BIOL 321 Part II Flashcards

Question 1

Q

Bryozoa lifestyle

Answer

A

colonial, sessile, suspension feeders

Question 2

Q

Individual bryozoan

Answer

A

zooid
very tiny (mm’s)
lophophore

Question 3

Q

lophophore

Answer

A

funnel of ciliated tentacles used for suspension feeding

Question 4

Q

Bryozoan exoskeleton

Answer

A

zooecium

often calcified

Question 5

Q

Bryozoan digestion

Answer

A

u-shaped digestive tract

Question 6

Q

why is u-shaped digestive tract appropriate for exoskeleton enclosed organisms

Answer

A

if posterior end is closed feces would accumulate

Question 7

Q

Bryozoan compartments

Answer

A

2 coelomic compartments - lophophoral coelom, perivivsceral coelom

Question 8

Q

Bryozoan organs

Answer

A

no specialized organs for gas exchange, excretion/osmoregulation, internal fluid circulation

Question 9

Q

How do Bryozoans accomplish gas exchange/fluid circulation without organs

Answer

A

ciliated mesothelium circulate fluids/gases

Question 10

Q

Bryozoan colony form diversity

Answer

A

stoloniferous
encrusting
erect

Question 11

Q

encrusting bryozoan colonies

Answer

A

zooids lie flat on substrate w/ dorsal surface attached to substrate

Question 12

Q

stoloniferous bryozoan colony

Answer

A

creep over rocks, zooids bud up from stolon

Question 13

Q

erect Bryozoans

Answer

A

flat blades

branched fronds

Question 14

Q

solitary bryzoan

Answer

A

Monobryozoan
solitary, motile, infaunal- interstitial fluids of sand grains, extensions hold on to sand grains, contact to pull organism down

Question 15

Q

Bryozoan polymorphs

Answer

A

heterozooid

autozooid

Question 16

Q

Heterozooid

Answer

A

usually defensive, non-feeding

e.g. avicularium, operculum snaps shut to deter predators/organisms settling

Question 17

Q

Autozooid

Answer

A

feeding, reproducing

Question 18

Q

Vibraculum

Answer

A

type of heterozooid (Bryozoan)

elongate ‘whips’ swarm around colony, dislodge settling/predators/used as ‘legs’ for movement

Question 19

Q

Bryozoan reproduction

Answer

A

larva -settles -metamorphosis -initial zooid (founder)- aseuxal budding - more individuals = colony
sexual reproduction to form new colony

Question 20

Q

Bryozoan circular colony

Answer

A

founder cell in middle

budding takes place around circumference

Question 21

Q

periphery of encrusting bryozoan colony

Answer

A

budding zone

Question 22

Q

brown body

Answer

A

degenerated mass of zooid tissue, only epidermis +mesothelium, regressed zooid

Question 23

Q

what happens with brown body

Answer

A

regenerate whole new zooid w/ brown body in stomach - defacate it out

Question 24

Q

why do zooids regress and regenerate?

Answer

A

possibly method of dealing with toxin/waste build up

Question 25

Q

Bryozoan defense

Answer

A

heterozooids
colonialism
chemical defense
induced defences
calcification of frontal membrane

Question 26

Q

colonial defense

Answer

A

strength in numbers, genome maintained - unlikely predator will eat whole colony, can regenerate

Question 27

Q

what are chemical defenses

Answer

A

secondary metabolites
deter predators
antibiotics

Question 28

Q

Bryozoan secondary metabolites

Answer

A

bryostatin - appears to have anti-cancer, anti-alzheimer properties, synthesized by symbiotic bacteria

Question 29

Q

why is it important to calcify frontal membrane of Bryozoan

Answer

A

flexible frontal membrane leaves them vulnerable to predation
e.g. nudibranch slices frontal membrane w/ radulae and sucks out bryozoan

Question 30

Q

Induced defense, bryozoa

Answer

A

initially put all E into reproduction, predator comes, w/i 48hrs of predator feeding zooids form calcareous spines on corners of zooecia

Question 31

Q

Bryozoan frontal membrane calcification

Answer

A

frontal surface inflexible to protect against predators

Question 32

Q

how can lophophore retreat with inflexible frontal membrane

Answer

A

sac inside of perivisceral compartment is filled w/ fluid, ejects fluid out pore to make room for lophophore

Question 33

Q

periversceral fluid-containing sac in Bryozoans with frontal membrane calcification

Question 34

Q

how is lophophore moved out in Bryozoan w/ frontal membrane calcification

Answer

A

parietal muscles expand balloon and water is sucked back in - forces lophophore out of way

Question 35

Q

how is lophophore retracted in a Bryozoan

Answer

A

lophophore retractor muscles

Question 36

Q

Bryozoan sexual characteristics

Answer

A

gametes arise from mesothelium
hermaphroditic (sequential or simultaneous)
sperm spawn through tentacular pores
external or internal fertilization

Question 37

Q

Bryozoan external fertilization

Answer

A

both gametes spawned externally

long-lived feeding larvae

Question 38

Q

Bryozoan internal fertilization

Answer

A

eggs maintained internally, brooded for short period, short-lived non-feeding larvae

Question 39

Q

Bryozoan egg brooder

Answer

A

ovicell (heterozooid)

Question 40

Q

Mollusca subphyla

Answer

A

Conchifera

Aculifera

Question 41

Q

Aculifera groups

Answer

A

Polyplacophora

also Chaetodermomorpha, Neomeniomorpha which we are not studying and are placaphora

Question 42

Q

Conchifera groups

Answer

A

Monoplacophora
Cephalopoda s.g.
Scaphopoda s.g.
Bivalvia s.g. 
Gastropoda

Question 43

Q

Mollusca primitive characteristics

Answer

A

dorso-ventral differentiation
CaCO3 shell
mantle cavity, gills, osphradia
shell-attached muscles

Question 44

Q

chiton shell

Answer

A

8 articulating shell valves w/ 8-pairs dorsal ventral shell-attached muscles (from shell-foot)

Question 45

Q

Mollusc dorso-ventral differentiation

Answer

A

visceropallium

cephalopodium

Question 46

Q

Chiton osphradia

Answer

A

2 sensory organs - on either side of anus

Question 47

Q

Mollusca gill

Answer

A

ctenidium - central axis w/ gill lamella, afferent/efferent blood vessels

Question 48

Q

Mollusca circulation

Answer

A

hemal fluid in to afferent blood vessel, through each gill lameli, out efferent blood vessel

Question 49

Q

Mollusca water circulation

Answer

A

in between each lameli - countercurrent to hemal flow to maximize efficiency of gas exchange

