1. Students
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2. Chapter 32 An Introduction to Animal Diversity
What is an animal?
Multicellular, heterotrophic eukaryote – ingestion
Structural support from structural proteins – NOT cell walls
Nervous tissue & muscle tissue for impulse conduction & movement
Sexual reproduction with motile sperm swimming to non-motile egg
How did animals evolve?
- Current animal development

3. Figure 32.2 Early embryonic development in animals (layer 1)
Zygote
Cleavage
Eight-cell stage
Cleavage – cell division w/out cytokinesis
- More cells but same total volume – no cell growth

4. Figure 32.2 Early embryonic development in animals (layer 2)
Zygote
Cleavage
Eight-cell stage
Blastula
Cross section of blastula
Blastocoel
Blastula – hollow ball of cells
-coel – opening or cavity

5. Figure 32.2 Early embryonic development in animals (layer 3)
Zygote
Cleavage
Eight-cell stage
Blastula
Cross section of blastula
Blastocoel
Gastrula
Gastrulation
Endoderm
Ectoderm
Blastopore
Gastrulation – movement of cells to form 2 layers
Blastopore – opening where cells move into
Ectoderm – outside layer
Endoderm – inside layer

6. Chapter 32 An Introduction to Animal Diversity
What is an animal?
Multicellular, heterotrophic eukaryote – ingestion
Structural support from structural proteins – NOT cell walls
Nervous tissue & muscle tissue for impulse conduction & movement
Sexual reproduction with motile sperm swimming to non-motile egg
How did animals evolve?
Current animal development
Current hypothesis

7. Figure 32.4 One hypothesis for the origin of animals from a flagellated protist
Colonial protist,
an aggregate of
identical cells
Hollow sphere of unspecialized cells (shown in cross section)
Beginning of cell specialization
Infolding
Gastrula-like “protoanimal”
Somatic cells
Digestive
cavity
Reproductive cells

8. Chapter 40: Basic Principles of Animal Form & Function
(a) Tuna
(b) Shark
(c) Penguin
(d) Dolphin
(e) Seal
Evolutionary convergence in fast swimmers

9. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Simple diffusion from direct contact w/ environment
To internal exchange thru moist medium

10. Figure 40.3 Contact with the environment
Diffusion
(a) Single cell
Mouth
Gastrovascular
cavity
(b) Two cell layers

11. Figure 40.4 Internal exchange surfaces of complex animals
External environment
Food
CO2 O2
Mouth
Animal
body
Respiratory
system
Circulatory
Nutrients
Excretory
Digestive
Heart
Blood
Cells
Interstitial
fluid
Anus
Unabsorbed
matter (feces)
Metabolic waste
products (urine)
The lining of the small intestine, a diges-
tive organ, is elaborated with fingerlike
projections that expand the surface area
for nutrient absorption (cross-section, SEM).
A microscopic view of the lung reveals
that it is much more spongelike than
balloonlike. This construction provides
an expansive wet surface for gas
exchange with the environment (SEM).
Inside a kidney is a mass of microscopic
tubules that exhange chemicals with
blood flowing through a web of tiny
vessels called capillaries (SEM).
0.5 cm
10 µm
50 µm

12. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Simple diffusion from direct contact w/ environment
To internal exchange thru moist medium
4. Reminder…what is the hierarchy of biological organization?
Atomsmoleculesorganellescellstissuesorgansorgan systems…
5. What is a tissue & what are the 4 types?
Group of cells in a matrix with a common structure & function
Epithelial
Tightly packed sheets that cover the body, line organs & cavities w/in the body
Involved with secretion & absorption
Connective
Binds & supports other tissues
3 kinds - collagenous, elastic, reticular
Muscular
Long cells made of contractile proteins (actin & myosin)
3 kinds - skeletal, smooth, cardiac
Nervous
Sense stimuli & transmits signals
Neuron – basic unit/cell

13. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
All of the chemical rxns within an organism
Catabolism – hydrolysis breaks bonds – releases energy – exergonic
Anabolism – dehydration rxns forms bonds – requires energy – endergonic

14. Figure 40.7 Bioenergetics of an animal: an overview
Organic molecules
in food
Digestion and
absorption
Nutrient molecules
in body cells
Cellular
respiration
Biosynthesis:
growth,
storage, and
reproduction
work
Heat
Energy
lost in
feces
urine
External
environment
Animal
body
Carbon
skeletons
ATP

15. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
All of the chemical rxns within an organism
Catabolism – hydrolysis breaks bonds – releases energy – exergonic
Anabolism – dehydration rxns forms bonds – requires energy – endergonic
7. What is homeostasis & how is it achieved?
- Steady state
Negative feedback
the response is in the opposite direction of the stimulus

16. Figure 40.11 A nonliving example of negative feedback: control of room temperature
Response
No heat
produced
Room
temperature
decreases
Heater
turned
off
Set point
Too
hot
Set
point
Control center:
thermostat
increases on
cold
Heat
Set point is maintained

17. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
What is homeostasis & how is it achieved?
Steady state
Negative feedback
the response is in the opposite direction of the stimulus
Positive feedback
Response & stimulus are in the same direction
8. What are the 2 types of thermoregulation?
Ectothermic – heat & metabolism based on environment
Endothermic – heat & metabolism regulated internally

18. Figure 40.12 The relationship between body temperature and environmental temperature in an aquatic endotherm and ectotherm
River otter (endotherm)
Largemouth bass (ectotherm)
Ambient (environmental) temperature (°C)
Body temperature (°C) 40 30 20 10

19. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
What is homeostasis & how is it achieved?
What are the 2 types of thermoregulation?

20. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
What is homeostasis & how is it achieved?
What are the 2 types of thermoregulation?
How can organisms exchange heat within their bodies?
- Countercurrent heat exchange

21. Figure 40.15 Countercurrent heat exchangers
Arteries carrying warm blood down the
legs of a goose or the flippers of a dolphin
are in close contact with veins conveying
cool blood in the opposite direction, back
toward the trunk of the body. This
arrangement facilitates heat transfer
from arteries to veins (black
arrows) along the entire length
of the blood vessels.
Near the end of the leg or flipper, where
arterial blood has been cooled to far below
the animal’s core temperature, the artery
can still transfer heat to the even colder
blood of an adjacent vein. The venous blood
continues to absorb heat as it passes warmer
and warmer arterial blood traveling in the
opposite direction.
As the venous blood approaches the
center of the body, it is almost as warm
as the body core, minimizing the heat lost
as a result of supplying blood to body parts
immersed in cold water.
In the flippers of a dolphin, each artery is
surrounded by several veins in a
countercurrent arrangement, allowing
efficient heat exchange between arterial
and venous blood.
Canada
goose
Artery
Vein
35°C
Blood flow
30º
20º
10º
33°
27º
18º 9º
Pacific
bottlenose
dolphin 1 2 3

22. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
What is homeostasis & how is it achieved?
What are the 2 types of thermoregulation?
How can organisms exchange heat within their bodies?
How do we achieve homeostasis for body temperature?
-insulation (fat, hair, etc.)
-circulatory adapations (vasodilation/vasoconstriction)
-evaporative cooling (sweating/panting)
-behavioral responses

23. Internal body temperature
Figure 40.21 The thermostat function of the hypothalamus in human thermoregulation
Thermostat in
hypothalamus
activates cooling
mechanisms.
Sweat glands secrete
sweat that evaporates,
cooling the body.
Blood vessels
in skin dilate:
capillaries fill
with warm blood;
heat radiates from
skin surface.
Body temperature
decreases;
thermostat
shuts off cooling
Increased body
temperature (such
as when exercising
or in hot
surroundings)
Homeostasis:
Internal body temperature
of approximately 36–38C
increases;
shuts off warming
Decreased body
temperature
(such as when
in cold
Blood vessels in skin
constrict, diverting blood
from skin to deeper tissues
and reducing heat loss
from skin surface.
Skeletal muscles rapidly
contract, causing shivering,
which generates heat.
activates
warming

24. Chapter 40: Basic Principles of Animal Form & Function
What is an animal?
How did animals evolve?
How has exchange with the environment evolved?
Reminder…what is the hierarchy of biological organization?
What is a tissue & what are the 4 types?
What is metabolism?
What is homeostasis & how is it achieved?
What are the 2 types of thermoregulation?
How do organisms exchange heat with their environment?
How do we achieve homeostasis for body temperature?
How do animals thermoregulate in temperature extremes?
Torpor – physiological state in which activity is low &
metabolism is decreased
Hibernation – winter – bears, Belding’s ground squirrels
Estivation – summer – many reptiles, bees

25. Figure 40.22 Body temperature and metabolism during hibernation in Belding’s ground squirrels
Additional metabolism that would be
necessary to stay active in winter
200
Actual
metabolism
100
Metabolic rate
(kcal per day)
Arousals 35
Body
temperature 30 25 20
Temperature (°C) 15 10 5
Outside
temperature -5
Burrow
temperature
-10
-15
June
August
October
December
February
April