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3/25/11
Invertebrates I
•  Porifera
•  Radiata
PORIFERA: The sponges
•  ~9,000 species
•  Position within Animalia is
under debate:
•  Ancient Animals?
•  Once considered as
subkingdom Parazoa and
sister taxon to Eumetazoa.
•  Recently considered a
paraphyletic grade, with one
group more closely related to
Eumetazoans than others.
PORIFERA:
The sponges
•  Position within Animalia is
under debate:
•  Secondarily simplified?
•  Recent (2008) study of
150 genes found
Ctenophora (comb jellies)
sister to all remaining
animals
•  Hypothesized that
sponges are not primitive,
but secondarily simplified
–  Lost tissues and other
Eumetazoan
characteristics from their
common ancestor
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PORIFERA:
The sponges
•  Position within Animalia is
under debate:
•  Or monophyletic?
•  Or even MORE recent:
–  Philippe et al. 2009, Current
Biology
•  128 genes
•  Sponges monophyletic
sister taxon to the Metazoa.
PORIFERA: The sponges
• 
• 
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• 
Regardless, very simple
animals.
No true tissues or
organs
Body is a perforated
sac surrounding the
spongocoel (internal
cavity)
Two layers a loose
aggregate of cells
–  Epidermis
–  Choanocytes (collar
cells)
• 
Between layers is
mesohyl
PORIFERA: The sponges
• 
• 
• 
Collar cells move
large volumes of
water through body
pores by their
beating flagella.
They also trap
suspended food
particles in their
microvilli collars.
Within mesohyl are
Amoebocytes which
transport food
particles and/or
produce Calcium
Carbonate (CaCO3)
spicules for support.
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PORIFERA: The sponges
•  Are very sessile
(immobile) filter
feeders.
•  98% marine, some
freshwater
PORIFERA: The sponges
• 
Reproduction
Hermaphroditic: each
individual functions as male &
female
–  Often sequential hermaphrodite
• 
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• 
Sperm and eggs develop from
choanocytes & amoebocytes in
mesohyl
Sperm expelled into spongocoel
then out
Eggs reside and are fertilized in
in mesohyl
Zygote  Flagellated freeswimming larva  disperse 
settles  adult
Also, can regenerate, repair,
and have asexual reproduction
The Eumetazoa
•  “True multicellular
animal”
•  Generally considered
monophyletic, complex,
true tissues
–  Diploblastic &
Triploblastic
•  Most hypotheses
consider Radiata
(Ctenophora + Cnidaria)
as a paraphyletic grade
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The Eumetazoa
•  Recent
phylogenomic
study calls this
into question
•  Eumetazoa no
longer a
monophyletic
group
The Eumetazoa
•  Or…
•  Metazoa monophyletic
AND Coelenterata/
Radiata (diploblasts)
monophyletic
Ctenophora: Comb Jellies
•  ~100 species
•  Transparent, all marine
•  1-10 cm, spherical/ovoid,
some elongate to 1 m
•  8 rows of ciliated comblike plates for locomotion:
Ctenophora = “comb
bearer”
•  Long retractible tenticles
with colloblasts for food
capture
•  Superficially (?) resemble
Cnidaria, relationships
under debate
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Cnidaria:
Hydras, jellies, anemones, corals
• 
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• 
General
Diploblastic (what germ layer do
they lack?)
Radial symmetry
Basic body plan: sac with
central gastrovascular cavity
–  One opening for both entrance
and exit of food
• 
Two forms:
–  Polyp: sessile sac with
tentacles upward
–  Medusa: free-swimming, sac
and tentacles downward
• 
• 
Independent as either OR
Medusa dispersal stage and
settled polyp stage
Cnidaria:
Hydras, jellies, anemones, corals
Feeding
•  Carnivorous
•  Tentacles armed with
cnidocytes
–  Specialized cells with
nematocysts (stinging
capsules)
•  Response system made of
of simple contractile fibers
linked to nerves
•  Gastrovascular cavity a
hydrostatic skeleton
–  Simple nerve net detects,
responds to stimuli,
changes shape
Cnidaria: Diversity
Anthozoa
Scyphozoa
Cubozoa
Hydrozoa
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Cnidaria: Diversity
• 
• 
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• 
Hydrozoa: Hydra,
Obelia
Mostly marine, some
freshwater (e.g.