Question 50

Q

Mollusca reduced coelom

Answer

A

pericardium

containing heart, attached to metanephridia, gonads, associated with gut

Question 51

Q

metanephridia, Mollusca

Answer

A

heart contraction = ultrafiltration

fluid down metanephridial ducts = selective reabsorption

Question 52

Q

Mollusca gonads

Answer

A

derived from mesothelium

most extant organisms do not retain connection between gonad-pericardium

Question 53

Q

Mollusca digestion

Answer

A

mouth, radular cartilage, foregut, radular sac

Question 54

Q

radular sac

Answer

A

secretes riot of radular chitinous teeth on ribbon

Question 55

Q

radular cartilage

Answer

A

rods, support radular teeth

Question 56

Q

how radula works

Answer

A

muscle protrudes radular cartilages out of mouth carrying radular teeth - pull teeth back in scraping substrate

Question 57

Q

Mollusc radula + cartilages

Answer

A

buccal mass

Question 58

Q

Mollusc nervous system

Answer

A

circum-esophogeal nerve ring (cephalopodium)
visceropallial nerve cords
pedal nerve cords
pleurovisercal ganglia 
cerebral ganglia 
pedal ganglia

Question 59

Q

distinctive characteristics of chitons

Answer

A

minimal cephalization
dorso-ventral flattening
dorsal shell w/ 8 articulating valves
mantle assisted substrate adhesion
radula with magnetite caps

Question 60

Q

Chiton cephalization

Answer

A

non-ganglionated

non-active, head non-specialized

Question 61

Q

Why chitons have dorsoventral flattening

Answer

A

low profile helps avoid being washed away - adaptation to wave swept shores

Question 62

Q

Chiton substrate adhesion

Answer

A

very muscular foot + mantle periphery for clinging

lift mantle roof = negative pressure = suction

Question 63

Q

Chiton radula caps

Answer

A

Mollusc teeth are replaced but chitons cap w/ magnetite (Fe containing bxomineral) to reduce wear

Question 64

Q

Chiton reproduction

Answer

A

dioecious, broadcast spawn (m and f), external fertilization, gametes from gonad mesothelium, ciliated non-feeding larvae

Answer 64

A

Arthropoda

Answer 65

A

very rare, deep sea, only known from fossils, single dorsal shell, ventrally similar to chiton, sister clade to rest of conchifera

Answer 66

A

mouth, anus, lateral mantle cavity w/ ctenidia, 8 dorsal shell muscles

Answer 67

A

isometric coiling -coils in same plane, only see one from front view -asymmetric coiling

Answer 68

A

visceroplallial elongation and coiling

Answer 69

A

columella, CaCO3, central coiling axis

Answer 70

A

protective retreat

Answer 71

A

single or single paired
hold on to columella
run down to foot/head to pull head in, close operculum

Answer 72

A

Shell coils (exogastric) and elongate dorsoventrally, 
reduced shell aperture, mantle cavity, # shell muscles, #ctenidia

Answer 73

A

Torsion (180ºrotation) of visceropallium relative to cephalopodium, rotation of shell (endogastric shell coil)- anus + mantle cavity over mouth

Answer 74

A

anatomy of living gastropod

development of basal gastropod

Answer 75

A

asymmetric coil of shell (goes to the left or right)
torsion
non-bilateral organs/structures (majority of gastropods have left ctenidium/osphradium)

Answer 76

A

cross-over of visceropallial nerve connectives

Answer 77

A

tiny calcareous shell swimming side down, 2 velar lobes, modified trochophore (prototroch, metatroch for feeding)

Answer 78

A

mantle cavity and therefore ctenidia are moved anterior - water that is brought in is less disturbed by movement

Answer 79

A

mc below foot = pull foot in first, velum in last; velum is more valuable and vulnerable than foot, advantageous to have mc above head and pull foot in last

Answer 80

A

ontogenetic torsion

see foot on both sides of shell in developmental stage

Answer 81

A

1 batch pre-torsional larvae, 1 post-torsional; both have predators; found no difference in # survivors- no evidence of torsion being advantageous

Answer 82

A

results in deeper anterior mantle cavity - water needs to be frequently circulated for aeration and removing waste

Answer 83

A

restricted mantle cavity
shell perforations
shit of anus to right side

Answer 84

A

have 2 ctenidia

Answer 85

A

Majority of gastropods; loss of right ctenidium, osphradium;
shift anus to right;
oblique current through mantle cavity; pick up fecal material last on way out

Answer 86

A

siphon

right side, highly mobile, muscular, samples water and picks up chemical signatures

Answer 87

A

unilateral enlargement of mantle cavity- 2 mc’s and one expands in different ways

Answer 88

A

monotocardian
diotocardia
heterobranchia

Answer 89

A

enlarged MC, ctenidia on left, anus on right

Answer 90

A

enlarged MC, 2 ctenidia (L/R), anus in middle

Answer 91

A

MC not enlarged, reduced to 1 ctenidia

Answer 92

A

fast moving, A-P axis = need for receptors, ganglionization: 1+ tentacle sets, eye spots, series of ganglia

Answer 93

A

protective shell - single plate into coiled cone
torsion
pronounced development of head

Answer 94

A

Patellogastropoda s.g.
Vetigastropoda s.g.
Caenogastropoda s.g.
Heterobranchia

Answer 95

A

Prosobranchia (Patellogastropoda, Vetigastropoda, Caenogastropoda) s.g. Opisthobranchia (Heterobranchia) s.g. Pulmonata (Heterobranchia)

Answer 96

A

keyhole limpets, abelone

Answer 97

A

majority of marine gastropods, well developed shells

Answer 98

A

herbivorous grazing using radula

Answer 99

A

ribbon of teeth secreted by radular sac, protruded out of mouth to scrape rock

Answer 100

A

area of gut that radula opens in to

Answer 101

A

many herbivorous grazers, retain primitive method

Answer 102

A

many herbivorous grazers, retained primitive feeding method (radula); many predators with proboscis

Answer 103

A

right side, normally tucked in, used for feeding

Answer 104

A

mouth - buccal cavity- anterior esophagus- mid-esophageal gland; salivary glands attach to buccal cavity

Answer 105

A

deep in-pocket in anterior end = proboscis sac, buccal cavity = proboscis, esophagus greatly lengthened, mid-esophageal gland is enlarged and connected to esophagus by narrow gut

Answer 106

A

shell drills, leave bevelled edged hole on preys shell

Answer 107

A

tip of proboscis has accessory boring organ - raps on shell = mechanical abrasion; also chelate shell = chemical dissolution

