Major Organ Systems PDF

Summary

These lecture notes cover major organ systems in vertebrate biology, focusing on circulation, respiration, and excretion. The notes detail the circulatory system's components, single and double circulation, and the evolution of the vertebrate heart. The excretory system is also discussed, including nephridia, nitrogenous wastes, and osmotic regulation mechanisms.

Full Transcript

Major organ systems
BI2CV1 Comparative Vertebrate Biology
Dr Manabu Sakamoto
[email protected]
Major organ systems

Circulatory system
Respiratory system
Excretory system
Circulatory system
Circulatory system

Vertebrates have a closed
circulatory system:
Blood
Heart
Arteries
Veins
Capillaries
The vertebrate blood

The vertebrate blood
comprises:
Plasma
Fluid component
Formed elements
Cellular components
The vertebrate heart

Vertebrates have multi-
chambered hearts:
Atrium
Receives blood
Ventricle
Pumps out blood
Blood vessels

Oxygenated blood is
delivered to the rest of the
body through the
arteries.
Deoxygenated blood
returns to the heart
through the veins.
Capillaries are the tiny
vessels that lie between
the arteries and veins.
Blood vessels

The interior surface of
vertebrate blood vessels
are lined with an
endothelium.
Endothelium forms a
barrier between blood and
tissue.
More efficient transfer of
blood?
Capillaries

Exchange between
capillaries and body tissue
occurs through differentials
in blood and osmotic
pressures.
Gas exchange in respiratory
organs will be covered in
the respiratory system
section.
Waste/water exchange will
be covered in the excretory
system section.
Single and double circulation

Blood travels in one of two Two-chambered hearts of fish

general patterns:
Single circulation
Blood passes through heart
only once during each
complete circuit.
Fish Four-chambered hearts of amniotes
Double circulation
Blood passes through the
heart twice during each
circuit.
Amniotes
Single and double circulation

Double circulation is also Two-chambered hearts of fish

called a “figure of eight
system".

Four-chambered hearts of amniotes
Evolution of the vertebrate heart

The ancestral vertebrate
heart was two-
chambered with a single
flow-through system.
Tetrapods acquired a
three-chambered
heart.
Amniotes evolved a
double-circuit circulatory
system.
Four-chambered hearts
acquired in archosaurs
Excretory system
Excretion

Management and
elimination of excess
substances that enter the
body.
Water
Salts
Metabolic by-products and
waste
Nitrogenous wastes
Nitrogenous wastes

Formed as by-product of metabolic breakdown of
nitrogen-containing molecules (mainly proteins and
nucleic acid).
Carbon, hydrogen and oxygen are extracted and stored in the
form of carbohydrates and fats.
Excess nitrogen (most commonly ammonia, NH3) is extracted
from the body (through excretion).
Ammonia is toxic!
NH3
Nucleic acid

Amino acid
Nitrogenous waste
NH3
Nitrogenous waste is excreted as urine.
Aquatic animals can directly excrete ammonia (NH3).
Ammonotelism: excretion of ammonia.
Terrestrial animals need to convert ammonia into
something less toxic.
Urea (amphibians and mammals)
Ureotelism: excretion of urea

Uric acid (reptiles and birds)
Uricotelism: excretion of uric acid
Excretory system: nephridia

Nephridia (singular:
nephridium) are an
ultrafiltration (UF) based
excretory system common
to bilaterians.

Ultrafiltration
site

Flow of
water
Excretion of urine

In vertebrates, urine is
excreted in four steps:
Ultrafiltration
Protein- and cell-free ultrafiltrate
(primary urine) made by filtering
through permeable membrane
(ultrafilter).
Reabsorption
Water, glucose and amino acids Nephro
are selectively reabsorbed. n
Secretion
Wastes selectively secreted out
into ultrafiltrate.
Excretion
Final urine is excreted.
Nephridial system in
cephalochordates
Lancelets have paired
nephridia consisting of a
cluster of podocytes on a
branch of the dorsal aorta. aor: aorta

Urine discharged into the
fcl: filtration cell
atr: atrium
coe: coelom
gls: gill slit

atrium – a
not: notochord
npr: nephridiopore (kidney)
sbc: subchordal coelom

circumpharyngeal water
jacket.

Ruppert 1994. Am Zool 34: 542–5
 1. Renal pyramid
2. Interlobular artery

Vertebrate kidneys
3. Renal artery
4. Renal vein
5. Renal hilum
6. Renal pelvis
7. Ureter
8. Minor calyx
9. Renal capsule
10. Inferior renal capsule
11. Superior renal capsule
12. Interlobular vein[citation needed]
13. Nephron

Vertebrate kidneys are
14. Renal sinus
15. Major calyx
16. Renal papilla
17. Renal column Nephro
ultrafiltration (UF)-based n
Nephro
excretory organs, derived n
from chordate nephridial
system.