Hydra)
Polyp & medusa
Just polyp
Just medusa
Cnidaria: Diversity
Scyphozoa: Jellies
•  All marine: medusa
prominent stage in life
cycle
•  Many are
bioluminescent
•  Nematocysts in hunting
tentacles
•  Food moved to
gastrovascular cavity by
unarmed tentacles
Cnidaria: Diversity
Cubozoa: Box jellies
•  These are THE
nasties!
•  Known for their toxic
venom
•  Complex eyes
embedded in
ectoderm of medusa
•  Main prey item of
many sea turtles
•  All marine
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Cnidaria: Diversity
Anthozoa:
Sea anemones & Corals
•  All marine
•  Exist only as polyps
•  Many corals are colonial
& secrete hard external
skeleton of calcium
carbonate
–  Reef builders
Bilateria
•  Bilateria STRONGLY
supported as
monophyletic
•  Bilateral symmetry
•  Triploblastic
development
•  All non-Bilateria hox
genes homologous with
“posterior” hox gene
cluster in Bilateria
•  “Anterior” hox gene
cluster is only found in
Bilateria
Bilateria
•  Protostomes consist of
two major clades
(supported in large
genomic survey):
–  LOPHOTROCHOZOA
–  ECDYSOZOA
•  Lophotrochozoa
contains the most phyla
and the highest
diversity of body plans
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Platyhelminthes: Flatworms
•  ~25,000 species
•  Protostomes
–  Triploblastic
–  Bilateral
–  Spiral cleavage
•  BUT lack a coelom
–  This is a loss of a
body cavity
–  One of 3 bilaterian
phyla with no coelom
Platyhelminthes: Flatworms
•  Cephalization present
–  Unidirectional movement
•  Complex tissues in
mesoderm
–  Organs, true muscle
tissue
•  Unidirectional
gastrovascular cavity
(one opening)
Platyhelminthes: Flatworms
•  Dorso-ventrally flattened
•  All tissues readily exposed
to external environment
–  No need for complex
vascular or excretory
system
–  Osmotic balance
maintained via
protonephridia
–  Flame bulbs pull fluid
through branched openings
to outside
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Platyhelminthes: Flatworms
DIVERSITY: 4 classes
Turbellarians: Free-living flatworms
Trematodes: Blood flukes
Cestodans: Tapeworms
Monogeneans: Gill flukes
Platyhelminthes: Flatworms
DIVERSITY
Turbellaria
•  Free-living flatworms
•  Mostly marine but
include common
freshwater such as
planarians
•  Carnivores or
scavengers
(carrion): Active
lifestyle
Platyhelminthes: Flatworms
DIVERSITY
Turbellaria
•  Move by ventral cilia
gliding over mucous
•  Head with eyespots
•  Lateral flaps for smell
•  Nervous system more
complex than Radiata
•  Asexual reproduction
through constriction
•  Sexual reproduction:
hermaphrodites
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Platyhelminthes: Flatworms
DIVERSITY
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Trematoda &
Monogenea
Flukes
ALL parasitic
Life cycle rotates
between sexual and
asexual reproduction
Usually requires an
intermediate host
Trematodes: Vertebrate
blood/liver
Monogeneans: Fish gills
Platyhelminthes: Flatworms
DIVERSITY
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Trematoda &
Monogenea
Blood fluke Schistosoma
(causes schistosomiasis)
Intermediate snail host infected
by free-living larvae
Reproduce asexually within
snail, produce 2nd larval stage
Larvae penetrate skin
Migrate to lung via veins,
develop more
Migrate to liver, complete
development: sexual
reproduction
–  Females reside in groove
(gynaecophoric channel) of
male worm
Platyhelminthes: Flatworms
DIVERSITY
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Cestoda
TAPEWORMS!