Answer 108

A

highly derived gastropod feeding, mostly tropical/subtropical, predatory caenogastropod, feeds on worms/molluscs/fish

Answer 109

A

very long proboscis, w/ harpoon tooth and venom

Answer 110

A

apex of radular tooth is shaped like hollow harpoon, snail takes 1 tooth and places it at end of proboscis, tooth is connected to venom gland

Answer 111

A

midesophogeal gland highly elongated ending in muscular ball specialized to synthesize and secrete conotoxins

Answer 112

A

neurotoxins, peptide that bind to Fe channels and neurotransmitters, rapidly immobilize prey, any 1 species may have 100’s

Answer 113

A

elaborated dorsal surface, secondarily deflected anus to posterior end (detorsion); loss of larval shell during metamorphosis

Answer 114

A

do have shell in juvenile form (and torsion), crawl out of shell and discard it and operculum

Answer 115

A

chemical defense
escape behaviour
sequester nematocysts
autotomy

Answer 116

A

dorsal chemical glands - unpallatable/toxic

Answer 117

A

some make own

many steal from prey (sponges, bryozoans) and put in dorsal gland sacs (cerata/papillae)

Answer 118

A

touched by predator – lift off seafloor - d/v body undulations - catch current and float away

Answer 119

A

feed on cnidarian- sequester nematocyst- carried up to cerata and deposited- phagocitized - utilized

Answer 120

A

cnidosac - special sac at time of cerata lined by epithelium

Answer 121

A

secrete mucus that makes them not trigger (like clown fish) - may get stung at first until they learn the right formula (species specific)

Answer 122

A

rapidly release body part, mainly cerata

Answer 123

A

snails, slugs; terrestrial; threats include desiccation, T changes

Answer 124

A

closed mantle cavity = ‘lung’, pneumostome = pore, opening to lung (able to close)

Answer 125

A

mantle cavity forms internalized lung
conversion of ammonia to uric acid
asetivation

Answer 126

A

metabolic slow-down, hide in humid location,
tolerance of desiccation
ability to rapidly rehydrate

Answer 127

A

Caenogastropods, pneumostome + long siphon opening in to lung
(convergence w/ heterobranchs)

Answer 128

A

open spaces between epithelial cells

Answer 129

A

broadcast spawn gametes, external fertilization

Answer 130

A

internal fertilization, encapsulated eggs, juvenile crawls out of egg capsule

Answer 131

A

dv flattened body
2 shell valves
spacious lateral mantle cavity to house ctenidia 
minimal cephalization
no radula

Answer 132

A

including foot, facilitate digging

Answer 133

A

life in substrate - need to remain open for circulation, need to shells to remain open - pressure would collapse mantle

Answer 134

A

none in extant members, feeding by suspension or deposit

Answer 135

A

along edge of shell or restricted to siphons

Answer 136

A

pull valves together, cause tension in ligaments, when released ligaments pull shells open

Answer 137

A

secreted by outer mantle lobe, sequential layers of bxomineral CaCO3 w/ crystals oriented in opposite directions - cross-hatched for strength

Answer 138

A

sensory structures on periphery of mantle fold (middle lobe)

Answer 139

A

most exposed to environment, may contain photoreceptors, tentacles

Answer 140

A

secretes shell

Answer 141

A

‘muscle lobe’

has pallial muscles connected to shell valve to pull and tuck all soft tissues in side shells

Answer 142

A

prosobranch
lamellibranch
septibranch

Answer 143

A

deposit feeder; use palp tentacles; gills for gas exchange only, ancestral feeding strategy, long paired siphons

Answer 144

A

ciliated, deposit feeding in protobranchs

Answer 145

A

gas exchange only

non-elaborate gill filaments on sides of gill axis

Answer 146

A

ctenidia for gas exchange and feeding, suspension feeders

Answer 147

A

elongate filaments, folded back to fit, highly ciliated to carry particles

Answer 148

A

demibranchs

outer demibranch = closest to shell

Answer 149

A

each ‘limb’ is surrounded by 3 types of cilia: lateral cilia, laterofrontal cilia, frontal cilia

Answer 150

A

short, on the ‘top/bottom’, create water current

Answer 151

A

longer, point diagonally, intercept particles

Answer 152

A

rare, predators, suction feeding, enormous inhalant siphon used for sucking in small organisms

Answer 153

A

modified gill = muscular, perforated diaphragm; closed shell, elevated muscular shelf = increased volume in inhalent chamber = suction

Answer 154

A

burrowers (majority; deeper = longer siphon)
attached to solid substrate
boring

Answer 155

A

secrete byssal threads

Answer 156

A

short, face out, frontal surface, carry particles down filament to elbow-like area of gil filament

Answer 157

A

byssal gland by foot secretes fluid– fluid runs down foot, forms puddle– starts to harden - lift foot- move foot and repeat

Answer 158

A

cement w/ CaCO3

Answer 159

A

shipworms

free-swimming larva, settle, metamorphose, feed/create tunnel

Answer 160

A

tusk shells, see text book ch 12

Answer 161

A

active, pelagic, predatory, smartest, largest, fastest molluscs, 3 subclasses, 1 extinct

Answer 162

A

radula
molluscan-style gill (but not ciliated)
shell-secreting mantle (but reduced/lost in most extant)

Answer 163

A

septate shell

highly modified foot

Answer 164

A

prehensile appendage (arms, tentacles)
funnel

Answer 165

A

Nautiloidea - extant, since Palaeozoic, first known group (540Ma)
Ammonoidea - extinct end of Mesozoic, known from mid Paleo
Coleoidea - extant, known from end of Paleo

Answer 166

A

primitive cephalopod, tentacles have no suckers, external shell, hood, funnel

Answer 167

A

external, gas-filled chambers, chambers separated by septa, septa perforated for siphuncle

Answer 168

A

active, agile swimming, predatory feeding

Answer 169

A

visual predators- image-forming eyes, eye morphology convergent w/ vertebrates

Answer 170

A

high metabolic rate, ventilate gills by pumping muscular mantle, closed circulatory system, systemic and branchial hearts

Answer 171

A

booster pumps to force blood through gills

Answer 172

A

Lophotrochozoa

Exdysozoa

Answer 173

A

Nematoda, Onychophoran, Arthropoda

Answer 174

A

Ecdysis

no motile cilia/flagella

Answer 175

A

periodically moult exoskeleton/cuticle for growth

Answer 176

A

multilayered collagenous cuticle, 4 moults, longitudinal muscles only, pseudocoel, syncytial epidermis, anterior nerve ring, longitudinal cords, aberrant cilia, eutely

