Animals are a major group of mostly multicellular,
eukaryotic organisms of the
kingdom Animalia or
Metazoa. Their
body plan
eventually becomes fixed as they develop, although some undergo a
process of
metamorphosis
later on in their life. Most animals are
motile, meaning they can move spontaneously and
independently. All animals are also
heterotrophs, meaning they must ingest other
organisms for
sustenance.
Most known animal
phyla appeared in the
fossil record as marine species during the
Cambrian explosion, about 542 million
years ago.
Etymology
The word "animal" comes from the
Latin word
animale,
neuter of
animalis, and is derived from
anima, meaning
vital breath or soul. In everyday colloquial usage, the word
usually refers to non-
human animals.
Frequently only closer relatives of humans such as
vertebrates or
mammals
are meant in colloquial use. The biological definition of the word
refers to all members of the Kingdom Animalia including
humans.
Characteristics
Animals have several characteristics that set them apart from other
living things. Animals are
eukaryotic and
are
multicellular (although see
Myxozoa), which separates them from
bacteria and most
protists.
They are
heterotrophic, generally
digesting food in an internal chamber, which separates them from
plants and
algae (some
sponges are capable of
photosynthesis and
nitrogen fixation though). They are also
distinguished from plants, algae, and
fungi
by lacking rigid
cell walls. All animals
are
motile, if only at certain life stages.
In most animals,
embryos pass through a
blastula stage, which is a characteristic
exclusive to animals.
Structure
With a few exceptions, most notably the
sponges (Phylum
Porifera) and
Placozoa, animals have bodies
differentiated into separate
tissues. These include
muscles, which are able to contract and control
locomotion, and
nerve tissue, which
sends and processes signals. There is also typically an internal
digestive chamber, with one or two
openings. Animals with this sort of organization are called
metazoans, or
eumetazoans when the former
is used for animals in general.
All animals have
eukaryotic cells,
surrounded by a characteristic
extracellular matrix composed of
collagen and elastic
glycoproteins. This may be calcified to form
structures like
shell,
bones, and
spicules. During
development it forms a relatively flexible framework upon which
cells can move about and be reorganized, making complex structures
possible. In contrast, other
multicellular organisms like plants
and fungi have cells held in place by cell walls, and so develop by
progressive growth. Also, unique to animal cells are the following
intercellular junctions:
tight
junctions,
gap junctions, and
desmosomes.
Reproduction and development
Nearly all animals undergo some form of
sexual reproduction. They have a few
specialized
reproductive cells, which undergo
meiosis to produce smaller motile
spermatozoa or larger non-motile
ova. These fuse to form
zygotes,
which develop into new individuals.
Many animals are also capable of
asexual reproduction. This may take
place through
parthenogenesis, where
fertile eggs are produced without mating, or in some cases through
fragmentation.
A
zygote initially develops into a hollow
sphere, called a
blastula, which undergoes
rearrangement and differentiation. In sponges, blastula larvae swim
to a new location and develop into a new sponge. In most other
groups, the blastula undergoes more complicated rearrangement. It
first
invaginates to form a
gastrula with a digestive chamber, and two separate
germ layers - an external
ectoderm and an internal
endoderm. In most cases, a
mesoderm also develops between them. These germ
layers then differentiate to form tissues and organs.
Food and energy sourcing
All animals are
heterotrophs, meaning
that they feed directly or indirectly on other living things. They
are often further subdivided into groups such as
carnivores,
herbivores,
omnivores, and
parasites.
Predation is a
biological interaction where a
predator (a heterotroph that is hunting) feeds on its prey (the
organism that is attacked). Predators may or may not kill their
prey prior to feeding on them, but the act of predation always
results in the death of the prey. The other main category of
consumption is
detritivory, the
consumption of dead
organic matter.
It can at times be difficult to separate the two
feeding behaviours, for example where
parasitic species prey on a host organism
and then lay their eggs on it for their offspring to feed on its
decaying corpse. Selective pressures imposed on one another has led
to an
evolutionary arms race
between prey and predator, resulting in various
antipredator adaptations.
Most animals feed indirectly from the energy of
sunlight. Plants use this
energy to convert sunlight into simple
sugars using a process known as
photosynthesis. Starting with the molecules
carbon dioxide (CO
2) and
water (H
2O), photosynthesis
converts the energy of sunlight into chemical energy stored in the
bonds of
glucose
(C
6H
12O
6) and releases
oxygen (O
2). These sugars are then used as
the building blocks which allow the plant to grow. When animals eat
these plants (or eat other animals which have eaten plants), the
sugars produced by the plant are used by the animal. They are
either used directly to help the animal grow, or broken down,
releasing stored solar energy, and giving the animal the energy
required for motion. This process is known as
glycolysis.
Animals who live close to
hydrothermal
vents and
cold seeps on the
ocean floor are not dependent on the energy of
sunlight. Instead
chemosynthetic
archaea and
bacteria
form the base of the
food chain.
