Invertebrates Notes PDF

Summary

These notes cover various invertebrate phyla, including their characteristics, body plans, and examples. The document details cell specialization, early development, body symmetry, cephalization, and body cavity trends in animal evolution. It also includes detailed anatomical information.

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Invertebrates
Notes #1: Kingdom Animalia: Invertebrates
Notes #2: Phylum Porifera (sponges)
Notes #3: Phylum Cnidaria (cnidarians)
Notes #4: Phylum Platyhelminthes
(flatworms)
Notes #5: Phylum Nematoda (roundworms)
Notes #6: Phylum Annelida (segmented
worms)
Notes #7: Phylum Mollusca (mollusks)
Notes #8: Phylum Arthropoda (arthropods)
Notes #9: Phylum Echinodermata
(echinoderms)
Notes #10: Invertebrate Systems
#1) Kingdom
Animalia:
Invertebrates
 Kingdom Animalia
Characteristics of animals:
eukaryotic cells; lack cell walls
multicellular
heterotrophic
two groups: 1) Invertebrates (no backbone)
2) Vertebrates (backbone)
 Invertebrate Phyla
There are 8 invertebrate phyla:
1) Phylum Porifera (sponges)
2) Phylum Cnidaria (cnidarians)
3) Phylum Platyhelminthes (flatworms)
4) Phylum Nematoda (roundworms)
5) Phylum Annelida (segmented worms)
6) Phylum Mollusca (mollusks)
7) Phylum Arthropoda (arthropods)
8) Phylum Echinodermata (echinoderms)
 Trends in Animal Evolution
Important trends in animal evolution:
1) Cell Specialization
2) Early Development
3) Body Symmetry
4) Cephalization
5) Body Cavity (coelom)
1) Cell Specialization
All the different cell
types are derived from 3
germ layers:
1) Ectoderm – outer
layer
2) Mesoderm –
middle layer
3) Endoderm – inner
layer
2) Early Development
In protostomes the
blastopore becomes
the mouth (most
invertebrates)
In deuterostomes
the blastopore
becomes the anus
(echinoderms and
vertebrates only)
 Cladogram showing
deuterostome evolution
 3) Body Symmetry
Asymmetry – no plane of symmetry
Radial symmetry – multiple planes of
symmetry
Bilateral symmetry – one plane of symmetry
 4) Cephalization
Cephalization – the evolutionary trend towards
a concentration of nerves and sensory organs in
the anterior (head)
 5) Body Cavity
The coelom is a fluid-filled body cavity that
contains the internal organs.

The three stages in the evolution of a body
cavity:
1) Acoelom → 2) Pseudocoelom → 3)
Coelom
 Acoelom
Acoelom:
no body cavity
three germ layers stacked; no space
e.g. flatworm
 Pseudocoelom
Pseudocoelom:
“false” body cavity
partially lined by mesoderm
e.g. roundworm
 Coelom
Coelom:
full body cavity
completely lined by mesoderm
e.g. annelid
#2) Phylum Porifera
(sponges)
 Phylum Porifera (sponges)
Characteristics: Sponge body plan
Latin “poros” = passage germ layers: none
filter feeders (use collar body cavity: absent
cells to trap food particles) body symmetry:
asymmetric
endoskeleton made of
spongin and/or spicules of cephalization: absent
calcium carbonate or silica
amoeboid cells build
spicules and help digest
food
 Sponges – Examples

Venus’ flower basket Bath sponge
Tube sponge
 Anatomy of a Sponge – water
flow
Water flow:
pore (ostia) → central cavity → osculum
#3) Phylum Cnidaria
(cnidarians)
Class Hydrozoa
Class Scyphozoa
Class Anthozoa
 Phylum Cnidaria (cnidarians)
Characteristics: Cnidarian body plan
Latin “cnidaria” = nettles cell layers: two
mostly carnivorous body cavity: absent
tentacles bear stinging
body symmetry:
nematocysts
radial
alternate between polyp and
medusa body forms cephalization:
gastrovascular cavity
absent
(GVC)
hydrostatic skeleton
 Body Forms: Polyp vs Medusa
Polyp – flower-like Medusa – bell-shaped
form; sessile form; free-swimming
(=attached to bottom)
Stinging Cells (cnidocytes) of
the Tentacles
A stinging
nematocyst is ejected
from a cnidocyte cell
when triggered
It immobilizes prey
 Class Hydrozoa