Answer 177

A

non motile, restricted to sensory function

Answer 178

A

embryo hatches w/ set # of somatic cells and never produces any more; growth only by enlargement of cells

Answer 179

A

thrashing motion; dorsoventral contractions; only useful for forward motion in dense medium

Answer 180

A

stiff cuticle;
fluid maintained under high pressure in pseudocoel;
longitudinal muscles

Answer 181

A

triradiated pharynx, muscle contraction opens lumen, have to actively open gut by muscular means b/c high pressure of gut, must drink water to actively push food down

Answer 182

A

Asexual and sexual

Answer 183

A

very rare - parthenogenesis (no budding or fission)

Answer 184

A

dioecious, internal fertilization, males w/ copulatory spicules, ameboid sperm (aflagellate)

Answer 185

A

4 moults to adult stage; egg - 4 juveniles - adult; eutely

Answer 186

A

Nematode facultative diapause, triggered by enviro. cues, age arrest (reduced metabolic rate), occurs at L2 (juvenile #2)

Answer 187

A

hookworm, wuchereria, golden nematode

Answer 188

A

intestinal parasite, 1 host, cuticle around mouth forms tooth/hook-like projections, consume blood from intestinal wounds, leads to anemia

Answer 189

A

adult worm in human intestine - eggs passed in feces - juv. 1 hatches - 2 moults - juv. 3 burrows into skin, often foot - moves to circulatory system - heart - lungs - trachea - pharynx– intestine

Answer 190

A

Nematode, Elephatiasis, microfilariae larvae clog lymphatic vessels, causes grotesque swelling, 2 hosts - human, mosquito

Answer 191

A

microfilariae - mosquito - moult - move to salivary gland - transmitted to human

Answer 192

A

1 host, damaging potato parasite, cysts on roots are dead swollen fm bodies filled w/ eggs

Answer 193

A

Europe, Asia, Africa, Canada (Nfld, Central Saanich)

Answer 194

A

burrow in to roots, feed on root tissues, cause death/stunted growth

Answer 195

A

model organism for developmental genetics- tiny (few mm’s), short generation times (3days), hermaphroditic (self-fertilize), eutely (959 somatic cells)

Answer 196

A

cell lineage known for all cells - map
synaptic connections btw neurons mapped
entire genome sequenced

Answer 197

A

high successful by any metric
important food web component
medical importance
economic importance 
model organisms

Answer 198

A

most specious, most individuals, ability to invade almost all habitats, etc.

Answer 199

A

important component - 1º and 2º consumers, removal of arthropods would collapse any ecosystem

Answer 200

A

mosquitos are disease vector

Answer 201

A

positive and negative

pollination, crop destruction

Answer 202

A

monophyletic or polyphyletic?
sister groups?
relations amongst major groups?
one of the most extensively debated subjects in evolutionary biology

Answer 203

A

convergent with Annelida

Answer 204

A

tagmosis

unit = tagmata

Answer 205

A

chitin (polysaccharide) + crosslinked proteins (sclerotization) secreted by epidermal epithelium

Answer 206

A

support
protection (predators, mechanical abrasion)
facilities movement

Answer 207

A

transmits force of muscle contraction

Answer 208

A

epicuticle (lipids, waxes)
Protocuticle (exocuticle + endocuticle)
Epidermis

Answer 209

A

4 hardened plates (sclerites): top = term, bottom = sternum, sides = pleuron

Answer 210

A

articles - thin hollow tubes connected to form appendages

Answer 211

A

joints formed by thin, flexible exoskeleton (articular membrane)

Answer 212

A

antagonistic muscle bands
condyle
many appendages/articles

Answer 213

A

extensor and flexor muscles

Answer 214

A

one article fits precisely into the other - only permits movement in 1 direction

Answer 215

A

movement in different directions/planes = large range of motion

Answer 216

A

versatile raw material:

can be sculpted into diff. shapes/functions
each article can be precisely moved by muscles

Answer 217

A

sensory, mouthparts, prey capture, crawling, swimming, escape behaviour

Answer 218

A

hemocoel separated by diaphragm in to pericardial and peravisceral

Answer 219

A

epithelial tubes capped by epithelial sac = metanephridium
excretory tubes homologous to metanephridium
saccule homologous to shrunken coelom(?)

Answer 220

A

moulting

sensilla

Answer 221

A

periodic moults under hormonal control- secrete inactive chitinases

Answer 222

A

glandular cells secrete inactive chitinase (proenzyme) - new epicuticle secreted - proenzyme activated - digest endocuticle - split out at areas of weakness

Answer 223

A

week/soft, not cross linked - pump up with air/water -make bigger before hardening - harden - shrink back down - have room

Answer 224

A

sensory, ball and socket joint, neurons w/ dendrites, lower exoskeleton cover

Answer 225

A

Onychophora

Answer 226

A

velvet worm, low species #s compared w/ arthro. (180), very humid terrestrial, chitinous cuticle, metameric, non-jointed appendages, annelid/arthropod, distinct terminal ends (claws)

Answer 227

A

Hallucigenia, Burgess Shale, Field BC, early Cambrian

Answer 228

A

Trilobitomorpha
Chelicerata
Mandibulata

Answer 229

A

2 tagmata
Prosoma
Opisthosoma

Answer 230

A

Prosoma - 6 pr.

Opisthosoma - variable

Answer 231

A

chelicerae

Answer 232

A

pedipalps

Answer 233

A

Merostomata
Arachnida
Pycnogonida

Answer 234

A

1 genus (4spp.) extant, marine, horseshoe crab

Answer 235

A

Limulus sp.

horse shoe crab

Answer 236

A

2 tagmata: prosoma (A), opisthosoma (P);

telson, compound eye (unique)

Answer 237

A

shovel-shaped to facilitate sediment burrowing

Answer 238

A

not true metamere, hinged to body, d-v movements, aids in ‘righting’ flipped over body

Answer 239

A

Prosoma: chelicerae, pedipalp, (mouth), 4 walking legs

Answer 240

A

pincer-like appendage

Answer 241

A

podomere (segment of appendage)

Answer 242

A

not chelate
‘pusher legs’
push off sediment
clean out gills

Answer 243

A

6pr appendages fused in to flaps = gill opercula

Answer 244

A

thicker exoskeleton protecting book gills (very thin exo.)

wave to oxygenate gills

Answer 245

A

proximal joint/ process of arthropod appendage, modified to aid in carrying/ masticating food

