (a) sockeye salmon and (b) coelacanth are both bony fishes of the Osteichthyes clade. The coelacanth, sometimes
called a lobe-finned fish, was thought to have gone extinct in the Late Cretaceous period 100 million years ago until one was discovered in
1938 between Africa and Madagascar. (credit a: modification of work by Timothy Knepp, USFWS; credit b: modification of work by Robbie
Cada)

Amphibians
Amphibians are vertebrate tetrapods. Amphibia includes frogs, salamanders, and caecilians. The term amphibian
means “dual life,” which is a reference to the metamorphosis that many frogs undergo from a tadpole to an adult
and the mixture of aquatic and terrestrial environments in their life cycle. Amphibians evolved in the Devonian
period and were the earliest terrestrial tetrapods.

As tetrapods, most amphibians are characterized by four well-developed limbs, although some species of
salamanders and all caecilians possess only vestigial limbs. An important characteristic of extant amphibians is a
moist, permeable skin, achieved by mucus glands. The moist skin allows oxygen and carbon dioxide exchange with
the environment, a process called cutaneous respiration. All living adult amphibian species are carnivorous, and
some terrestrial amphibians have a sticky tongue that is used to capture prey.

Amphibian Diversity
Amphibia comprise an estimated 6,500 extant species that inhabit tropical and temperate regions around the world.
Amphibians can be divided into three clades: Urodela (“tailed-ones”), the salamanders and newts; Anura (“tail-less
ones”), the frogs and toads; and Apoda (“legless ones”), the caecilians.

Living salamanders (Figure 15.40a) include approximately 500 species, some of which are aquatic, others
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terrestrial, and some that live on land only as adults. Adult salamanders usually have a generalized tetrapod body
plan with four limbs and a tail. Some salamanders are lungless, and respiration occurs through the skin or external
gills. Some terrestrial salamanders have primitive lungs; a few species have both gills and lungs.

FIGURE 15.40 (a) Most salamanders have legs and a tail, but respiration varies among species. (b) The Australian green tree frog is a
nocturnal predator that lives in the canopies of trees near a water source. (credit a: modification of work by Valentina Storti; credit b:
modification of work by Evan Pickett)

LINK TO LEARNING
Watch this video (https://www.youtube.com/watch?v=P_kyeHZjRJ4) about an unusually large salamander species.

Frogs (Figure 15.40b) are the most diverse group of amphibians, with approximately 5,000 species that live on all
continents except Antarctica. Frogs have a body plan that is more specialized than the salamander body plan for
movement on land. Adult frogs use their hind limbs to jump many times their body length on land. Frogs have a
number of modifications that allow them to avoid predators, including skin that acts as camouflage and defensive
chemicals that are poisonous to predators secreted from glands in the skin.

Frog eggs are fertilized externally, as they are laid in moist environments. Frogs demonstrate a range of parental
behaviors, with some species exhibiting little care, to species that carry eggs and tadpoles on their hind legs or
backs. The life cycle consists of two stages: the larval stage followed by metamorphosis to an adult stage. The larval
stage of a frog, the tadpole, is often a filter-feeding herbivore. Tadpoles usually have gills, a lateral line system, long-
finned tails, but no limbs. At the end of the tadpole stage, frogs undergo a gradual metamorphosis into the adult
form. During this stage, the gills and lateral line system disappear, and four limbs develop. The jaws become larger
and are suited for carnivorous feeding, and the digestive system transforms into the typical short gut of a predator.
An eardrum and air-breathing lungs also develop. These changes during metamorphosis allow the larvae to move
onto land in the adult stage (Figure 15.41).

FIGURE 15.41 A frog begins as a (a) tadpole and undergoes metamorphosis to become (b) a juvenile and finally (c) an adult. (credit:
modification of work by Brian Gratwicke)

Caecilians comprise an estimated 185 species. They lack external limbs and resemble giant earthworms. They
inhabit soil and are found primarily in the tropics of South America, Africa, and southern Asia where they are
adapted for a soil-burrowing lifestyle and are nearly blind. Unlike most of the other amphibians that breed in or near
water, reproduction in a drier soil habitat means that caecilians must utilize internal fertilization, and most species
give birth to live young (Figure 15.42).