Hydra Portuguese Man-of-War
 Class Scyphozoa

Lion’s Mane Jellyfish Moon Jelly Sea Wasp
 Class Anthozoa

Reef Coral Sea Anemone

Sea Pen Sea Fan
 #4) Phylum
Platyhelminthes
(flatworms)
Class Turbellaria
Class Trematoda
Class Cestoda
 Phylum Platyhelminthes
(flatworms)
Characteristics: Flatworm body plan
Latin “platy” = flat, germ layers: three
“helminth” = worm body cavity: acoelom
unsegmented body symmetry:
free-living or parasitic bilateral
hydrostatic skeleton cephalization:
present
 Class Turbellaria (turbellarians)
Characteristics:
free-living carnivores
and scavengers
live in fresh, salt water,
or on land
move with cilia marine turbellarian
GVC Planaria
example: Planaria,
marine turbellarians
 Anatomy of Planaria

One-opening digestive
tract: Flames cells excrete
mouth → pharynx → GVC
excess water
 Class Trematoda (flukes)
Characteristics:
parasitic
infect blood and organs
life cycle typically involves more than
one host:
primary host – sexual reproduction
occurs
intermediate/secondary host –
liver fluke
asexual rep. occurs
examples: blood flukes (e.g.
Schistosoma Life Cycle
(sequence the stages)
 Class Cestoda (tapeworms)
Characteristics:
internal parasites
lack digestive tract
body composed of many repeating
sections called proglottids
(contain eggs)
the scolex (head) attaches to
host’s
tapeworm
intestines
example: tapeworm
 Anatomy of a Tapeworm
Tapeworm infection
occurs by ingesting
infected meat (with
larval cysts)
 #5) Phylum
Nematoda
(roundworms)
 Phylum Nematoda
(roundworms)
Characteristics: Roundworm body plan
Latin “nemato” = thread germ layers: three
unsegmented body cavity:
digestive system has two pseudocoelom
openings – a mouth and body symmetry:
an anus bilateral
hydrostatic skeleton cephalization:
examples: free-living or present
parasites
 Nematode Digestive System
The two-opening digestive system:
(the first phylum to have this)

mouth → pharynx→ intestine → anus
 Adult Ascarid Worm
Ascarid infection
occurs through
ingesting food or water
containing Ascarid
eggs
Ascarid Worm Lifecycle
(sequence the stages)
 Trichinella
Trichinella infection
occurs from
consuming raw pork
 Eye Worm
Eye worm is
transmitted through
the bite of a fly
#6) Phylum Annelida
(segmented worms)
Class Polychaeta
Class Oligochaeta
Class Hirudinea
 Phylum Annelida (segmented
worms)
Characteristics: Annelid body plan
Latin “annellus” = little ring
germ layers: three
body composed of segments
separated by internal body cavity: coelom
partitions body symmetry:
digestive system has two
bilateral
openings
closed circulatory system* cephalization:
respiration by diffusion present
across skin
hydrostatic skeleton
 Class Polychaeta (polychaetes)
Characteristics:
most live in salt water
pair of bristly, fleshy
appendages on each sandworm
segment
examples: sandworm,
fanworm

fanworm
 Class Oligochaeta
(oligochaetes)
Characteristics:
lack appendages
few bristles
terrestrial or fresh
earthworm
water
examples: Tubifex
(sludge worm) ,
earthworm
Tubifex
 Earthworm Systems
e.g. Nephridia are
kidney-like structures
that excrete
nitrogenous wastes
 Earthworm Digestive System

mouth → pharynx → esophagus → crop → gizzard → intestine →
anus
 Class Hirudinea (leeches)
Characteristics:
lack appendages
carnivores or blood-
sucking external
parasites
most live in fresh
water
example: medicinal leech
leech
#7) Phylum Mollusca
(mollusks)
Class Bivalvia
Class Gastropoda
Class Cephalopoda
 Phylum Mollusca (mollusks)
Characteristics: Mollusk body plan
Latin “molluscus” = soft germ layers: three
four body parts: body cavity: coelom
1) foot
body symmetry:
2) shell (endo- or
exoskeleton) bilateral
3) mantle cephalization:
4) visceral mass present
digestive system with
two openings
Four Body Parts of a Mollusk
(text pg. 586)
 Class Bivalvia
Characteristics:
two-part hinged shell
wedge-shaped foot
typically sessile as
clam oyster
adults
some burrow in mud or
sand
examples: clam, oyster,
scallop, mussel
scallop mussel
 Class Gastropoda (gastropods)
Characteristics:
use broad, muscular foot in
movement
most have spiral,
chambered shells; some snail slug
lack shell
distinct head
aquatic or terrestrial
examples: snail, slug,
nudibranch, limpet
nudibranch
limpet
 Class Cephalopoda
(cephalopods)
Characteristics:
foot is divided into
tentacles
closed circulatory
system* octopus squid
examples: octopus,
squid, nautilus,
cuttlefish
nautilus cuttlefish
Squid Anatomy
#8) Phylum Arthropoda
(arthropods)
Subphylum Trilobita
Subphylum Chelicerata
Subphylum Uniramia
Subphylum Crustacea
 Phylum Arthropoda
(arthropods)
Characteristics: Arthropod body plan
Latin “arthro” = jointed, germ layers: three
“poda” = foot
exoskeleton of chitin body cavity: coelom
jointed appendages body symmetry:
segmented body
bilateral
many undergo cephalization:
metamorphosis during present
development
open circulatory system*
 Subphylum Trilobita (trilobites)
Characteristics:
all extinct (known from
fossil record)
each appendage
divided into a gill and
a walking leg