Answer 246

A

scorpions, spiders, ticks, mites
terrestrial, largest group of chelicerata, few opisthosome appendages, predators, malpighian tubules, book lungs/tracheae, spermatophores

Answer 247

A

mostly predatory, mostly on other arachnids

Answer 248

A

must get in to exoskeleton - rip up, vomit digestive enzymes, suck up sap

Answer 249

A

lined tubules extend from gut and float in hemocoel, take up rates and crystallize- move down tubule - removed from anus - save water

Answer 250

A

internalized book gill

delicate epidermis layers covered by thin exoskeleton

Answer 251

A

tubular, branched, invagination of epithelia w/ exoskeleton floating in hemocoel

Answer 252

A

internal fertilization

spermatophores - protected bundles of sperm

Answer 253

A

Prosoma: chelicerae (small), 1 pr pedipalps (large, chelate), 4 pr walking legs
telson: stinger w/ neurotoxin glands

Answer 254

A

prey capture, ambush predator (only use stinger for big prey)

Answer 255

A

comb-like sensory structure - high density of mechanoreceptors to detect substrate movements, opens to book lung, ventral side of prosoma

Answer 256

A

no compound eyes, unique pedipalps, pedicel, spinneret

Answer 257

A

fm - sensory appendages
m- deliver sperm
not chelate, daggers

Answer 258

A

pedicel

narrow for movement = flexibility of spinneret

Answer 259

A

many spigots release strands of silk

Answer 260

A

no spermatophores, extrude sperm on to silk, pedipalp sucks it up in to chamber, fits in to fm gonopore like lock&key

Answer 261

A

sperm transfer
egg cases
prey capture
aqualung 
ballooning

Answer 262

A

move through the air by releasing threads to catch the wind

Answer 263

A

huge diversity- aquatic, predator/ herbivorous/ parasites

Answer 264

A

hypostome
chelicera
pedipalp
4 pr walking legs

Answer 265

A

attach to host - slice open host w/ chelicera - insert hypostome to anchor and hold position - use pedipalps to support body and for sensory

Answer 266

A

sea spiders

ectoparasites, very small, puncture hole in host and suck out body fluid

Answer 267

A

Prosoma: proboscis, chelicera (chelifore), pedipalp, ovigerous leg, 4 prs legs
Opisthosoma great reduced, bears anus

Answer 268

A

forced through body wall of host to suck body fluid, chelicera help open wound for insertion

Answer 269

A

often only in m, used to carry eggs, males carry and brood eggs until hatching

Answer 270

A

Chelicerata

Mandibulata

Answer 271

A

Myriapoda

Pancrustacea

Answer 272

A

Crustaceans = Hexapoda

Ostracodes, Cirripedia, Malacostraca, Copepoda, Branchiopoda, Hexapoda, Remipedia

Answer 273

A

no, paraphyletic

Answer 274

A

2 or 3
head + trunk
or head+ thorax + abdomen

Answer 275

A

cephalothorax (secondarily consolidated)

Answer 276

A

3

head+ thorax + abdomen

Answer 277

A

head: 1-antennae, 2-antennae or X, 3-mandibles, 4-maxillae I, 5- maxillae II
(3prs mouthpart appendages)

Answer 278

A

disarticulated
upper lip (labrum), 2 mandibles, 2 maxillae, lower lip (labium)

Answer 279

A

epipod, protopod

Answer 280

A

2 basal articles made of multiple articles - exopod, endopod

Answer 281

A

common in mandibulate

many hexagons = ommatidium

Answer 282

A

single photoreceptor cartridge: each one samples section of visual field at different angle than neighbour, detecting slightly different visual field

Answer 283

A

crystalline cone focuses incoming light - reticular cells covered in microvilli are receptors - open ion channels - membrane polarization - propagate action potential - brain -information

Answer 284

A

2:
head
thorax

Answer 285

A

head: pair antennae, mandible, 2 pr maxillae

Answer 286

A

centipedes, millipedes

Answer 287

A

predators, poison claws, fast

Answer 288

A

first trunk appendage

Answer 289

A

fast effective stroke, slow recovery stroke, high speed, high gear, low power, not many legs on ground at once

Answer 290

A

herbivorous, slow, diplosegments

Answer 291

A

2prs legs/segment

Answer 292

A

slow effective stroke, fast recovery stroke, slow movement, low gear, high strength, most legs on ground at once pushing - strong walking

Answer 293

A

Remipedia - primitive body plan - annelid like, not very successful

Answer 294

A

Minimize water loss
Avoid/tolerate temperature extremes
Wings/flight

Answer 295

A

minimized via: waxy epicuticle (myriapods lack waxes in epicuticle), mapighian tubules, water reabsorption (specialized rectum), tracheal tubules

Answer 296

A

tubules in hemocoel take up urates, precipitate uric acid (non-soluble), pass w/ feces

Answer 297

A

glow produced w/ malpighian tubules - sticky silk threads ensnare prey

Answer 298

A

hollow cylindrical invaginations of body wall, dendritically branched, end on cell body, O2 delivered directly to cell via tube, lined inside by exoskeleton

Answer 299

A

spiracle with filter hairs

Answer 300

A

Taenidia - circular thickenings of exoskeleton along length of tube to prevent collapsing

Answer 301

A

not closable (dry out quicker)

Answer 302

A

behavioural
morphological
physiological

Answer 303

A

basking, stilting, crouching

Answer 304

A

extend legs, lift body off of hot ground

Answer 305

A

ground heats/cools slower than air, crouching close to rock to absorb heat

Answer 306

A

insolating cuticler hairs, layer of hair around body prevents heat loss, e.g. bumblebee

Answer 307

A

shivering, antifreeze proteins

Answer 308

A

sharp crystals rupture cells

Answer 309

A

Antifreeze Proteins

Answer 310

A

surround small ice crystals and prevent them from growing

Answer 311

A

mesothoracic, metathoracic wings

from 2nd, 3rd thoracic segments

Answer 312

A

apterygotes

Answer 313

A

largely exoskeleton, reinforced by wing veins (tracheal tubules), nerves, sensory receptors, tissues

Answer 314

A

new niche space, dispersal to new resources, reach resources inaccessible to others, escape predators, find mates, migration, find suitable mating locations

Answer 315

A

Tergal lobes

Appendage derivatives

Answer 316

A

tergum (top sclerite lobe) draw out laterally

Answer 317

A

no hinge (wings are hinged)
would require elaborate modification

Answer 318

A

epipods are hinged and fn in gas exchange

Answer 319

A

Drosophila gene rubbin (Tc factor) is essential for wing development; mutated rubbin = little nub wings; look for homologues of rubbin in pancrustacea - mark - follow development