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 15.6 Vertebrates 385

FIGURE 15.42 Caecilians lack external limbs and are well adapted for a soil-burrowing lifestyle. (credit: modification of work by
"cliff1066"/Flickr)

Reptiles and Birds
The amniotes—reptiles, birds, and mammals—are distinguished from amphibians by their terrestrially adapted
(shelled) egg and an embryo protected by amniotic membranes. The evolution of amniotic membranes meant that
the embryos of amniotes could develop within an aquatic environment inside the egg. This led to less dependence
on a water environment for development and allowed the amniotes to invade drier areas. This was a significant
evolutionary change that distinguished them from amphibians, which were restricted to moist environments due to
their shell-less eggs. Although the shells of various amniotic species vary significantly, they all allow retention of
water. The membranes of the amniotic egg also allowed gas exchange and sequestering of wastes within the
enclosure of an eggshell. The shells of bird eggs are composed of calcium carbonate and are hard and brittle, but
possess pores for gas and water exchange. The shells of reptile eggs are more leathery and pliable. Most mammals
do not lay eggs; however, even with internal gestation, amniotic membranes are still present.

In the past, the most common division of amniotes has been into classes Mammalia, Reptilia, and Aves. Birds are
descended, however, from dinosaurs, so this classical scheme results in groups that are not true clades. We will
discuss birds as a group distinct from reptiles with the understanding that this does not reflect evolutionary history.

Reptiles
Reptiles are tetrapods. Limbless reptiles—snakes—may have vestigial limbs and, like caecilians, are classified as
tetrapods because they are descended from four-limbed ancestors. Reptiles lay shelled eggs on land. Even aquatic
reptiles, like sea turtles, return to the land to lay eggs. They usually reproduce sexually with internal fertilization.
Some species display ovoviviparity, with the eggs remaining in the mother’s body until they are ready to hatch. Other
species are viviparous, with the offspring born alive.

One of the key adaptations that permitted reptiles to live on land was the development of their scaly skin, containing
the protein keratin and waxy lipids, which prevented water loss from the skin. This occlusive skin means that
reptiles cannot use their skin for respiration, like amphibians, and thus all must breathe with lungs. In addition,
reptiles conserve valuable body water by excreting nitrogen in the form of uric acid paste. These characteristics,
along with the shelled, amniotic egg, were the major reasons why reptiles became so successful in colonizing a
variety of terrestrial habitats far from water.

Reptiles are ectotherms, that is, animals whose main source of body heat comes from the environment. Behavioral
maneuvers, like basking to heat themselves, or seeking shade or burrows to cool off, help them regulate their body
temperature,

Class Reptilia includes diverse species classified into four living clades. These are the Crocodilia, Sphenodontia,
Squamata, and Testudines.

The Crocodilia (“small lizard”) arose approximately 84 million years ago, and living species include alligators,
crocodiles, and caimans. Crocodilians (Figure 15.43a) live throughout the tropics of Africa, South America, the
southeastern United States, Asia, and Australia. They are found in freshwater habitats, such as rivers and lakes, and
spend most of their time in water. Some species are able to move on land due to their semi-erect posture.
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FIGURE 15.43 (a) Crocodilians, such as this Siamese crocodile, provide parental care for their offspring. (b) This Jackson’s chameleon
blends in with its surroundings. (c) The garter snake belongs to the genus Thamnophis, the most widely distributed reptile genus in North
America. (d) The African spurred tortoise lives at the southern edge of the Sahara Desert. It is the third largest tortoise in the world. (credit
a: modification of work by Keshav Mukund Kandhadai; credit c: modification of work by Steve Jurvetson; credit d: modification of work by
Jim Bowen)

The Sphenodontia (“wedge tooth”) arose in the Mesozoic Era and includes only one living genus, Tuatara, with two
species that are found in New Zealand. There are many fossil species extending back to the Triassic period
(250–200 million years ago). Although the tuataras resemble lizards, they are anatomically distinct and share
characteristics that are found in birds and turtles.

Squamata (“scaly”) arose in the late Permian; living species include lizards and snakes, which are the largest extant
clade of reptiles (Figure 15.43b). Lizards differ from snakes by having four limbs, eyelids, and external ears, which
are lacking in snakes. Lizard species range in size from chameleons and geckos that are a few centimeters in length
to the Komodo dragon, which is about 3 meters in length.

Snakes are thought to have descended from either burrowing lizards or aquatic lizards over 100 million years ago
(Figure 15.43c). Snakes comprise about 3,000 species and are found on every continent except Antarctica. They
range in size from 10 centimeter-long thread snakes to 7.5 meter-long pythons and anacondas. All snakes are
carnivorous and eat small animals, birds, eggs, fish, and insects.

