Biol 224.3 – Animal Body Systems Lecture 3 PDF

Summary

This document is a lecture on animal body systems, specifically focusing on classifying animals through their body plans, embryonic development, and germ layers. It delves into the concepts of protostomes, deuterostomes, diploblasts, and triploblasts. The lecture also discusses the importance of animal diversity and evolution, including environmental adaptations, and how they are influenced by factors like embryonic development and body cavity types.

Full Transcript

 Biol 224.3 – Animal Body Systems

Lecture 3: Classifying Animals

Dr Joan Forder

Supplementary Textbook Reading: (5th Edition: Chapter 24, page 603-611)
1
 Classifying Animals
Use of Body Plans to classify animals
Describe the way that animals are built
Considered the “blueprint” of cellular organization
Summary of Body Plans in Animals

Fig. 24.5, p. 608
 Animal Body Plans
Animal body plans are influenced by:

Embryonic development pattern
(Protostomes vs. Deuterostomes)
Germ cell layers
(Diploblasts vs. Triploblasts)
Body symmetry
Body cavity type

4
 Sexual Reproduction in Animals
Most animals undergo some form of sexual reproduction
Germ line cells Note: asexual
undergo meiosis to reproduction also
produce haploid occurs (e.g.,
gametes budding in hydra,

unfertilized
fragmentation in
echinoderms, and
Gametes fuse parthenogenesis in
during fertilization insects, some
to form a diploid reptiles)
zygote eggs

*We will learn more about animal reproduction later in the course 5
 Zygote Cleavage

Zygote Cleavage follows fertilization
The division of cells in the early embryo

Zygotes undergo rapid cell cycles with
no significant growth
C Zygote
-
develops into a compact mass
of cells termed morula
develop
-top
aeee

G Morula derives into a hollow sphere of
single layer of cells, termed blastula
Unique to animals -bottom
Protostomes and Deuterostomes have
different cleavage patterns Morula Blastula
6
 Cleavage Patterns in PROTOSTOMES
Protostomes exhibit spiral cleavage -
newly produced cells lie in the space
between the cells immediately below
them

Each cell’s developmental path is
determined as the cell is produced
meaning that each blastomere is
unable to develop into a
complete organism by itself
(Determinant Cleavage).
-
cell already has function when
produced
7
Image source: cronodon.com
 Cleavage Patterns in DEUTEROSTOMES
Deuterostomes exhibit radial cleavage -
newly produced cells lie directly above
and below other cells of the embryo

Developmental fates of the first few cells
are not determined if cell removed, each
-

cell can produce separate
identical onganisms :

Meaning a cell removed from the morula
will go on to form a complete organism
(Indeterminant Cleavage)

8
Image source: cronodon.com
 Gastrulation
Gastrulation Follows Cleavage
Gastrulation begins at the vegetal
pole
Blastula invaginates and
undergoes further differentiation
into 2 or 3 (most animals) germ
layers: gastrula
Ectoderm Blastula
Mesoderm
Endoderm
Germ layers differentiate to form
tissues and organs
9
 Animal Body Plans
Animal body plans are influenced by:

Embryonic development pattern
(Protostomes vs. Deuterostomes)
Germ cell layers
(Diploblasts vs. Triploblasts)
Body symmetry
Body cavity type

10
 Germ Layers

?
layers
+
which
les

Keramp
Diploblastic animals (e.g., jellyfish, corals, anemones)
have 2 germ layers: Ectoderm and Endoderm
Triploblastic animals (e.g., flatworms, chordates) have
3 germ layers: Ectoderm, Endoderm and Mesoderm
/
in middle
layer

11
 Primary Cell Layers in Embryos
Endoderm
Innermost layer
Forms lining of gut
Mesoderm
Between other layers
Forms muscles of body wall and most other structures between gut
and external covering
Ectoderm
Outermost layer
Forms external covering and nervous system
 From Germ Layers to Tissues and Organs
Ectoderm – Skin and nervous system
Endoderm – Digestive tract
Mesoderm – Muscle and skeleton

Tissues - Groups of similar differentiated cells specialized for particular functions
- Usually isolated from other tissues by membrane layers

Questions:
1. Since Diploblastic animals (e.g., jellyfish, corals, anemones)
have only 2 germ layers which layer are they missing? mesoderm
-

other structures other
2. Which tissues are missing? - all system
than nervous

3. How does that affect the function of the animals? -

13
 Polarity of the Digestive System
Blastopore develops Embryonic developmental pattern
first
Later, another body
opening at the carity
opposite end of the 6
embryo develops
This second opening
transforms the
pouch-like gut into a
digestive tube.
·
pouch >
-

tube
6 C

Protostomes Deuterostomes
14
 hizo
split
S2
* Enteronela
ted tofine
intes Origin of the Mesoderm
Protostomes
Mesoderm differentiates near the
blastopore O
Coelom (body cavity) originates as a split
in the mesoderm (i.e., schizocoelom)