Answer 320

A

rubbin traced to epipod in crayfish and brine shrimp- consistent with epipod-wing theory

Answer 321

A

chewing, sponging, piercing, sucking

Answer 322

A

chewing type

e.g. grasshopper

Answer 323

A

heavily sclerotized, chewing:

labrum, 2 mandibles, 2 maxilla, labium (2nd pr maxillae), hypopharynx

Answer 324

A

pterygotes

Answer 325

A

tongue

salivary glands

Answer 326

A

labium (2nd pair maxillae)

tubules for sponging liquid food

Answer 327

A

sponging labium + cutting mandibles (cut open prey to sponge up fluids)

Answer 328

A

labium =protective sheeth, supports stiletto-like mouthparts - labrum, mandibles, maxillae = elongate spheres;
mandibles puncture, labrum forms sucking tube, salivary secretions make us itchy

Answer 329

A

sucking; 1st pr maxillae curve together to form elongate sucking straw

Answer 330

A

ametabolous
hemimetabolous
holometabolous

Answer 331

A

=external wing development
hemimetabolous development
larva similar to adult minus wings

Answer 332

A

apterygotes
nymphs hatch from eggs that look exactly like adult, live in same habitat, feed on same material
stages of moults all look same
no major transitions in development (except reproduction)

Answer 333

A

mainly they do not have wings

Answer 334

A

endopterygote development
larva very different than adult
internal wing development

Answer 335

A

grasshopper, locusts, mayfly larva, dragonfly larva

Answer 336

A

wing pads

Answer 337

A

imaginal discs

Answer 338

A

differential specialization
larva specialized for feeding
adult specialized for reproduction

Answer 339

A

body rearrangement

exclusively adult features develop internally (wing, antennae, mouthparts)

Answer 340

A

nests of stem cells that differentiate in to various adult structures

Answer 341

A

rearrangement
larval structures destroyed
adult structures everted

Answer 342

A

2 life history stages, major development, differential specialization

Answer 343

A

adult - eggs in water - larva (w) - pupa (w) - adult emerges in to air
larva has posterior siphon for breathing
pupae has anterior snorkle

Answer 344

A

morphological
behavioural
chemical
physiological

Answer 345

A

shape and colour matching

e.g. stick bug

Answer 346

A

flight
projectile defecation
petiole clipping
behavioural crypsis

Answer 347

A

release feces in projectile motion to hide location

Answer 348

A

fill up on leaf, chop off stem so hole-y leaf is not so visible

Answer 349

A

woolly aphid, ant, lacewing larvae

Answer 350

A

leaf beetle larva

hold mass of own feces containing defensive chemicals from plant on back - disguise as something not tasty

Answer 351

A

venomous stings (bees, wings)
sticky threads to entangle
(termites)
reflex bleeding (ladybug)

Answer 352

A

toxic hemal fluid released from self-directed rupturing of articular membrane between leg articles

Answer 353

A

thin area of exoskeleton ‘joints’

Answer 354

A

abdominal reaction chamber - explosively eject hot, toxic fluid from anus

Answer 355

A

secrete hydroquinone and H2O2, catalaze reduces H2O2, O2 oxidizes hydroquinones (exothermic), hot quinones released (toxic)

Answer 356

A

2 pair antennae (hexapods have 1)
biramous appendages (hexapods have uniramous)
nauplius larvae

Answer 357

A

no cilia
3 pr muscle-operated appendages
single median eye
2 pr antennae, 1 pr mandibles = swimming

Answer 358

A

Copepoda
Cirripedia
Malacostraca
Hexapoda

Answer 359

A

3 tagmata - abdomen (6 segments), thorax (8), head (5)

Answer 360

A

2pr antennae, 1 pr mandibles, 2 pr maxillae

Answer 361

A

thoracopods
8 prs appendages
maxillipeds, pereopods

Answer 362

A

1+ pairs often modified accessory mouthparts

Answer 363

A

walking legs

Answer 364

A

6pairs
pleopods (swimming)
uropods

Answer 365

A

tergal sclerites fused in to cephalothorax = carapace

lateral carapace flaps form chamber

Answer 366

A

branchiostegites

Answer 367

A

Malacostraca, krill

incomplete branchiostegite, no maxillipeds, specialized thoracopods

Answer 368

A

setose biramous feeding appendages = feeding basket/sieve

Answer 369

A

exoskeleton elaborated in to bristle like extensions

Answer 370

A

Amphipoda, Isopoda

no carapace, 1pr thoracopods = maxilliped, eggs brooded in marsupium formed by oostegite

Answer 371

A

laterally compressed

Answer 372

A

dorso-ventrally compressed (form ball)

Answer 373

A

basal most article

Answer 374

A

bottom layer, closest to body

Answer 375

A

skeleton shrimp, Malacostraca

Answer 376

A

mantis shrimp (Malacostraca)
tropical/semitropical, benthic, carapace does not cover entire length of thorax, functional telson, very aggressive

Answer 377

A

5prs maxillipeds, 2pr raptorial appendages

Answer 378

A

species that burrow in soft substrate

Answer 379

A

species that live in rock crevices

Answer 380

A

stomatopod compound eye

Answer 381

A

mounted on moveable stocks = 360ºrotation = large visual field
eye divided in half = stereo vision = broad focal range
12-19 photoreceptors w/ different photopigments

Answer 382

A

more sensitive to subtle difference in colour, and extremes (UV, polarized)
less ‘windows’ (missing coverage areas)

Answer 383

A

wide flat defense shield

reflect polarized light -signaling?

Answer 384

A

Caridoa
Astacidea
Anomura
Brachyura

Answer 385

A

(Malacostraca)
well-developed carapace (entire thorax)
3 pr maxillipeds

Answer 386

A

Shrimp
delicate, slender pereopods
large muscular abdomen
well developed pleopods
holopelagic or pelago-benthic

Answer 387

A

delicate perching appendages

unique amongst the decapods

Answer 388

A

well developed, swimming

Answer 389

A

Crayfish, lobsters (Decapoda, Malacostraca)

massive pereiopods, large muscular abdomen, pleopods, chelipeds

Answer 390

A

swimming (but don’t swim a lot)

Answer 391

A

1st pair of pereopods - prey capture, defense, offence

Answer 392

A

true crabs (Decapoda, Malocastraca)
broad flat cephalothorax, heavy robust pereopods, chelipeds, reduced tucked in abdomen, closed gill chambers

Answer 393

A

robust pereopods
1st pr pereopods = chelipeds
uropods - secondarily lost
pleopods - reduced/lost, retained in fm to hold eggs between thorax and abdomen
4 pr walking legs

Answer 394

A

squat lobsters, hermit crabs (Decapoda, Malacostraca)
most diverse group of decapods
very reduced 5th pr pereopods
3 prs walking legs 
abdomen well developed

Answer 395

A

abdomen has spiral asymmetry to fit gastropod shell
pleopods only developed on one side
uropods have grippers to hold on to columella

Answer 396

A

Anomuran
carcinization
3 prs walking legs

Answer 397

A

anomurans that have converged body morphology with brachyuran crabs (reduced abdomen, carapace over cephalothorax)

Answer 398

A

decapod elaboration of second pair of maxillae, aerate gills, moves in a wave-like fashion

Answer 399

A

to clean out gill filaments - no motile cilia!!

