Mollusca BIO205 PDF

Summary

This document provides an overview of the Phylum Mollusca, covering its characteristics, diversity, and various classes. It details the features such as the radula, mantle, and circulatory system. The document also discusses the digestive and excretory systems and the nervous system of molluscs.

Full Transcript

Phylum Mollusca
Chapter 10
 METAZOA
Bilateria
Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

Trochophore larva
Mouth formed from
blastopore, etc. (Org. & Syst. level)

Gastrulation Bilateral symmetry
Diploblasty Cephalization
Triploblasty
Multicellularity
Blastulation
Mollusca

Spiral cleavage
Mosaic embryo

Blastopore
becomes mouth Triploblasty
Bilateral symmetry
Cephalization
Reminder: Body cavities (gut + cavity around the gut)

Through embryonic development, the blastocoel of triploblasts can:
c) be replaced by the true coelom (cavity forms inside the mesoderm)

Triploblastic coelomate

A true coelom found in earthworms, molluscs, chordates and most phyla (15-
20)
Reminder: Body cavities (gut + cavity around the gut)

Through embryonic development, the blastocoel of triploblasts can:
c) be replaced by the true coelom (cavity forms inside the mesoderm)

A true coelom found in earthworms, molluscs, chordates and most phyla (15-
20)
 Phylum Mollusca

“Soft animals”
90K named living spp.; 70K fossil spp.
Very important size range
Majority free-living, few parasites
Ecologically diverse, marine, freshwater,
and terrestrial
Filter-feeders, carnivores and
herbivorous grazers
Mono or dioecious, w/without
copulation
 Phylum Mollusca

Diverse body plans reflecting diverse lifestyles
Ex: variable degrees of cephalization
Ex: presence or absence of calcium carbonate shell

Squids
Chitons Snails Clams
Octopuses
Slugs Oysters
Nautiluses
Mussels
Cuttlefishes
 “Generalized” mollusc
2 main body parts: head-foot and visceral mass
- Feeding
- Digestion
- Locomotion
- Circulation
- Sensory organs
- Respiration
- Reproduction
 Phylum Mollusca

Synapomorphies:
1) radula: rasping organ used in feeding
(lost in bivalves)
 (supporting cartilage)

Ribbon-like
Radula membrane

à Treadmill (or
Rasping, protrusible, tongue-like escalator)
organ

In all molluscs except bivalves
 Phylum Mollusca

Synapomorphies:
1) radula: rasping organ used in
feeding (lost in bivalves)

2) mantle: sheath of skin
extending from dorsal body
wall. Mantle secretes the
shell and forms mantle cavity
housing gills (or lungs)
Mantle and mantle cavity
Mantle and mantle cavity
Mantle and mantle cavity
 Phylum Mollusca
Synapomorphies:
1) radula: rasping organ used in feeding
(lost in bivalves)
2) mantle: sheath of skin extending from dorsal
body wall and secreting shell
also forms mantle cavity à houses gills (or lungs).
 METAZOA
Bilateria
Protostomia Deuterostomia
Lophotrochozoa Ecdysozoa

choanofla
gellates sponges cnidarians molluscs annelids flatworms nematodes arthropods echinoderms chordates

Radula & mantle

Trochophore larva
Mouth formed from
blastopore, etc. (Org. & Syst. level)

Gastrulation Bilateral symmetry
Diploblasty Cephalization
Triploblasty
Multicellularity
Blastulation
Diversity of body plans

MANTLE
CAVITY

GASTROPODS
CHITONS
Diversity of body plans

MANTLE
CAVITY

GASTROPODS
CHITONS
Diversity of body plans

MANTLE
CAVITY

GASTROPODS
CHITONS
Diversity of body plans

MANTLE
CAVITY

GASTROPODS
CHITONS
Diversity of body plans

MANTLE
CAVITY

GASTROPODS
CHITONS
 Phylum Mollusca
Digestive system:
Complete
Complexe
Highly specialized for specific feeding habits
Extracellular digestion in stomach, absorption in intestine
 Phylum Mollusca