Nephro
n
Osmotic regulation in fishes

Freshwater fish are
osmoregulators.
Actively control salt
concentrations despite the
salt concentrations in the
environment
Saltwater fish are
osmoconformers.
Match their body osmolarity
to their environment.
Birds and reptiles

Birds and reptiles form
urine in paired kidneys as
in other vertebrates.
Urine passes by way of
tubes called ureters to the
cloaca.
There is no urinary
bladder
Excrete nitrogenous waste
as uric acid.
Often white solid.
Mammals

Mammals form urine in
paired kidneys as in other
vertebrates.
Urine passes from kidney
via the ureters to the
bladder.
Urine excreted through 1. Human urinary system:
2. Kidney
3. Renal pelvis
4. Ureter

the urethra. 5. Bladder
6. Urethra. (Left side with frontal section
7. Adrenal gland
Vessels: 8. Renal artery and vein
9. Inferior vena cava
10. Abdominal aorta
11. Common iliac artery and vein
With transparency: 12. Liver
13. Large intestine
14. Pelvis
Respiratory system
Respiration = gas exchange

Physiological respiration
Also called gas exchange.
Movement of gas across
the external boundary of an
organism and its
surroundings.
Uptake of O2.
Release of CO2.
Provides O2 for cellular
respiration.
Production of energy;
adenosine triphosphate Blood flow
(ATP).
Mechanism of gas exchange
Passive diffusion of gas
across boundaries between
the body and surrounding
medium (water or air).
Membranes in respiratory
organs (gills, lungs).
Cell membranes (sponges).
Water flow reaches each cell.
Body walls (cnidarians).
Epidermis and gastrodermis.
Mechanism of gas exchange

Diffusion across 𝜑: concentration
d𝜑/dx: concentration gradient across
membranes occurs along membrane
a concentration gradient. J: flux, the amount of gas diffusing per
Gas flows from high to low unit area per unit time.

concentrations.
Concentration gradient
dependent on thickness
Simple diffusion across
body walls does not work
on larger animals.
Mechanism of gas exchange Decreasing concentration
differential between two
flows

Cocurrent exchange
Respiratory medium and
blood flow in the same
direction.
Inefficient exchange rate. Consistent concentration
Countercurrent exchange differential between two
flows
Respiratory medium and
blood flow in opposite
directions.
Efficient exchange rate. CROSSCURRENT FLOW

Crosscurrent exchange
Respiratory medium and
blood flow in oblique
directions.
Oxygen transport

Once diffused across a
surface:
O2 may be transported in
physical solution in plasma
or coelomic fluid or
O2 binds to respiratory
pigment in blood or
coelomic fluid.
Complex of metal and
protein.
Increases the oxygen-
carrying capacity of the fluid.
Respiratory pigments

Three types of respiratory
pigments:
Hemoglobin
Iron-based
Widely found across Bilateria
Hemerythrin
Iron-based
Rare (only in a few invert
Hemoglobin Heme
species)
Found in cells
Hemocyanin
Copper-based
Molluscs and arthropods

Hemocyanin
Gas exchange in vertebrates

Gas exchange in
vertebrates occur
fundamentally in the same
way as in other phyla:
Gas exchange across a
surface between respiratory
medium (water or air) and
blood flow.
Gills
Lungs
Skin (cutaneous
respiration)
Gas exchange in vertebrates

In gill respiration the
flow of water is
unidirectional.
Continuous flow.
In lung respiration the
flow of air is bidirectional.
Intermittent flow
Aquatic respiration in cyclostomes

In larval lampreys, water
is drawn into the mouth
by muscular velum.
Water is driven across
gills, exiting through
pharyngeal slits.
Blood in gill filaments flow
in opposite direction
(countercurrent flow).

Ammocoete larva of lamprey Adult lamprey
Aquatic respiration in cyclostomes

In parasitic adult
lampreys, the mouth grips
its prey, prohibiting water
entering to ventilate the
gills.
Water flows in and out of
the pharyngeal slits.
Muscles of the branchial
apparatus drive this tidal
flow.
Ammocoete larva of lamprey Adult lamprey
Aquatic respiration in cyclostomes

In hagfish, water is drawn
in through the nostrils by
currents generated by the
scrolling and unscrolling
of the velum.
Gas exchange occurs
along the gill lamellae
inside branchial pouches.
Aquatic respiration in
chondrichthyans
In chondrichthyans, each
gill consists of an
interbranchial septum,
covered on each face by
primary lamellae (gill
filaments).
Primary lamellae are
composed of secondary
lamellae.
Aquatic respiration in
chondrichthyans
Ventilation in sharks is
alternating negative and
positive pressures.
Negative pressure drives
water in through the
mouth.
Positive pressure forces
water across the gills.
Aquatic respiration in bony fishes
Water flows in