trilobite
 Subphylum Chelicerata
(chelicerates)
Characteristics:
mouth parts:
chelicerae (1st pair) –
used for biting or sucking
pedipalps (2nd pair) –
horseshoe crab tick
used for prey capture
mite
two-part body –
cephalothorax and
abdomen
lack antennae
examples: horseshoe crab,
tick, mite, spider, tarantula, spider tarantula
scorpion scorpion
Chelicerate Body (e.g. spider)
 Subphylum Uniramia
Characteristics of uniramians:
almost all terrestrial
one pair of antennae
mandibles
examples: centipedes, millipedes, insects
 Centipedes (Class Chilopoda)
Characteristics:
long body consisting of
many segments
one pair of legs per
segment
poison claws for
feeding centipede
carnivorous
 Millipedes (Class Diplopoda)
Characteristics:
long body consisting of
many segments
two pair of legs per
segment
mostly herbivorous
millipede
 Insects (Class Insecta)
Characteristics:
body divided into three
parts – head, thorax,
abdomen
three pairs of legs
one or two pairs of
wings
some undergo
complete
metamorphosis (e.g.
Insect – Three Part Body
 Grasshopper Systems
e.g. Malpighian
tubules are kidney-
like structures that
excrete nitrogenous
wastes
 Grasshopper Respiratory
System
Oxygen enters
through tiny
spiracles and
into tracheal
tubes where it
diffuses directly to
tissues.
 Insect Metamorphosis
Complete Incomplete
metamorphosis: metamorphosis:
 Symbiosis in Arthropods
Symbiosis is a close relationship between two
species
Three types:
1) mutualism – both organisms benefit
2) commensalism – one organism benefits,
the other neither benefits nor is harmed
3) parasitism – one organism harms the
other
 1) Mutualism
Aphids feed the ants and the ants protect the
aphids
 2) Commensalism
Pseudoscorpions hitch a ride by grabbing hold of
flying insects
 3) Parasitism
Parasitic wasps inject their eggs into a host (e.g.
moth larvae)
 Subphylum Crustacea
most are aquatic; salt
water
two pair of antennae
mouth parts called barnacle crayfish
mandibles pill bug
carapace covers
body
e.g. crab, crayfish, pill
bug, water flea, water flea crab
barnacle
 #9) Phylum
Echinodermata
(echinoderms)
 Phylum Echinodermata
(echinoderms)
Characteristics: Echinoderm body plan
Latin “echino” = spiny, germ layers: three
“dermata” = skin body cavity: coelom
deuterostomes body symmetry: radial
water vascular system cephalization:
respiration across skin absent
gills
endoskeleton
 Sea Lilies and Feather Stars
Characteristics:
filter feeders
feathery arms for feeding
and respiration
sea lily
examples: sea lily,
feather star

feather star
 Sea Stars
Characteristics:
star-shaped
carnivorous
bottom dwellers sea star
mouth on lower
surface, anus on top
surface
examples: crown-of
thorns, sea star, sunstar
crown-of-thorns
sunstar
Water Vascular System of Sea
stars

madreporite → stone canal → ring canal → radial canal →
ampulla → tube feet
 Brittle Stars and Basket Stars
Characteristics:
small body disk
most have only five arms
lack an anus brittle star

most are filter feeders or
detritus feeders
examples: brittle stars
and basket stars
basket star
 Sea Urchins and Sand Dollars
Characteristics:
lack arms
body encased in rigid, box-
like covering
sea urchin
covered with spines
most grazing herbivores or
detritus feeders
examples: sea urchin, sand
dollar sand dollar
 Sea Cucumbers
Characteristics:
leathery, cylindrical
body with feeding
tentacles on one end
mostly detritus or filter
feeders
endoskeleton greatly sea cucumber
reduced
#10) Invertebrate
Systems
 Invertebrate Systems
Six major invertebrate systems:
1) skeletal system
2) digestive system
3) circulatory system
4) respiratory system
5) excretory system
6) nervous system
 Skeletal System
exoskeleton endoskeleton
hydrostatic skeleton
Digestive System
Circulatory System
Respiratory System
Excretory System
Nervous System