Origin and fossil record
Animals are generally considered to have
evolved from a
flagellated eukaryote. Their closest known living
relatives are the
choanoflagellates, collared flagellates
that have a morphology similar to the choanocytes of certain
sponges.
Molecular studies place animals
in a supergroup called the
opisthokonts,
which also include the choanoflagellates,
fungi and a few small parasitic
protists. The name comes from the posterior location
of the
flagellum in motile cells, such as
most animal spermatozoa, whereas other
eukaryotes tend to have anterior flagella.
The first fossils that might represent animals appear towards the
end of the
Precambrian, around 610
million years ago, and are known as the
Ediacaran or Vendian biota. These are
difficult to relate to later fossils, however. Some may represent
precursors of modern phyla, but they may be separate groups, and it
is possible they are not really animals at all. Aside from them,
most known animal phyla make a more or less simultaneous appearance
during the
Cambrian period, about 542
million years ago. It is still disputed whether this event, called
the
Cambrian explosion,
represents a rapid divergence between different groups or a change
in conditions that made fossilization possible. However some
paleontologists and geologists would suggest that animals appeared
much earlier than previously thought, possibly even as early as 1
billion years ago.
Trace fossils such
as tracks and burrows found in
Tonian era
indicate the presence of
triploblastic
worm like
metazoans roughly as large
(about 5 mm wide) and complex as
earthworms. In addition during the beginning of
the Tonian period around 1 billion years ago (roughly the same time
that the trace fossils previously discussed in this article date
back to) there was a decrease in
Stromatolitediversity which may indicate the
appearance of grazing animals during this time as Stromatolites
also increased in diversity shortly after the end-Ordovician and
end-Permian rendered large amounts of grazing marine animals
extinct and decreased shortly after their populations recovered.
The discovery that tracks very similar to these early trace fossils
are produced today by the giant single-celled protist
Gromia sphaerica casts further doubt
on their interpretation as evidence of early animal
evolution.
Groups of animals
Porifera, Radiata and basal Bilateria
The sponges (
Porifera) were long thought to
have diverged from other animals early. They lack the complex
organization found in most other phyla. Their cells are
differentiated, but in most cases not organized into distinct
tissues. Sponges typically feed by drawing in water through pores.
Archaeocyatha, which have fused
skeletons, may represent sponges or a separate phylum. However, a
phylogenomic study in 2008 of 150 genes in 21 genera revealed that
it is the
Ctenophora or comb jellies
which are the basal lineage of animals, at least among those 21
phyla. The authors speculate that sponges—or at least those lines
of sponges they investigated—are not so primitive, but may instead
be secondarily simplified.
Among the other phyla, the Ctenophora and the
Cnidaria, which includes
sea
anemones,
corals, and
jellyfish, are radially symmetric and have
digestive chambers with a single opening, which serves as both the
mouth and the anus. Both have distinct tissues, but they are not
organized into
organs. There are
only two main germ layers, the ectoderm and endoderm, with only
scattered cells between them. As such, these animals are sometimes
called
diploblastic. The tiny
placozoans are similar, but they do not have a
permanent digestive chamber.
The remaining animals form a
monophyletic group called the
Bilateria. For the most part, they are
bilaterally symmetric, and often have a
specialized head with feeding and sensory organs. The body is
triploblastic, i.e. all three germ
layers are well-developed, and tissues form distinct organs. The
digestive chamber has two openings, a mouth and an anus, and there
is also an internal body cavity called a
coelom or pseudocoelom. There are exceptions to each
of these characteristics, however - for instance adult
echinoderms are radially symmetric, and certain
parasitic worms have extremely
simplified body structures.
Genetic studies have considerably changed our understanding of the
relationships within the Bilateria. Most appear to belong to two
major lineages: the
deuterostomes and
the
protostomes, the latter of which
includes the
Ecdysozoa,
Platyzoa, and
Lophotrochozoa. In addition, there are a few
small groups of bilaterians with relatively similar structure that
appear to have diverged before these major groups. These include
the
Acoelomorpha,
Rhombozoa, and
Orthonectida. The
Myxozoa, single-celled parasites that were
originally considered Protozoa, are now believed to have developed
from the Medusozoa as well.
Deuterostomes
Deuterostomes differ from the other
Bilateria, called
protostomes, in several
ways. In both cases there is a complete digestive tract. However,
in protostomes the initial opening (the
archenteron) develops into the mouth, and an
anus forms separately. In deuterostomes this is reversed. In most
protostomes, cells simply fill in the interior of the gastrula to
form the mesoderm, called schizocoelous development, but in
deuterostomes it forms through
invagination of the endoderm, called
enterocoelic pouching. Deuterostomes also have a dorsal, rather
than a ventral, nerve chord and their embryos undergo different
cleavage.
All this suggests the deuterostomes and protostomes are separate,
monophyletic lineages. The main phyla of deuterostomes are the
Echinodermata and
Chordata. The former are radially symmetric and
exclusively marine, such as
starfish,
sea urchins, and
sea cucumber. The latter are dominated by the
vertebrates, animals with backbones.
These include
fish,
amphibians,
reptiles,
birds, and
mammals.
