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Invertebrates II
Phylum: Nemertea
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The ribbon or
proboscis worms
exhibit an acoelomate
body plan but have a
fluid sac that some
suggest may be an
early coelom.
Alimentary canal,
closed circulatory
system and the fluid
sac mentioned above.
Phyla: Nematoda
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Unsegmented, round with
tapered ends
Pseudocoelom
Complete alimentary canal
No Circulatory System
Dorsal and Ventral Nerve
Cord
Longitudinal muscles only
Cuticle
decomposers, agricultural
pests, parasites
Cooperation of Muscles and
Skeletons
Muscles
always
contract
 Muscles
attached in
antagonistic
pairs
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Skeletal Muscles
Muscles are made up
of muscle fibers
 Fibers are made up of
myofibrils
 Myofibrils are made up
of myofilaments
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– thin filaments (actin)
– thick filaments (myosin)
Sliding Filament
Model
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Sacromeres (basic
functioning unit)
– Z lines (border of
sacromeres)
– H zone (center of
sacromere)
– I band (only thin
filaments)
– A band (length of thick
filaments)
Sliding Filament
Model
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During contraction,
thin and thick
filaments slide past
each other
– I band and H zone
decreases in size
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Caused by myosin
head creating cross
bridge with actin
fiber and then
moves by using ATP
Muscle
Control
Tropomyosin
blocks
myosin
binding sites
 Calcium ions
allow cross
bridges to
form
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Muscle Fibers
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Fast Muscle Fibers
– rapid, powerful
contractions
– flight muscle
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Slow Muscle Fibers
– sustain, long
contractions
– adductor muscles
Invertebrate Muscles
 Flight
muscles in insects are capable
of independent contractions
– wings beat faster than action potentials
 Clam
muscles contain paramyosin
that allows them to remain
contracted with little energy
 Nematodes only have longitudinal
muscle that gives them their
characteristic movements
Ancylostoma
 Hookworm
(burrows
into skin
and moves
to
intestine)
Enterobius
 Pinworm
(pick up
eggs from
anus or
dust with
eggs)
Ascaris
 Human
in food)
roundworm (pick up eggs
Trichinella
 Trichina
worm (pick up from
infected muscle in pork)
Wuchereria
Causes
elephantiasis
 blocks lymph
channels
 pick up from
mosquitoes
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Phylum: Arthropoda
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Hard exoskeleton,
segmented
Segments carry paired
appendages
Open circulatory
system
Alimentary Canal
Complex Muscular
system
Nervous system
similar to annelids
Malphigian Tubules for
excretion
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Skin, Gills, Trachaea
or Book lungs for
respiration
Contains two-thirds of
all identified species
Arthropod Diversity
 Versatile
exoskeleton
 Segmentation and appendages
 Tracheae
 Highly developed sense organs
 Complex behavior patterns
 Metamorphosis
Invertebrate Structures
Malpighian
Tubules
 Open into the
digestive tract
 Osmoregulation
and excretion
 Insects and
terrestrial
arthropods
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Conditions for Respiratory
Surfaces
 Large
 Thin
 Moist
surface area
Aquatic vs. Terrestrial
Less than 1%
oxygen
 Oxygen amounts
decrease as the
temperature
increases
 Aquatic animals
use large amounts
of energy to obtain
oxygen (20%)
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About 21% oxygen
 Developed
invaginations to
increase surface
area and decrease
evaporation
 Terrestrial animals
may use only 1% 2% of its energy to
obtain oxygen
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Respiratory Surfaces
 Cutaneous
Respiration
 Gills
 Tracheal
 Lungs
Systems
Cutaneous Respiration
 Direct
diffusion of gases between the
organism and the environment
 Found in Porifera, Cnidarians,
Platyhelminthes, nematodes, and
some annelids
 Supplements other organisms
Gills
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Found in
echino-derms,
mollusks,
annelids,
arthropods,
some
vertebrates
Tracheal Systems
Found in arthropods
 Tracheae
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– open tubes
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Spiracles
– openings
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Tracheoles
– contact with cells
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Muscle
– increase amount of
Carbon Dioxide
removed
Tracheal Systems
Diffusion Lungs
 Found
in invertebrates
 Gas moved primarily by diffusion
– may be increased by body movement
 Modifications
– snails - cavity with gill modified into
lung
– scorpions and spiders - invaginations of
the abdomen (Book Lungs)
Sensory Receptors
 Mechanoreceptors
 Pain
Receptors
 Thermoreceptors
 Chemoreceptors
 Electromagnetic Receptors
Sensory Receptors
Mechanoreceptors
 Pain Receptors
 Thermoreceptors
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Sensory Receptors
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Chemoreceptors
Evolution of the
Eye
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Complex eyes
have developed
many times
Evolution of the
Eye
 All light-sensitive
organs rely on
photoreceptor
systems employing a
family of proteins
called opsins.