Turtles are members of the clade Testudines (“having a shell”) (Figure 15.43d). Turtles are characterized by a bony
or cartilaginous shell, made up of the carapace on the back and the plastron on the ventral surface, which develops
from the ribs. Turtles arose approximately 200 million years ago, predating crocodiles, lizards, and snakes. Turtles
lay eggs on land, although many species live in or near water. Turtles range in size from the speckled padloper
tortoise at 8 centimeters (3.1 inches) to the leatherback sea turtle at 200 centimeters (over 6 feet). The term
“turtle” is sometimes used to describe only those species of Testudines that live in the sea, with the terms
“tortoise” and “terrapin” used to refer to species that live on land and in fresh water, respectively.

Birds
Data now suggest that birds belong within the reptile clade, but they display a number of unique adaptations that
set them apart. Unlike the reptiles, birds are endothermic, meaning they generate their own body heat through

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 15.6 Vertebrates 387

metabolic processes. The most distinctive characteristic of birds is their feathers, which are modified reptilian
scales. Birds have several different types of feathers that are specialized for specific functions, like contour feathers
that streamline the bird’s exterior and loosely structured down feathers that insulate (Figure 15.44a).

Feathers not only permitted the earliest birds to glide, and ultimately engage in flapping flight, but they insulated the
bird’s body, assisting the maintenance of endothermy, even in cooler temperatures. Powering a flying animal
requires economizing on the amount of weight carried. As body weight increases, the muscle output and energetic
cost required for flying increase. Birds have made several modifications to reduce body weight, including hollow or
pneumatic bones (Figure 15.44b) with air spaces that may be connected to air sacs and cross-linked struts within
their bones to provide structural reinforcement. Parts of the vertebral skeleton and braincase are fused to increase
its strength while lightening its weight. Most species of bird only possess one ovary rather than two, and no living
birds have teeth in their jaw, further reducing body mass.

FIGURE 15.44 (a) Primary feathers are located at the wing tip and provide thrust; secondary feathers are located close to the body and
provide lift. (b) Many birds have hollow pneumatic bones, which make flight easier.

Birds possess a system of air sacs branching from their primary airway that divert the path of air so that it passes
unidirectionally through the lung, during both inspiration and expiration. Unlike mammalian lungs in which air flows
in two directions as it is breathed in and out, air flows continuously through the bird’s lung to provide a more
efficient system of gas exchange.

Mammals
Mammals are vertebrates that have hair and mammary glands used to provide nutrition for their young. Certain
features of the jaw, skeleton, skin, and internal anatomy are also unique to mammals. The presence of hair is one of
the key characteristics of a mammal. Although it is not very extensive in some groups, such as whales, hair has
many important functions for mammals. Mammals are endothermic, and hair provides insulation by trapping a layer
of air close to the body to retain metabolic heat. Hair also serves as a sensory mechanism through specialized hairs
called vibrissae, better known as whiskers. These attach to nerves that transmit touch information, which is
particularly useful to nocturnal or burrowing mammals. Hair can also provide protective coloration.

Mammalian skin includes secretory glands with various functions. Sebaceous glands produce a lipid mixture called
sebum that is secreted onto the hair and skin for water resistance and lubrication. Sebaceous glands are located
over most of the body. Sudoriferous glands produce sweat and scent, which function in thermoregulation and
communication, respectively. Mammary glands produce milk that is used to feed newborns. While male and female
monotremes and eutherians possess mammary glands, some male marsupials do not.

The skeletal system of mammals possesses unique features that differentiate them from other vertebrates. Most
mammals have heterodont teeth, meaning they have different types and shapes of teeth that allow them to feed on
388 15 Diversity of Animals

different kinds of foods. These different types of teeth include the incisors, the canines, premolars, and molars. The
first two types are for cutting and tearing, whereas the latter two types are for crushing and grinding. Different
groups have different proportions of each type, depending on their diet. Most mammals are also diphyodonts,
meaning they have two sets of teeth in their lifetime: deciduous or “baby” teeth, and permanent teeth. In other
vertebrates, the teeth can be replaced throughout life.

Modern mammals are divided into three broad groups: monotremes, marsupials, and eutherians (or placental
mammals). The eutherians, or placental mammals, and the marsupials collectively are called therian mammals,
whereas monotremes are called prototherians.