Parasitic flatworms, adults reside in vertebrates
Head with suckers and hooks: Scolex
Allows tapeworm to adhere to intestinal lining
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Platyhelminthes: Flatworms
DIVERSITY
• 
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Cestoda
Body made up of segments
called proglottids
Each is just a sac of sex organs
No digestive system (food
predigested by host): simply
absorbs food across body wall
Mature proglottids are full of
fertilized eggs and break off
from posterior end  released
in feces  contaminate water
 picked up by pigs, cows, etc.
 encysts in muscle tissue 
undercooked meat results in
human infections
Longest human
tapeworm: 11.2m
Longest tapeworm:
37m from a whale
Lophophorates
Ectoprocta (Bryozoans), Brachiopods
• 
Distinguished by lophophore
–  Circular fold of body wall
bearing ciliated tentacles that
surround the mouth
–  Used in filter feeding
• 
• 
Molecular phylogeny favors
protostome affinity, but
embryonic development more
similar to deuterostomes
Pseudocoelomates
Lophophorates
Brachiopods
•  “lampshells”
•  ~330 species, all
marine
•  Resemble Bivalves
(clams) but shell halves
dorsal/ventral, attached
by stalk to substratum
•  Very important fossils:
~30,000 species
Paleozoic, Mesozoic
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MOLLUSCA
•  True coelom (body cavity
enclosed by mesoderm)
•  Obvious protostome
development
•  Snails, slugs, oysters, clams,
octopus, squid
•  50,000 species, 8 classes
MOLLUSCA
•  Most marine, some fresh
water, some truly
terrestrial
•  Soft bodies,
unsegmented
•  Protected by hard shell of
Calcium carbonate
(CaCO3), secondarily lost
in some taxa
•  Larva a trochophore
•  Body plan: visceral mass,
mantle, mantle cavity,
muscular foot.
Molluscan classes
Cephalopoda
Scaphopoda
Gastropoda
Bivalvia
Polyplacophora
(Sigwart, J.D., and Sutton, M.. 2007. Proc. R. Soc. B 274: 2413–
2419; N.G. Wilson et al. 2010. Mol. Phyl. Evol. 54: 187-193)
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MOLLUSCA: Polyplacophora
•  Chitons
•  Marine, oval, shell
divided in 8 plates
•  Intertidal, clinging to
rocks with foot
•  Scrape algae with
radula
MOLLUSCA: Gastropoda
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Snails, slugs
40,000 species, most
species-rich class of
Mollusca
Spiralled shell in most
Flat shell in abalones and
limpets
Slugs, nudibranchs lack
shells
Often distinct heads, eyes
on retractable stalks
Radula for grazing, some
use it for boring holes,
predacious
MOLLUSCA:
Gastropoda
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Embryonic torsion
Visceral mass rotates 180°,
anus, mantle above head
Evolved in concert with a shell
with a single opening
Gastropods with secondarily
lost shell (slugs) have detorted.
–  Untwisted
–  Maintain vestige of ancestral
twist
–  One set of gills
–  Anal papillae and gills
functionally related
–  Gills have secondarily evolved
at other structures
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MOLLUSCA:
Bivalvia
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Clams, oysters, mussels scallops
~30,000 species
Shell divided in half (fundamentally
dorsal), hinged mid-dorsally,
connected by adductors
Mantle cavity has gills for gas
exchange, feeding
–  Gill serves dual function
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Sedentary: muscular foot for anchor
HOWEVER, some can dig very
quickly and scallops can swim
NO RADULA
Mollusca: Scaphopoda
•  Tooth shells or tusk
shells
•  Open end ‘tooth’ or‘tusk’
shell
•  Mouth with grinding
radula
•  Tentacles used for
grasping substrate and
collecting detritus/prey
•  Tentacles shared with
Cephalopods
MOLLUSCA:
Cephalopoda
•  Octopus, squid, cuttlefish,
chambered nautilus
•  ~800 species, all marine
•  Most <75cm; largest
17m, 2 ton squid
•  Characterized by their
speed and rapid
movement
•  PREDATORS with beaklike jaws surrounded by
long tentacles
•  Inside mouth is rasp-like
radula
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MOLLUSCA:
Cephalopoda
•  Shell present in fossil
cephalopods (e.g.
ammonites) and extant
nautilus
•  Shell internalized in most
squids and some octopuses.
•  Shell lost in most octopuses
•  Squid movement backward
via water jets from mantle
cavity modified as muscular
cavity
MOLLUSCA:
Cephalopoda
•  Only molluscs with
closed circulatory
system
•  Well-developed
brain, nervous
system, sense
organs.
•  Complicated, imageforming eye.
Annelida: Segmented worms
•  ~15,000 species
•  Marine, freshwater,
terrestrial
–  Some unsegmented
phyla (e.g. Echiura and
Sipuncula) now included
within Annelida
•  1mm to 4m (giant
Gippsland earthworm)!