Answer 400

A

chelate pereopods - reach in to gill chambers w/ delicate pinchers
(no chelopeds)

Answer 401

A

5th pair of pereopods = little ‘stub’ on posterior dorsal end of carapace, insert in to gill chamber for cleaning, setose tip

Answer 402

A

3pr maxilliped epipods = elongate, setose, gill cleaning combs
extend back in to gill chambers
gill scrubbing whenever maxillipeds move

Answer 403

A

closed gilled chambers

lateral rim of branchiostagites fused to abdominal surface

Answer 404

A

telson + 2pr biramous uropods

used along w/ abdominal muscles for movement = tail flip

Answer 405

A

flexion of posterior abdomen segments - pulls body backwards

Answer 406

A

Pancrustacea
extremely abundant, diverse aquatic habitats - freshwater/marine- puddles, hot springs, enormous number of individuals, largest animal biomass on the planet, holopelagic, pelago-benthic, parasitic

Answer 407

A

transfer organic carbon from producers to higher trophic levels

Answer 408

A

flexion between abdomen and cephalothorax -bend middle of body – body move upwards

Answer 409

A

torpedo-shaped
2 tagmata - head/thorax, abdomen
single medial eye

Answer 410

A

1st pr antennae - sensory
2nd pr antennae- swimming
pr mandibles, 1st pr maxillae
2nd pr maxillae - food capture
1pr maxillipeds - assist feeding
4-5prs thoracic app. - hop swim
forked telson - 2 caudal rami

Answer 411

A

forked telson

Answer 412

A

2nd pr antennae (biramous, bristled)

4-5prs thoracic appendage (hop swim) coupled together along median line

Answer 413

A

2nd pr maxillae

1 pr maxillipeds

Answer 414

A

pull of gravity
depth-dependent light intensity
nowhere to hide
dilute resources
small Re #

Answer 415

A

1st pr antennae long,bristled increase drag
2nd pr antennae- swim
store nutrients as lipid globules for buoyancy

Answer 416

A

describes viscous : inertial forces for characterizing behaviour of fluids flowing past an object

Answer 417

A

(velocity x size x density) / viscosity

Answer 418

A

flow lines disrupted by particle - 1st antennae detect disrupted flow while swimming on back- 2nd pr maxillae move apart rapidly - negative pressure, particle drawn in - close maxillae rapidly to capture particle

Answer 419

A

velocity, size

density/viscosity relatively unchanging within water column

Answer 420

A

flow lines move past object in orderly fashion, maintain trajectory, at low speed fluid dominated by viscous forces

Answer 421

A

Turbulent flow
dominated by inertial forces
flow lines severely disrupted past object

Answer 422

A

very active movement, no gliding when movement stops

small size = low Re = viscosity dominant

Answer 423

A

to increase Re (increased velocity)

Answer 424

A

non-moving fluid around object

low Re = thick boundary layer

Answer 425

A

1st antennae covered in mechanoreceptors and setose bristles have thick boundary layer (paddle-like)

Answer 426

A

transparent w/ few tissue pigments
loss of compound eyes (pigmented)
hop swim
diel vertical migration 
1st antennae sensory axons have myelin sheath

Answer 427

A

action potentials travel more rapidly if axon is enlarged (vertebrates), inverts use myelin sheath to speed potential

Answer 428

A

Pheromones

Behaviour patterns

Answer 429

A

male swim back and forth across top of column, fm swim up and down releasing pheromone, when pheromone detected m swims down

Answer 430

A

eggs brooded in egg sacs

nauplius larva

Answer 431

A

salmon louse
ectoparasite
huge, cling to external surface, feed on mucus/epidermis/ blood, detrimental to fish health

Answer 432

A

family Pennellidae
ectoparasite of marine mammals
up to 30cm long

Answer 433

A

sessile in post-metamorphic stage (unique)
carapace as calcified plates
suspension feeding
free-living or symbiotic

Answer 434

A

acorn barnacles

stalked (gooseneck) barnacles

Answer 435

A

calcified cone directly attached to substrate

Answer 436

A

calcified plate mounted on fleshy stalk

Answer 437

A

opercular plates
wall plates
cirri

Answer 438

A

6 pairs thoracic appendages, biramous and setose, very small = low Re, feeding paddles

Answer 439

A

Large Re

generate turbulent flow

Answer 440

A

high flow -incapable of sweeping cirri, can’t raise Re

passive feeding

Answer 441

A

peduncle (stalk)
adhesive gland
ovary, gut, cecum, muscle, mouth, mantle cavity, cirri

Answer 442

A

partial moult, only exoskeleton of cirri

Answer 443

A

CaCO3 added to basal rim and up sides - grow in diameter, height

Answer 444

A

most hermaphroditic
very long penis
gregarious settlement, metamorphosis

Answer 445

A

larval stage attracted to settle near other members of the species - need to be nearby each other

Answer 446

A

as long as there is neighbour fertilization can take place

Answer 447

A

Nauplius larvae - cyprid larva

Answer 448

A

2nd larval stage, non-feeding, must find suitable settling place, crawl around on rocks w/ 1st pr antennae

Answer 449

A

commensal

parasitic

Answer 450

A

dwarf, complemental males in some species
when density low
settle out of copulation range

Answer 451

A

decorator crab with anemone on top to protect itself against cephalopods - barnacle reaches up and rips off anemone tentacles

Answer 452

A

endoparasite of decapod malacostracan
highly derived adult morphology
manipulation of hosts behaviour

Answer 453

A

dioecious - naplius metamorphoses to cyprid - fm swim around looking for decapod - settle - slice hole- insert cells - grow in to series of branched root-like structures that invade all tissues of host (interna) -derive nutrients from host - break through as mass of tissue to exterior (externa) - ‘mate’

Answer 454

A

fm forms externa, male cyprid finds externa, metamorphosis into dwarf male - essentially a sperm sac

Answer 455

A

breaks out where egg mass would normally be, alters hosts behaviour to treat it like eggs (aerate, clean) - even male hosts!