There are three living species of monotremes: the platypus and two species of echidnas, or spiny anteaters (Figure
15.45). The platypus and one species of echidna are found in Australia, whereas the other species of echidna is
found in New Guinea. Monotremes are unique among mammals, as they lay leathery eggs, similar to those of
reptiles, rather than giving birth to live young. However, the eggs are retained within the mother’s reproductive tract
until they are almost ready to hatch. Once the young hatch, the female begins to secrete milk from pores in a ridge
of mammary tissue along the ventral side of her body. Like other mammals, monotremes are endothermic but
regulate body temperatures somewhat lower (90 °F, 32 °C) than placental mammals do (98 °F, 37 °C). Like reptiles,
monotremes have one posterior opening for urinary, fecal, and reproductive products, rather than three separate
openings like placental mammals do. Adult monotremes lack teeth.

FIGURE 15.45 The platypus (left), a monotreme, possesses a leathery beak and lays eggs rather than giving birth to live young. An echidna,
another monotreme, is shown in the right photo. (credit “echidna”: modification of work by Barry Thomas)

Marsupials are found primarily in Australia and nearby islands, although about 100 species of opossums and a few
species of two other families are found in the Americas. Australian marsupials number over 230 species and include
the kangaroo, koala, bandicoot, and Tasmanian devil (Figure 15.46). Most species of marsupials possess a pouch in
which the young reside after birth, receiving milk and continuing to develop. Before birth, marsupials have a less
complex placental connection, and the young are born much less developed than in placental mammals.

FIGURE 15.46 The Tasmanian devil is one of several marsupials native to Australia. (credit: Wayne McLean)

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 15.6 Vertebrates 389

Eutherians are the most widespread of the mammals, occurring throughout the world. There are several groups of
eutherians, including Insectivora, the insect eaters; Edentata, the toothless anteaters; Rodentia, the rodents;
Chiroptera, the bats; Cetacea, the aquatic mammals including whales; Carnivora, carnivorous mammals including
dogs, cats, and bears; and Primates, which includes humans. Eutherian mammals are sometimes called placental
mammals, because all species have a complex placenta that connects a fetus to the mother, allowing for gas, fluid,
waste, and nutrient exchange. While other mammals may possess a less complex placenta or briefly have a
placenta, all eutherians have a complex placenta during gestation.

Primates
Order Primates of class Mammalia includes lemurs, tarsiers, monkeys, and the apes, which include humans. Non-
human primates live primarily in tropical or subtropical regions of South America, Africa, and Asia. They range in size
from the mouse lemur at 30 grams (1 ounce) to the mountain gorilla at 200 kilograms (441 pounds). The
characteristics and evolution of primates are of particular interest to us as they allow us to understand the evolution
of our own species.

All primate species have adaptations for climbing trees, as they all descended from tree-dwellers, although not all
species are arboreal. This arboreal heritage of primates resulted in hands and feet that are adapted for brachiation,
or climbing and swinging through trees. These adaptations include, but are not limited to 1) a rotating shoulder joint,
2) a big toe that is widely separated from the other toes and thumbs that are widely separated from fingers (except
humans), which allow for gripping branches, and 3) stereoscopic vision, two overlapping visual fields, which allows
for the depth perception necessary to gauge distance. Other characteristics of primates are brains that are larger
than those of many other mammals, claws that have been modified into flattened nails, typically only one offspring
per pregnancy, and a trend toward holding the body upright.

Order Primates is divided into two groups: prosimians and anthropoids. Prosimians include the bush babies of
Africa, the lemurs of Madagascar, and the lorises, pottos, and tarsiers of Southeast Asia. Anthropoids include
monkeys, lesser apes, and great apes (Figure 15.47). In general, prosimians tend to be nocturnal, smaller in size
than anthropoids, and have relatively smaller brains compared to anthropoids.

FIGURE 15.47 Primates can be divided into prosimians, such as the (a) lemur, and anthropoids. Anthropoids include monkeys, such as the
(b) howler monkey; lesser apes, such as the (c) gibbon; and great apes, such as the (d) chimpanzee, (e) bonobo, (f) gorilla, and (g)
orangutan. (credit a: modification of work by Frank Vassen; credit b: modification of work by Xavi Talleda; credit d: modification of work by
Aaron Logan; credit e: modification of work by Trisha Shears; credit f: modification of work by Dave Proffer; credit g: modification of work by
Julie Langford)