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Annelida: Segmented worms
Morphology
•  Segmented body
•  Coelom
partitioned by
septa (singular
septum)
•  Digestive tract,
nerves, vessels
continuous
through septa.
Annelida: Segmented worms
Morphology
•  Digestive tract:
– 
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Pharynx
Esophagus
Crop
Gizzard
Intestine
•  Circulatory system:
–  Blood with hemoglobin
–  Pumping muscles
•  Excretory system:
–  Segmented
metanephridia
•  Nervous system:
–  Cerebral ganglia
–  Ventral nerve cord
•  Respiratory system
–  Cutaneous respiration
Annelida: Segmented worms
Movement
•  Burrowers, some can
swim
–  Creep by longitudinal,
circular muscles
working against fluidfilled coelom as
hydrostatic skeleton
–  This contracts and
elongates segments
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Annelida: Segmented worms
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Reproduction
Hermaphroditic (Hirudinea &
Oligochaeta), separate sexes
(Polychaeta), cross fertilization
Sperm stored in clitellum;
cocoon in clitellum houses
eggs
Trochophore larva in
Polychaeta
Embryonic worm in terrestrial
Hirudinea & Oligochaeta
Some asexual reproduction via
fission
–  In some, posterior end breaks
off, develops into new
individual
–  In others, penis breaks off,
develops into new individual
Annelida: Oligochaeta
•  Typical earth worms and
some aquatic forms
•  Primarily detritivores
•  Eats through soil or mud,
undigested material and
mucus egested as casts
•  Important soil-enhancement
animals.
Annelida: Hirudinea
•  Leeches
•  Primarily freshwater, but also
some terrestrial forms
•  1-30cm
•  Many haemophagic (bloodfeeding)
–  Secrete anticoagulants
–  Important in medicine
•  Many predacious
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Annelida: Polychaeta
•  Bristle worms (and
many other names)
•  Mostly marine
–  Drift passively or crawl
–  Tube (fanworms) burrow,
make shell of mucous
and sand
–  Each segment with
paired parapodia
(extended area of skin)
for locomotion, filter
feeding, and gill function.
Bilateria
•  Protostomes consist of two
major clades (supported in
large genomic survey):
–  LOPHOTROCHOZOA
–  ECDYSOZOA
•  Ecdysozoa contains more
species than all other
groups of multicellular
organisms combined!
Ecdysozoa
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Nematoda
Arthropoda
(and numerous other phyla not
covered in Biology 221)
Protostomes
Proposed as monophyletic
based on DNA sequences
But originally proposed as early
as 1897 (Perrier) because this
includes all animals that shed
their exoskeleton (ecdysis)
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Nematoda: Round worms
•  ~80,000 species
described, this is a
dramatic
underestimate of
actual diversity
•  Possibly the most
numerous animals
•  Pseudocoelomate
Nematoda: Round worms
•  Cylindrical, tapered
body; 1mm - 1m
•  Most aquatic habitats,
damp soil; body fluids &
tissues (plant & animal
parasites)
•  Alimentary canal
•  Food transport via fluid
in pseudocoel
•  Longitudinal muscles,
thrashing movement
Nematoda: Round worms
•  Reproduction usually
sexual
•  Sexes separate,
dimorphic, female larger
•  Fertilization internal
•  Female can lay
>100,000 eggs/day
•  Fertilized eggs are a
resistant zygote
(dormant stage)
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Nematoda: Round worms
•  Caenorhabditis elegans
•  Model organism (like
Drosophila)
•  One of first organisms
with complete genome
sequenced
•  Developmental fate of
every cell mapped (and
mappable!)