Further, the genetic
toolkit for positioning
eyes is common to
all animals: the PAX6
gene controls where
the eye develops in
organisms ranging
Photoreceptors
Eye cups (ocelli)
- light detection
 Genetic basis
that started as a
light detector
600 mya
 During the
Cambrian
explosion
around 540 mya
two types of
eyes arose
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Photoreceptors
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Compound Eyes made up of
ommatidia that
helps detect
movement
Arthropod Classification
 Subphylum:
Trilobita
 Subphylum: Cheliceriformes
– Class: Merostomata (Horseshoe
crabs)
– Class: Pycnogonida
– Class: Arachnida (Scorpions,
Spiders, Ticks, Mites)
Arthropod Classification
 Subphylum:
Crustacea
– Class: Crustacea (Lobster, Crabs,
Shrimp)
 Subphylum:
Myriapoda
– Class: Chilopoda (Centipedes)
– Class: Diplopoda (Millipedes)
– Class: Insecta (Insects)
Subphylum: Trilobita
All extinct
(Permian era - 250
mya)
 Segmented without
specialization
 Paired appendages
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Subphylum: Cheliceriformes
 Six
pairs of appendages
– one pair of chelicerae
– one pair of pedipalps (not in
horseshoe crabs)
– four pair of walking legs
 No
mandibles
 No antennae
Class: Merostomata
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Six pairs of
appendages
– one pair of
chelicerae
– five pair of
walking legs
Unchanged since
the triassic period
 Shallow coastal
waters
 Larvae similar to
trilobites
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Class: Pyconogonida
Called Sea
spiders (not
true spider)
 May have
extra legs
(duplicate
segments)
 Polar oceans
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Class: Arachnida
Class: Arachnida
 Scorpions
are the first terrestrial
invertebrates
– pedipalps modified as pinchers
– tail modified with stinger
 Ticks
and Mites are parasitic
 Spiders contain modified chelicerae
– used as fangs to inject poison
– produce silk used for webs, eggs,
escape, courtship
Subphylum: Crustacea
Subphylum: Crustacea
 Contain
two pair of antennae
 Each appendage is biramous (two
main branches)
 Mandibles
 Body of two or three parts
 Mostly marine
Subphylum: Myriapoda
Subphylum: Myriapoda
 Contain
one pair of antennae
 Each appendage is uniramous (one
main branch)
 Mandibles
Classes: Chilopoda &
Diplopoda
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Chilopoda
– Centipedes
– one pair of jointed
legs per segment
– poison claws
– predators
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Diplopoda
– Millipedes
– two pair of jointed
legs per segment
(fused)
– herbivores
Class: Insecta
Most diverse of all
arthropods
 May have been the
cause of
angiosperm
diversity
 Metamorphosis
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– complete
– incomplete
Coleoptera – Beetles
Two pairs of
wings, one
thick, the
other
membranous
 Chewing
mouth parts
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Diptera – True Flies
One pair of clear
wings
 Sucking mouth
parts
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Lepidoptera –
Butterflies & Moths
Two pairs of wings
with scales
 Long proboscis
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Hemiptera – True Bugs
Two pairs of wings,
one half wing
(thick in front,
membranous in
back) and the
other membranous
 Piercing or sucking
mouthparts
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Homoptera – Cidadas, Aphids
Wings held
roof-like over
body
 Piercing –
sucking mouth
parts
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Hymenoptera –
Ants, Bees, Wasps
Two pairs of
membranous wings
 Thin waist
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Odonata – Dragonflies
Long, narrow
membranous
wings
 Long,
slender body
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Orthoptera
Large Hind legs for
jumping
 Two pairs of wings
(one leathery, one
membranous)
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Phylum: Echinodermata
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Deuterostomes
– radial and
indeterminate
cleavage
– Enterocoelous
– anus from
blastopore
Phylum: Echinodermata
Secondary Radial
Symmetry
 Water vascular
system
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– Ambulacral groove
– Madreporite
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All marine
Water Vascular System
Madreporite
 Stone Canal
 Ring Canal
 Radial Canal
 Lateral Canal
 Ampulla
 Tube Feet
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Classification
 Class:
Asteroidea (Seastars)
 Class: Opiuroidea (Brittlestars)
 Class: Echinoidea (Sea Urchins,
Sand Dollars)
 Class: Crinoidea (Sea Lilies)
 Class: Holothuroidea (Sea
Cucumbers)
Class: Asteroidea
Five arms radiating
from a central disc
 Open ambulacral
groove
 Madreporite on the
aboral side
 Contain
pedicellariae or
papulae
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Class: Ophiuroidea
Five thin arms
radiating from a
central disc
 Closed ambulacral
grooves
 Madreporite on the
oral side
 No suckers on tube
feet, pedicellariae
or papulae
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Class: Echinoidea
No arms but have
five rows of tube
feets
 Contain spines
 Closed ambulacral
grooves
 Madreporite on the
aboral side
 Contain pedicellariae
or papulae
 Aristotle’s lantern
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Class: Crinoidea
Attached to
substrate with
many branched
arms
 Open ambulacral
grooves
 No Madreporite
 No pedicellariae or
papulae
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Class: Holothuroidea
Soft bodied
 Ambulacral areas
with tube feet
 Internal
Madreporite
 No pedicellariae
or papulae
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