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Body Symmetry
&
Coelomate
Symmetrical
Acoelomate
no mesoderm
Pseudocoelomate
mesoderm attach to one side but
no cleavage
Coelomate
mesoderm cleavage with coelom inbetween
Segmented Body
Porifera (spongy)
•Asymmetric body
•Lack of body
organizaiton
Structure
•Spicules as
structural
component
•Choanocyte
for water flow
and feeding
Adaptive features
Gaseous exchange diffusion
Nutrition
Choanocyte filtering
Support
water
Fertilization
external
Embryo develop
no
Movement
no
Special features
Asymmetical no mouth no anus
Introduction to
coelenterata
Radially symmetrical
Diploblastic
With nematocysts for food capture and
protection
No blood, respiratory, or excretory organs
A network of nerve cells and fibres exists in body
wall
Single internal cavity with only opening to the
exterior, the ‘mouth’ which is surrounded by
tentacles
Reproduction by assexual budding in polyp
stage, sexual reproduction by eggs and sperm in
medusa stage
Polyp and Medusa
•
Polyp
• body is tubular or cylindrical
• oral end, bering the mouth and tentacles, is
directed upwards, and the opposite, or aboral
end is attached
• layer of mesoglea is thin
Polyp
 Medusa
 body resembles a bell or umbrella, with the
convex side upward and the mouth located
in the cneter of the concave under-surface
 tentacles hang downwards from the margin
of the ‘bell’
 layer of mesoglea is extremely thick
Medusa
Adaptive features
Gaseous exchange diffusion
Nutrition
Holozoic by nematocyst
Support
water
Fertilization
external
Embryo develop
external
Movement
Only in larva and medusa
Special features
Nematocyst, polyp, medusa
Radial symmetrical, acoelomate
Nematoblasts
 Nematoblasts
1. they are in the ectoderm
2. each consists of highly complex organelle,
nematocyst, which is a minute capsule
filled with fluid and containing a coiled,
barbed thread tube
 when the triggering device, cnidocil, on the
outer surface of the nematoblast is
stimulated, the thread tube everts to aid in
capture of prey, protection or locomotion
Morphology of Obelia
1. Classification
–
Class Hydrozoa (hydroids)
2. Habitat
–
lives in shallow coastal water attached to
substratum
 Morphology
–
–
–
exists in 2distinctly different forms in its life
colonial form (polyps)
free living form (medusa)
The colonial form
Medusa
Sea Anemone
Introduction
to Platyhelminthes
Triploblastic, bilaterally symmetrical,
acoelomate and unsegmented
Body is flattened dorsoventrally
Digestive system incomplete –a mouth
but no anus
No skeletal, circulatory, or respiratory
systems; excretory system of many flame
cells joined to excretory ducts
Nervous system primitively a simple
nerve net, but advanced forms have a pair
of anterior ganglia or a nerve ring and 1
to3 pairs of longitudinal nerve cords with
transverse connectives
Complex hermaphroditic reproductive
system; internal fertilization;
development either direct or with 1 or more
larval stages
Adaptive features
Gaseous exchange Flattened, diffusion
Nutrition
Holozoic in planaria or parasitic
Support
no
Fertilization
Hermaphrodite
Embryo develop
Egg external
Movement
muscle
Special features
Bilateral symmetrical, acoelomate
Planaria
1. Habitat
–
the common planaria inhabit cool ,clear
permanent lakes and streams, where they
avoid light by clinging to the under surface
of stones or logs in the water
Structure
Cross section
of body
Tapeworm
1. Habitat
–
–
The adult stage lives in the small of its
primary host (e.g. man) i.e. it is an
endoparasite
The immature stage lives inside the body of
the secondary host (e.g. pig)
Structure
Life Cycle
Nematoda
Adaptive features
Gaseous exchange diffusion
Nutrition
Parasite, holozoic
Support
no
Fertilization
hermaphrodite
Embryo develop
egg
Movement
muscle
Special features
Bilateral symmetrical, no segment
&
External view of an earthworm
Introduction to annelids
Annelids…for example as earthworm
 belong to the Phylum Annelida
 are segmented worms showing metameric
segmentation
 are coleomate animals
 have a fluid-filled body in which the gut and other
organs are suspended
 are further classified into three classes: polychaeta,
oligochaeta, hirudinea
Body structure of
annelids
 enlarged coelom to accommodate more
complex internal organs.
 well-developed, fluid-filled coelom and the
tough integument act as a hydrostatic skeleton.