In bony fishes, each gill is
from the
mouth

V-shaped composed of
primary lamellae and
secondary lamellae. Water
flows over
Water flows in the the gills

opposite direction to the
blood flowing in the
secondary lamellae,
forming a countercurrent
exchange system.
Terrestrial respiration in vertebrates
Respiration in lungfish

Lungfish have lungs, as the
name suggests, and lung
respiration predominates
over gill respiration.
Australian lungfish has a
single lung in a dorsal
position.
African lungfish has paired
lungs.
Lungs subdivided into faveoli.
Gas exchange occurs with
capillaries.
Respiration in amphibians

Amphibians undergo both
gill respiration and lung
respiration in their lifetime.
Amphibian larvae have both
internal and external gills.
External gills are held out in
passing current.
Larval anurans use buccal
and pharyngeal force pumps
to produce unidirectional
flow of water across internal
gills.
Respiration in amphibians

Amphibians lose gills
through metamorphosis.
Adults typically respire
through lungs.
Lungs are ventilated by a
buccal pump.
Respiration in amphibians

Skin is a major respiratory
organ – gases easily
diffuse across the thin
moist skin with rich supply
of capillaries.
Cutaneous respiration
Terrestrial respiration in reptiles

Compression and
expansion of the rib cage
force air in and out of the
lungs.
Internal faveoli increase
surface area for gas
exchange.
Capillaries line the walls of
the faveoli.
Many snakes have only 4: Vestigial left lung
5: Right lung

one lung.
Terrestrial respiration in birds

Birds have a pair of lungs
connected to the trachea
and ventilated by an
aspiration pump.
Birds have a pulmonary
flow-through system
made up of small one-way
passageways, the CROSSCURRENT FLOW
parabronchi.
Airflow is managed by
extensive air sac system.
Terrestrial respiration in mammals

Mammals also have a pair of
lungs.
Mammalian ventilation is Intercostal muscles

bidirectional.
Air is forced in and out
through an aspiration pump,
driven by the rib cage and
diaphragm.
Mammal lungs terminate in
small alveoli lined with
arteries and veins.
Patterns of gas transfer in animals

Mammalian lungs are blind-
ended. Air moves tidally.
Gas exchange involving a uniform
pool.
Avian lungs are flow-through. Air
moves one way.
Blood flows obliquely to airflow.
Crosscurrent gas exchange.
Fish gills are also one-way
systems.
Blood flows in opposite direction to
water.
Countercurrent gas exchange.
Evolution of the vertebrate lungs
Lungs in sarcopterygians
True paired lungs are only
found in tetrapods. Unpaired Unpaired Paired

Unpaired respiratory lungs are ventral fatty dorsal dorsal
lung lung lungs
Paired
found in lungfish. ventral
Dorsal position but opens from lungs

the oesophagus ventrally.
Coelacanths have unpaired
fatty organ that is homologous
to lungs in other
sarcopterygians.
Unpaired ventral lung is
ancestral to Sarcopterygii.
Evolution of the vertebrate lungs
Lungs in sarcopterygians
Actinopterygians (ray-
finned fishes) lack Unpaired
dorsal gas
Unpaired
ventral fatty
Unpaired
dorsal
Paired
dorsal
respiratory lungs but have bladder lung lung lungs
Paired
gas-filled sacs called gas ventral
lungs

(swim) bladders.
Some fish use them for
respiration.
Evolution of the vertebrate lungs
Lungs in sarcopterygians
Which came first, the gas
bladder or the lungs? Unpaired
dorsal gas
Unpaired
ventral fatty
Unpaired
dorsal
Paired
dorsal
bladder lung lung lungs
Paired
ventral
lungs
Evolution of the vertebrate lungs

Polypterids (bichirs), the
basal actinopterygian, Polypterids
have an unpaired ventral have an
unpaired
lung, which they use for ventral lung

respiration.
Evolution of the vertebrate lungs

Polypterids (bichirs), the
basal actinopterygian,
have an unpaired ventral
lung, which they use for
respiration.
Polypterids preferentially
breath through spiracles
at the back of their skulls.
Evolution of the vertebrate lungs

Polypterid lungs are
developmentally Polypterids
homologous to gas have an
unpaired
bladders and ventral lung

sarcopterygian lungs.
Evolution of the vertebrate lungs

Unpaired, ventral lungs
may be ancestral to Polypterids
Osteichthyes (bony have an
unpaired
fishes). ventral lung

Lungs came first!
Then gas bladders
evolved in ray-finned
fishes.
Paired lungs evolved in
tetrapods. Unpaired ventral
lung ancestral
state to bony
fishes?