In addition to these, the deuterostomes also include the
Hemichordata or acorn worms. Although they are
not especially prominent today, the important fossil
graptolites may belong to this group.
The
Chaetognatha or arrow worms may
also be deuterostomes, but more recent studies suggest protostome
affinities.
Ecdysozoa
The
Ecdysozoa are protostomes, named after
the common trait of growth by moulting or
ecdysis. The largest animal phylum belongs here, the
Arthropoda, including
insects,
spiders,
crabs, and their kin. All these organisms have a body
divided into repeating segments, typically with paired appendages.
Two smaller phyla, the
Onychophora and
Tardigrada, are close relatives of the
arthropods and share these traits.
The ecdysozoans also include the
Nematoda
or roundworms, perhaps the second largest animal phylum. Roundworms
are typically microscopic, and occur in nearly every environment
where there is water. A number are important parasites. Smaller
phyla related to them are the
Nematomorpha or horsehair worms, and the
Kinorhyncha,
Priapulida, and
Loricifera. These groups have a reduced coelom,
called a pseudocoelom.
The remaining two groups of protostomes are sometimes grouped
together as the
Spiralia, since in both
embryos develop with
spiral
cleavage.
Platyzoa
The
Platyzoa include the phylum
Platyhelminthes, the flatworms. These were
originally considered some of the most primitive Bilateria, but it
now appears they developed from more complex ancestors. A number of
parasites are included in this group, such
as the
flukes and
tapeworms. Flatworms are
acoelomates, lacking a
body cavity, as are their closest relatives, the microscopic
Gastrotricha.
The other platyzoan phyla are mostly microscopic and
pseudocoelomate. The most
prominent are the
Rotifera or rotifers,
which are common in aqueous environments. They also include the
Acanthocephala or spiny-headed worms,
the
Gnathostomulida,
Micrognathozoa, and possibly the
Cycliophora. These groups share the presence of
complex jaws, from which they are called the
Gnathifera.
Lophotrochozoa
The
Lophotrochozoa include two of the
most successful animal phyla, the
Mollusca
and
Annelida. The former, which is the
second-largest animal phylum by number of described species,
includes animals such as
snails,
clams, and
squids, and the latter
comprises the segmented worms, such as
earthworms and
leeches. These
two groups have long been considered close relatives because of the
common presence of
trochophore larvae,
but the annelids were considered closer to the arthropods, because
they are both segmented. Now this is generally considered
convergent evolution, owing to many
morphological and genetic differences between the two phyla.
The Lophotrochozoa also include the
Nemertea or ribbon worms, the
Sipuncula, and several phyla that have a fan of
cilia around the mouth, called a
lophophore. These were traditionally grouped
together as the lophophorates. but it now appears they are
paraphyletic, some closer to the Nemertea and
some to the Mollusca and Annelida. They include the
Brachiopoda or lamp shells, which are prominent
in the fossil record, the
Entoprocta, the
Phoronida, and possibly the
Bryozoa or moss animals.
Model organisms
Because of the great diversity found in animals, it is more
economical for scientists to study a small number of chosen species
so that connections can be drawn from their work and conclusions
extrapolated about how animals function in general. Because they
are easy to keep and breed, the fruit fly
Drosophila melanogaster and the
nematode
Caenorhabditis
elegans have long been the most intensively studied
metazoan
model organisms, and were
among the first life-forms to be genetically sequenced. This was
facilitated by the severely reduced state of their
genomes, but the double-edged sword here is that with
many
genes,
introns and
linkages lost, these ecdysozoans can
teach us little about the origins of animals in general. The extent
of this type of evolution within the superphylum will be revealed
by the crustacean, annelid, and molluscan
genome projects currently in progress.
Analysis of the
starlet sea
anemone genome has emphasised the importance of sponges,
placozoans, and
choanoflagellates,
also being sequenced, in explaining the arrival of 1500 ancestral
genes unique to the Eumetazoa.
An analysis of the homoscleromorph sponge
Oscarella
carmela also suggests that the last common ancestor of sponges
and the eumetazoan animals was more complex than previously
assumed.
Other model organisms belonging to the animal kingdom include the
mouse (
Mus musculus) and
zebrafish (
Danio rerio).
History of classification
Aristotle divided the living world between
animals and
plants, and this was followed by
Carolus Linnaeus (Carl von Linné),
in the first hierarchical classification. Since then biologists
have begun emphasizing evolutionary relationships, and so these
groups have been restricted somewhat. For instance, microscopic
protozoa were originally considered animals
because they move, but are now treated separately.
In Linnaeus's original scheme, the animals were one of three
kingdoms, divided into the classes of
Vermes,
Insecta,
Pisces,
Amphibia,
Aves, and
Mammalia. Since then the last four have all been
subsumed into a single phylum, the
Chordata, whereas the various other forms have been
separated out. The above lists represent our current understanding
of the group, though there is some variation from source to
source.
See also
References
Notes
Bibliography
External links
.jpg/180px-Sympetrum_flaveolum_-_side_(aka).jpg)
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