Reduced coelom
Open circulatory system = pericardiac cavity
(closed in cephalopods)
3 chambered heart
1 muscular ventricle
2 atria
Simple
Open
 Phylum Mollusca
Circulatory system:
3 chambered heart
1 muscular ventricle
2 atria
Simple
Open

Circulatory system &
coelom are fused
= Hemocoel

Hemocoel

Bivalves
Gills
 (sinus = cavity or space in
tissues)

Few open ended vessels
Organs bathed directly in blood Blood entirely enclosed in vessels
(hemolymph) Exchange with organs through capillary
Large sinuses form hemocoel (cavity) beds
Blood circulation slow = less efficient Blood circulation fast = more efficient
25
 Phylum Mollusca

Respiratory system:
Most have gills (or lung) linked to
circulatory system for gas
exchange
Water flow over gills created by
movement of gill cilia
Importance of the mantle
cavity:
Protects gills
Keeps humidity
Mantle also involved in gas exchange

Note: mantle is also involved in passive gas
exchange
Phylum Mollusca

Gills
Oxygen exchange between water and gill

(% indicate saturation levels)
Oxygen exchange between
water and gill

Most gills are designed so that the flow of water over the
surface runs in the direction opposite to blood flow (counter-
current exchange)
Oxygen exchange between water and gill

30
Oxygen exchange between water and gill
 Phylum Mollusca

Excretory system:
1 pair of metanephridia.
Nephridiopore
More complex and efficient
than protonephridia of
Platyhelminthes (controls
osmolarity and nitrogenous
wastes)
Note: mantle is also
involved in excretion
Platyhelminthes protonephridium

Protonephridium:
a type of primitive
nephridium.

Wastes = ammonia (NH3)
Nitrogenous wastes

Ammonia Urea Uric acid
NH3 CO(NH2)2 C5H4N4O3

Most toxic Least toxic

Platyhelminthes
Molluscs (most)
 Excretory system (Mollusca)

Metanephridium: a
type of nephridium in
which the inner end
opens into the coelom
Waste = ammonia (NH3)

1 of a pair of metanephridia
 Phylum Mollusca
Nervous system:
Many pairs of ganglia, connected by nerve cords
Many specialized sensory organs
Cephalization in some
 Reproduction

Most dioecious (some monoecious, especially in Gastropoda)
Life cycle direct or indirect

Zygote
(fertilized egg)

immature
adult
 Reproduction

Most dioecious (some monoecious)
NO asexual reproduction
Life cycle direct or indirect
 Reproduction

Most dioecious (some monoecious)
Life cycle direct or indirect
No asexual reproduction (few
exceptions in Gastropoda)
With or without copulation
Mollusc classes

Class Solenogastres Class Polyplacophora Class Gastropoda Class Cephalopoda

Class Caudofoveata Class Monoplacophora Class Bivalvia Class Scaphopoda
Animalia
Molluscs
Gastropoda, Cephalopoda, Bivalvia, Polyplacophora
42
43
 Class Polyplacophora

800 marine, most shore dwellers
Shell forms 7-8 plates
2 lateral mantle cavities with
gills
Use radula to scrape algae off
rocks
Mostly dioecious with
trochophore larva, no
copulation (external
fertilization)
Trochophore larva
juvenile
nacre

45
 Class Gastropoda

70 K living species
Marine, freshwater, terrestrial
Mostly monoecious with
copulation, trochophore larva
present in most
Shell present, reduced or lost
Most secondarily asymmetrical
due to torsion
Gastropoda

Torsion: twisting of visceral mass, nerve cord and mantle
cavity relative to foot and head

Generalized mollusc Gastropods

47
Torsion: twisting of visceral mass, nerve cord and
mantle cavity relative to foot and head

Mouth Mouth
Anus

Mouth Anus Mantle
Anus cavity

Advantage: head can be retracted first

Problem?: FOULING
Gastropoda

Coiling

FOULING

49
Gastropoda

Coiling:
Leads to more compact,
efficient use of space
Animal becomes bilaterally
asymmetrical
In this case, the gills and
metanephridium are lost on
the right side