Nematoda: Round worms
•  Includes many
important parasites of
humans and agricultural
crops
•  E.g. root-knot nematode
•  E.g. Trichinella spiralis
–  Infects undercooked
meat (especially pork)
–  Encysts in muscle tissue
–  Juveniles develop in
human intestine
ARTHROPODA
•  Nearly 1 million
species
•  The majority are
insects
•  2/3 of all organisms
known are
arthropods
•  The most successful
animal phylum
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ARTHROPODA
General Characteristics
•  Segmentation
– 
– 
– 
– 
Head
Thorax
Abdomen
Tail
•  Exoskeleton-cuticle
–  Protein and chitin
–  Strong armor
•  Defense
•  Desiccation resistance
–  Periodic molting
(ecdysis)
ARTHROPODA
General Characteristics
•  Jointed appendages
–  (arthropod = “jointed feet”)
–  Variously specialized for
locomotion, feeding
•  Well-developed sensory
organs
– 
– 
– 
– 
Cephalization pronounced
Eyes
Olfactory receptors
Antennae in many (touch,
smell)
ARTHROPODA
General Characteristics
• 
Open circulatory system
–  Hemolymph
–  Heart to sinuses to tissues to
heart
–  Sinuses collectively known as
homocoel
• 
Reduced coelom
• 
Gas exchange
–  Hemocoel becomes body cavity
in adults
– 
– 
– 
– 
Diverse mechanisms
Gills
Book lungs
Trachea
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Arthropoda: Diversity
•  Four major extant lineages (subphyla)
–  Chelicerates
–  Myriapods
–  Crustaceans
–  Hexapods
Great Devonian Land Grab
•  One major extinct lineage (subphylum)
–  Trilobitomorpha
Trilobitomorpha: Trilobites
•  Extinct, ~4,000 fossil species
described
•  Shallow marine
environments
•  Common in Paleozoic,
extinct by Permian
•  Relatively unspecialized
body segments
Chelicerata
•  Horseshoe crabs, spiders,
scorpions, mites (& a few
others)
•  Anterior appendages
modifed as pincers, fangs =
chelicerae
•  No antennae
•  Cephalothorax (head and
thorax fused)
•  Simple eyes
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Chelicerata: Eurypterids
•  “Sea scorpions”
•  Extinct
•  Largest known
arthropods to have
ever lived (2m)
•  Marine, predaceous
•  Extinct at Permian
extinction
Chelicerata: Horseshoe crabs
•  “living fossils”
–  Extant forms nearly
indistinguishable
from Jurassic fossils
•  Ocean floor, living
on soft substrate
•  come ashore for
reproduction
Chelicerata: Arachnida
Spiders, scorpions, ticks, mites, harvestmen, others
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Chelicerata: Arachnida
•  Cephalothorax
with six pairs of
appendages
–  Chelicerae
–  Pedipalps
–  Four pairs of
walking legs
•  Book lungs for
gas exchange
•  Webs: silky protein
from spinnerets;
used in feeding,
dispersal
Arthropoda
•  Relationships of Chelicerata to
other groups under considerable
debate.
•  Remaining groups: Myriapoda,
Crustacea, Hexapoda
–  All without Chelicerae, but with
Mandibles
–  All with antennae
–  All with compound eyes
–  Morphology argues for a
monophyletic “Mandibulata”
–  But molecules sometimes suggest
Chelicerata + Myriapoda
(centipedes, millipedes)
Arthropoda
•  Previously, “Mandibulata” were divided
into the Biramia (Crustacea) and
Uniramia (Myriapods + Hexapods)
•  Based on whether appendages are
branched (Biramia) or unbranched
(Uniramia)
–  Upper branch acting as gill
–  Lower branch acting as leg
•  Probably not a good phylogenetic
character: too involved in function.
–  Some Crustacea are uniramous.
Which ones would you guess?
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Myriapoda
Millipedes & Centipedes
•  Terrestrial
•  Diplopoda: Millipedes
–  Wormlike, 2 pair walking
legs/segment (actually one
segment is derived from
two fused segments)
–  Detritus feeders
•  Chilopoda: Centipedes
–  1 pair walking leg/segment
–  Venom claws as first
appendage
Hexapoda
Insects and close relatives
•  >1,000,000 described
species (more than half
are beetles…)
•  Everywhere in terrestrial
environments
•  Rare in marine
environments
•  First fossils in Devonian
(mid-Paleozoic): Oldest
400 mya
•  First winged insects in
Carboniferous 320 mya
Hexapoda
Insects and close relatives
•  Why so diverse???