 Closed circulatory system with blood vessels
running the length of the body and branching
into every segment
 nervous system consists of a brain connected
to a ventral solid nerve cord, with a ganglion in
each segment
 complete digestive system including a
pharynx, stomach, intestine, and accessory
glands
 excretory nephridia in each segment to collect
waste material from coelom and excrete it
through the body wall
Anatomy of a typical annelid, earthworm
Cross section of through the earthworm body
Adaptive features
Gaseous exchange Diffusion through skin
Nutrition
Holozoic, debris feeder
Support
hydroskeleton
Fertilization
Internal, hermaphrodite but mate
Embryo develop
External, cocoon
Movement
Muscle, chaetae
Special features
Coelomate, segmented,
Morphology of an earth worm
Earthworms belong to the oligochaeta class.
 They are hermaphroditic with both male and female
gonads.
 The mesoderm of an earthworm splits into outer and
inner layer with coelom in between which allows:
- space for development of organs
- development of hydrostatic skeleton for support and
movement
- for independent movement of body wall and gut
Metameric segmentation of earthworms allows for:
- specialization of different body parts
- division of labour
- muscular body wall divides into blocks to provide
independent movement of different parts of the body
Earthworms have hydroskeletons to maintain the
body shape
Muscles of body wall acts on coelomic fluid to
bring about locomotion, support and protection
Ecological significance
of earthworms
Soils may barbor 50 to 500 earthworms per square
meter; they contribute to soil formation and
improvement in the following ways:
 tunnels improve aeration and drainage
 dead vegetation is pulled into the soil where decay
by saprobionts take place
 mixing of soil layers
 castings fertilizes the soil
 addition of organic matter by excretion and death
secretions of gut neutralize acid soils
improving tilth by passing soil through gut
It may be doubted whether there are
many other creatures which have played
so important a part in the history of the
world
Charles Darwin,
1881
Classification of the
Annelida
Arthropoda
segmented appendices
Introduction to arthropods
Arthropods…
 have exoskeleton
 have jointed limbs
 have segmented body
 have dorsal heart and open blood system
grow in stages after moulting (ecdysis)
 because of the size and importance of this
phylum, it is mainly divided into four further
classes:
- crustacea: with very hard exoskeleton
- insecta : body with three parts and three pairs of
legs
- arachnida: body divided into two parts with four
pairs of legs
- myriapoda: with many segments and legs
Adaptive features
Gaseous exchange Trachea, gill
Nutrition
Holozoic, parasitic
Support
exoskeleton
Fertilization
internal
Embryo develop
egg
Movement
Leg, fly by wing, swim by tail
Special features
Segmented, coelomate
The subphylum crustacea
Crustacea contains 30,000 mostly marine species. A
few species live in freshwater. For example: lobsters,
crabs, crayfish, shrimp, etc.
They process...
 two pairs of antennae
 a pair of mandibles
 a pair of compound eyes (usually on stalks)
 two pairs of maxillae on their heads
 a pair of appendages on each body segment
 a head, thorax, and abdomen
 gills for gaseous exchange
 a hard exoskeleton for support and protection
Anatomy of crustacean (a prawn)
Marine Copepod (Crustacean),
Pleuromamma sp.
Marine Copepod
(Crustacean), Actitius sp.
The subphylum insecta
Insects are the largest group, with probably over one
million identified and named species.
Insects live in almost all terrestrial and freshwater
habitats, with a few species living in the oceans.
These contribute to insects that they are the most
successful group of animal, and are the least likely to
become extinct.
General characteristics
of the insects
External characteristics
 body comprises head, thorax and abdomen
 three pairs of thoracic walking legs
 two pairs of thoracic wings derived from the
outgrowths of the body wall
 one pair of antennae on the head
 one pair of relatively large compound eyes
Other characteristics
 respiration by a tracheae system with external
openings called spiracles dividing into finely
branched tubules that carry gases directly to
metabolizing tissues
 nervous system include a number of ganglia and
a ventral, double nerve cord
 have a complete and complex digestive system
very sensitive to sound and have excellent
chemoreceptive abilities.
 have to moult in order to increase in size
Anatomy of the insect body
Fruit flyFruit Fly. The insect body is divided into head,
thorax (with wings), and a segmented abdomen. The
compound eye of insects is also quite prominent.
Significance of insects
to the ecosystem
Insects are very valuable to us although it sometimes
eat our food, sting us and transmit diseases. They
play a vital role in the ecosystem by functioning in:
 pollination of many flowering plants
 decomposition of organic materials
 recycling of carbon, nitrogen, and other essential
nutrients
 control of populations of harmful invertebrate
species (including other insects)
 direct production of certain foods like honey
 manufacture of useful products such as silk and
shellac
 become prey of other predators to balance the food
chain
Insecta is most successful animal because it
divided to 70% of all animal species.
Some more examples of
insects
Cockroach - can
transmit dieseas
Dragonfly
Bee - a born pollinator of
flowers
Moth - can also
pollinate like the bees
Cicada
Ant - sometimes
bite the wooden
furniture