Reduces fouling problem

Some taxa have ‘’detorted’’
(ex: sea slugs)
50
Gastropoda

Anus
Gill

Water flow

51
 Digestive system
Radula
Herbivorous
Rasping algae from substrate
Break off pieces of seaweeds Moon snail
Naticarius orientalis
Scavengers
Carnivorous
Gas exchange in terrestrial gastropods
 Gas exchange in sea slugs

Some have lost their gills:
Gas exchange through skin
Highly ramified body surface
Why?
 Reproduction in Gastropoda

Mostly monoecious with copulation

Mollusc video #3: https://www.youtube.com/watch?v=wG9qpZ89qzc
56
 Squid Nautilus
Class
Cephalopoda

Octopus Cuttlefish
Class Cephalopoda
= head and foot
600 marine species
2-3 cm to 18m

Giant squid
 Class Cephalopoda

600 marine species
All predaceous with radula and jaws, some with
poison glands
Dioecious with “copulation”, direct development
Shell external and coiled in nautilus, internalized
or absent others
Very active animals (mostly pelagic)
Closed circulatory system
Largest invertebrate brain, complex eyes
Cephalopod body plan

Anterior view
Cephalopod body plan

(= gill)

Lateral view
Cephalopoda Predators à digestive and nervous system

62
Digestive system à Predators

Mouth:
- Strong beaklike jaws
- Radula in the middle to tears off pieces of flesh
Digestive system à Predators

Arms:
- Complex musculature
- Used to catch and manipulate preys
- Used for locomotion in octopuses
 Class Cephalopoda

Very active animals
Closed circulatory system
Swim by forcing water from mantle cavity
through a funnel
Systemic
heart
 Class Cephalopoda

“Smart” animals
largest invertebrate brain
complex eyes
visual communication
Cephalopoda Parallelism between cephalopod and
vertebrate eye
convergent evolution

cornea
iris blind spot
lense retina

67
 Parallelism between cephalopod and vertebrate eye
convergent evolution

Outgrowth of
the brain

cornea
iris blind spot
lense retina

Ingrowth of
epidermis
Skeletal system à Where is the shell?

Shell:
- Ancestor had a shell
Skeletal system à Where is the shell?

Shell:
- Ancestor had a shell

Lost in some Coiled in some
(octopuses) (nautiluses)
Skeletal system à Where is the shell?

Shell:
- Ancestor had a shell
pen

Internal in some
(squids)
 Space filled
Cephalopod shell with gas

Nautilus internal anatomy

72
 Squid copulation

Dioecious with copulation
zygote
Direct development
immature adult
Paul the Octopus
Soccer Oracle 2008-2010
75
 Class Bivalvia

8K aquatic species
Most are sessile filter feeders;
benthic habitats
No radula, reduced
cephalization
Two shells (valves) hinged
dorsally, held shut by adductor
muscles
Animal laterally flattened
between two valves
Most dioecious, no copulation
Bivalve body plan
Bivalve body plan

Dorsal

Ventral
Bivalvia Filter feeders à Respiratory / Digestive system:
Dorsal
Right valve
Posterior
adductor muscle

Posterior
TWO OPENINGS

Anterior

Ventral
79
Lateral view of left side of freshwater clam
Bivalvia
Excurrent
Incurrent
siphon
siphon

80
Bivalvia
Digestive system:

81
Left mantle and gill removed
Bivalvia Generalized bivalve reproduction

External fertilization

Gametes shed
through
excurrent
opening

Most dioecious, no copulation 82
Bivalve sensory structures

Aequipecten irradens
 Phylum Mollusca
What’s new:
Circulatory system more complex
Heart more complex (ventricle & 2 atria)
Complete digestive tract, with stomach
Respiratory system more complex, with gills
Cephalopoda:
Most complex brain in in vertebrates
Closed circulatory system
Complex muscular system

Skeletal system ?