Deuterostomes
mesoderm originates from outpocketings
O
of the archenteron (primitive gut).
Coelom develops from space within the
outpocketings (i.e., enterocoelom)
15
&Summary of Embryonic Development#
Differences
Protostomes Deuterostomes
Cleavage Pattern Spiral Radial
Cell Fate Determinant Indeterminant
Polarity of Mouth develops from Mouth develops from
Digestive Tract blastopore secondary opening

Origin of Differentiates near Mesoderm originates from
Mesoderm blastopore outpocketings of the
archenteron
Origin of Coelom Schizocoelom Enterocoelom
 Animal Body Plans
Animal body plans are influenced by:

Embryonic development pattern
(Protostomes vs. Deuterostomes)
Germ cell layers
(Diploblasts vs. Triploblasts)
Body symmetry
Body cavity type

17
 Body Symmetry of Animals

Radial symmetry: can be divided Bilateral symmetry: can be divided
equally by any longitudinal along a vertical plane at the middle to
plane passing through the central create two identical halves
ex human
axis ex
sear 18
 Animals with RADIAL SYMMETRY
All are=
Diploblastic (except adult
echinoderms)
Exhibits no left or right sides
Have a top (dorsal) and a bottom (ventral)
side
Often circular or tubular in shape with
a mouth at one end (e.g., cnidarians
and ctenophores)

19
 Animals with BILATERAL SYMMETRY
Triploblastic
Balanced duplicate distribution of
most body parts
Specialized head with feeding and a
of

sensory organs (Cephalization) formation
-

Digestive chamber with two openings,
mouth and an anus
Most animals with bilateral
symmetry contain Segmentation

20
 Segmentation
Repeated structures along the anterior-posterior axis
Seen in annelids, arthropods, chordates
Advantages: movement, specialization

21
 Animal Body Plans
Animal body plans are influenced by:

Embryonic development pattern
(Protostomes vs. Deuterostomes)
Germ cell layers
(Diploblasts vs. Triploblasts)
Body symmetry
Body cavity type

22
 Deuterostome Body Cavity (COELOM)
In most bilaterally symmetrical
animals, a body cavity (coelom)
separates the gut from the body Most animals are coelomate
wall (= Eucoelomate)

A fluid-filled cavity between the
intestines and the body wall
Formed within the mesoderm of the
embryo
 Protostome Body Cavities
Acoelomate (a = not; koilos = hollow)
No body cavity
-surface areatovolnigh
Flat worms
(Phylum Platyhelminthes)

Note: Diploblasts are all acoelomates

Pseudocoelomate (pseudo = false)
Pseudocoelum: Fluid-filled or organ-filled
space between endoderm and mesoderm
Roundworms
(Phylum Nematoda)

24
⑪Summary of Body Plans in Animals *

Fig. 24.5, p. 608
 Something to Think About
What are the advantages of
multicellularity over unicellularity?

Why bilateral symmetry is more common in
animal kingdom?

What are the disadvantages of being an
acoelomate animal?

26
 Why do we study Animal Diversity &
Evolution?
Animals (and animal body systems) have a common evolutionary
history
helps us to learn common principles
Animals occupy very diverse types of environments
helps us understand environmental adaptations
· help understand how they adapted
The physiological phenotype is a product of
the genotype and the environment.

27
Example of Environmental Constraints
Compare Respiratory
system adaptations Fish: Flow through
t
a
men
depen

Bird: Circular flow

Human: Tidal Flow
28
 Challenges for Animals

What challenges must animals overcome to be able to survive
and reproduce?
Extract nutrients & O2/energy from the environment
Eliminate toxic metabolic wastes from the body
Sense the environmental changes and respond favorably
Maintain near constant internal body conditions homeostasis
-

29
 Unifying Concepts
Animals are diverse, yet some common principles apply to all
animals

Physiological processes must:

Obey the laws of physics and chemistry

Usually tightly regulated (homeostasis)

30
 Example: Electrical Laws
Electrical laws describe membrane function of all cells
including excitable cells such as neurons and muscle cells

Neuron Muscles
31
 NEXT WEEK

Communication & integration in the animal
body – Homeostasis.

Nervous systems.