•  Hypotheses:
–  Intimate associations
with plants (mutualisms &
parasitisms)
–  Flight
–  Compartmentalized body
plans
–  Partitioning of the life
cycle
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Insect Flight
•  Wings not true appendages,
extensions of exoskeleton
•  No appendages given over to
flight (compare to other
winged animals)
Insect Flight
•  Two forms of flight:
–  Direct
–  Indirect
•  Direct flight
–  Ancestral form, found in
Paleoptera: Dragonflies &
Mayflies
–  Muscles directly attached
to wings
–  Very fine control
–  One nerve impulse = one
muscle contraction = one
wing beat
Insect
Evolution
Wings & Flight
Pterygota
Ancestral Direct Flight
Paleoptera
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Insect Flight
•  Indirect flight
–  Flight muscles attached to interior of
thorax (NOT directly to wings)
–  Downstroke is accomplished solely
through the elastic recoil of the
thorax
•  Reduces number of muscle
contractions per wingstroke by half
–  Single nerve impulse required to
initiate muscle contraction, single
impulse to cease.
•  Reduces number of nerve impulses
to muscle contractions immensely.
•  Results in much more rapid wing
beats (up to 1,000 times per second
in some gnats)
•  Derived form found in Neoptera
Insect
Evolution
Wings & Flight
Pterygota
Derived Indirect Flight
Neoptera
Compartmentalized Body Plan
Insect Segments
• 
• 
Three main segments
Head
– 
– 
– 
– 
• 
Segments fused
One pair antennae
Compound eyes
Numerous pairs of appendages
modified for feeding
Thorax
–  Three pairs walking legs
–  Two pairs wings
• 
Abdomen
–  Most of the digestive, respiratory,
excretory and reproductive internal
structures
–  Only appendages used in mating
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Compartmentalized Body Plan
Insect Segments
• 
• 
Internal: Several complex
organs
Nervous system
–  Pronounced cephalization
–  Paired ventral nerve cords
–  Segmented ganglia (minibrain in each segment)
• 
Excretory system
–  Malpighian tubules
–  Remove waste from
hemolymph
• 
Cardiovascular
–  Open circulatory system
with heart
–  Spiracles open to tracheal
tubes, breathe through body
–  Spiracles muscularized to
inhale and exhale
Partitioning of
Life Cycle
•  Most insects sexual,
internal fertilization
•  Many insects mate only
once
•  Juvenile stage unwinged,
can be dramatically
different from adult stage
–  E.g. many orders with
aquatic larvae, terrestrial
adults
–  Allows occupation of
multiple niches by a single
individual
Partitioning of Life Cycle
•  Evolutionary Trend: More
distinction between life
cycles
•  Incomplete
metamorphosis
(Hemimetabolous)
–  Ancestral state
–  Juvenile form closely
resembles adult, but without
wings
–  Grows by successive molts
–  Ultimate stage is winged
adult
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Partitioning of
Life Cycle
•  Evolutionary Trend: More
distinction between life
cycles
•  Complete metamorphosis
(Holometabolous)
–  Derived state
–  Juveniles are larvae: maggots,
grubs, caterpillars, etc.
–  Larval stage grows by
successive molts
–  Enter an inactive stage: pupa,
chrysalis
–  Entire body digested, reformed
as adult, winged insect
Incomplete
Metamorphosis
Insect
Evolution
Incomplete
Metamorphosis
Insect
Evolution
Complete
Metamorphosis
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Crustacea
Chelicerata
•  But the Crustacea are the
dominant arthropod group in
the oceans.
•  Indeed, insects are probably
crustaceans that colonized
land.
•  Crustacea paraphyletic
•  Biramous appendage
probably lost as a
consequence of move to
terrestrial environment.
Myriapoda
Crustacea
•  Plesiomorphically
biramous.
•  Dominant marine
arthropods: ~52,000
species.
Crustacea
•  General morphology:
•  Two paired antennae
•  Modified appendages (e.g.
lobster has 19 pairs)
–  3 or more pairs as
mouthparts
–  Walking legs on thorax and
abdlomen
–  Lost appendages can
regenerate
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Crustacean Diversity
•  DECAPODS
•  Most commonly
encountered
–  lobsters, crabs (land,
marine), shrimp,
crayfish (fresh)
–  Antarctic krill
–  exoskeleton
hardened with
CaCO3
Crustacean Diversity
•  BRANCHIOPODS
•  Fairy shrimp, brine
shrimp, water fleas,
sea-monkeys
•  Primarily fresh-water
•  Fertilized eggs can
go dormant, survive
extreme conditions
Crustacean Diversity
•  BRANCHIOPODS
•  Fairy shrimp, brine
shrimp, water fleas,
sea-monkeys
•  Primarily fresh-water
•  Fertilized eggs can
go dormant, survive
extreme conditions
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Crustacean Diversity
•  ISOPODS
•  Most widespread group of
Crustacea
•  From deep sea vents to
truly terrestrial
•  Diverse habitats from
herbivorous to parasitic
•  Pill bugs, roly-poly, sea
lice
Crustacean
Diversity
•  COPEPODS
•  Marine and freshwater
•  Numerous
–  Millions can be present in
m3 of seawater
•  Important as fresh and
marine plankton
•  Include krill, major
component of plankton and
major prey item of baleen
whales
•  Some parasitic forms
Crustacean Diversity
• 
• 
• 
• 
CIRRIPEDIA
Barnacles
Sessile crustaceans
Carapace hardened
by CaCO3
•  Limbs modified as
filter feeding
appendages
•  How do they mate?
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Summary
•  Protostomes are characterized by
specific early embryonic features
•  Include two main lineages
–  Lophotrochozoa
–  Ecdysozoa
•  Lophotrochozoa most diverse in phyla
(fundamentally different body plans)
•  Ecdysozoa most diverse in species
Deuterostomia
•  Deuterostomes are
sister-group to
Protostomes within
Bilateria
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Deuterostomia
•  Deuterostomes are
sister-group to
Protostomes within
Bilateria
•  Deuterostomes also
characterized by
details of early
embryonic
development
Deuterostomia
•  Includes two major
lineages
•  Echinodermata
•  Chordata
–  Cephalochordata
–  Urochordata
–  Vertebrata
Echinodermata
•  Sea stars, urchins and
relatives
•  ~7000 species, six
classes
•  All marine
•  “Spiny skin”
–  Calcareous shell, often w/
bumps, spines
–  Covered with thin
epidermis
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Echinodermata
• 
SECONDARY RADIAL
SYMMETRY
–  Bilateral larvae
–  Left side grows at expense of
right side (eventually
absorbed)
–  Five radiating spokes from
central axis
• 
• 
Slow-moving, sessile or
sedentary
Separate sexes, external
fertilization
Echinodermata
•  Water vascular
system
•  Operates hydraulic
canals, branching
and ramifying into
tube feet
–  Locomotion
–  Feeding
–  Gas exchange
Echinoderm
Diversity
•  1: Asteroidea - sea stars
•  Five or more arms radiate
from central disc
•  Tube feet on undersurface of
arms, act like suction disc for
slow walking
•  Also for feeding, grasping
clams, mollusks; inverts
digestive tract inside animal
and secretes digestive
enzymes: predators
•  Some with powers of
regeneration
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Echinoderm Diversity
•  2: Ophiuroidea- brittle stars
and basket stars (sister-taxon
to Asteroidea)
•  Distinct central disc; thin
flexible arms
•  Tube feet lack suckers; move
by thrashing arms
•  Feeding modes vary:
scavenging, predaceous
(brittle stars), suspension
feeders (basket stars)
Echinoderm Diversity
•  3: Echinoidea - sea urchins,
sand dollars
•  No arms, spherical (urchins);
or flat, disc-shaped (sand
dollars)
•  Five rows of tube feet for
locomotion
•  Long external spines
controlled by muscles, also
for movement
•  Complex mouth for eating
seaweed
Sea Urchins & Sea Otters
•  Sea urchins are voracious
herbivores of kelp
•  Sea otters eat lots of sea
urchins.
•  Sea otters hunted to ~38
individuals, kelp forests
crashed.
•  Sea otters protected, now
>3,000, kelp beds
recovering
•  Effect visible from space.
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Echinoderm Diversity
•  4: Crinoidea - sea lilies,
feather stars
•  Ancient group, to
Cambrian
•  Attaches to substratum by
stalk
•  Others crawl by long
flexible arms, also used in
filter feeding, mouth
upward
Echinoderm Diversity
•  5: Holothuroidea - sea
cucumbers
•  Lack spines, exoskeleton
reduced
•  Elongate, “cucumber” shape,
but...
•  Five rows of tube feet as in
other echinoderms;
•  Some oral tube feed
modified as tentacles.
Echinoderm Diversity
•  Concentricycloidea
- sea daisies
•  First discovered in
1986
•  Live on sunken
deep-sea wood
(>1000m)
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