Answer 456

A

'spiny skin'
Deuterostome
Eucoelomate 
WVS
calcareous endoskeleton
pentamerous radial symmetry
mutable collagenous tissue

Answer 457

A

coelom
endoderm derived mesoderm
3 sets of compartments formed in development

Answer 458

A

enterocoely

Answer 459

A

water vascular system
coelomic compartments
operates tube feet

Answer 460

A

highly flexible, muscular, tubes filled d w/ fluid, moved by hydrostatic mechanism, unique

Answer 461

A

pentaradial
at least in adult stage
bilateral + 5 point
bilateral in juvenile stage

Answer 462

A

connective tissues that can change response to tension between extensible and rigid, under control of nervous system

Answer 463

A

calcareous endoskeleton
spines are skeleton covered w/ living tissue 
secreted by embryonic mesoderm
ossicles 
microporosity

Answer 464

A

yes, but not all collagenous tissues are mutable

Answer 465

A

lots of collagen fibres

form in keeping things together (skin to muscle) - generally not active

Answer 466

A

Crinozoa
Asterozoa
Echinozoa

Answer 467

A

Class Crinoidea

Answer 468

A

Class Stelleroidea - Subclasses Asteroidea, Ophiuroidea

Answer 469

A

Classes Echinoidea, Holothuroidea

Answer 470

A

sea stars, mostly predatory

spines, disk, ambulacra, madreporite, arms, ossicles, pedicellariae

Answer 471

A

where tube feet extend to environment (oral surface)

Answer 472

A

latticework of interconnected ossicles, laced together w/ collagen fibres
spines

Answer 473

A

2 jaws formed by specialized ossicles

cleaning, removing settlers

Answer 474

A

epidermis
2 jaw ossicles
basal ossicle
attached by opener/closer muscles

Answer 475

A

fluid-filled tubes 
ring canal around esophagus/ mouth
radial canal down arm
lateral canals out from radial to tube feet
stone canal - from ring to madreporite

Answer 476

A

close valve - contact muscle surrounding ampulla- force water down in to tube foot- foot extended - reach out- contract tube foot muscles to bend

Answer 477

A

flexible pipettes

Answer 478

A

filled with fluid

fluid reservoir

Answer 479

A

reaches up to specialized ossicle (madreporite)

Answer 480

A

very coarse ossicle

replenish fluid in WVS by taking in sea water

Answer 481

A

manufactures phagocytes to phagocitize invading particles that come in madreporite

Answer 482

A

WVS
perivisceral coelom
perihaemal coelom
genital coelom

Answer 483

A

ring nerve + 5 radial nerves
intra-epithelial
no centralization
same organization as WVS

Answer 484

A

tube feet pry open shell- evert cardiac stomach- digest and ingest

Answer 485

A

madreporite
spines
pedicellariae

Answer 486

A

Asexual - fission and regeneration, autotomy
Sexual
planktonic, feeding larva
catastrophic metamorphosis

Answer 487

A

central disk breaks in two then regenerates missing parts

Answer 488

A

arm is shed and lives independently as a ‘comet’, eventually regenerating missing parts

Answer 489

A

dioecious
broadcast spawn
external fertilization

Answer 490

A

Echinozoa (Echinoidea, Holothuroidea)

Answer 491

A

no arms
endoskeleton
aristotles lantern

Answer 492

A

flat ossicles that fit tightly together
5 ambulacral plates, 5 interambulacral areas, 2 rows of plates in each
spines, stalked pedicellaria

Answer 493

A

2 rows of double pores for tube feet

Answer 494

A

attach via ball-and-socket joints, moved by muscles, function in bracing, manipulating food, defense, may extrude toxin

Answer 495

A

stalked
calcareous support rods
three opposing jaws

Answer 496

A

complex system of ossicles and muscles surrounding esophagus
teeth can be protruded from mouth and moved in various directions to eat or scrape

Answer 497

A

sea urchin
radial symmetry
rocky substrates

Answer 498

A

superimposed bilateral symmetry

e.g. sand dollar

Answer 499

A

spines and tube feet

Answer 500

A

scarpe algae from rocks
shred kelp
capture drift algae with tube feet

Answer 501

A

sand/mud substrate
locomotion by spines only
deposit feeding (tube feet)

Answer 502

A

petaloid tube feet specialized for gas exchange

Answer 503

A

no arms
elongation along oral-aboral axis
bilateral symmetry

Answer 504

A

microscopic ossicles

not connected flexible, muscular body wall

Answer 505

A

5 ambulacra
buccal podia
suspension/deposit feeding
internal madreporites

Answer 506

A

bivium (‘dorsal’)

trivium (‘ventral’)

Answer 507

A

circle of 10-30 tentacles around mouth, may be same
size, or some dwarfed, may be branched (dendritic / arborescent), may be pinnate, peltate or digitate, retractile and the body wall can close over them

Answer 508

A

toxic structures attached to left respiratory tree, used for discouraging and entangling potential predators

Answer 509

A

expelling internal organs, cuvierian tubules or entire digestive system, respiratory trees, and gonads; liquify and rupture connective tissue attaching viscera to inner body wall, eventually regenerated

Answer 510

A

sausage shape
microscopic ossicles
muscular body wall
spacious perivisceeral coelom
buccal podia for feeding
respiratory trees

Answer 511

A

bury central disk and stick arms up (kind of looks like whip coral)

Answer 512

A

ophiuroid w/ branched arms - suspension feeding, coil around prey (zooplankton)

Answer 513

A

narrow slit along inner arms of Ophiuroids, leading into large thin-walled sac (the bursa) which has a respiratory function

Answer 514

A

central disk w/ highly flexible arms
locomotion by arm rowing
arm autotomy (MCT)
no anus
tube feet lack suckers and ampullae
bursa for gas exchange

Answer 515

A

mutable collagenous tissue

soften body wall before autotomy

Answer 516

A

cilia-lined sacs called bursae; each opens between the arm bases on the underside of the disk

Answer 517

A

‘sea lily’, ‘feather star’
arms with pinnules and podia
stalk or cirri

Answer 518

A

suspension feeding w/ pinnule podia

Answer 519

A

disc or vertebrate-shaped ossicle

allow long term extension of arms

Answer 520

A

body orientation - mouth up
endoskeleton -articulating discs
WVS for suspension feeding (not locomotion)
MCT for long-term maintenance of posture w/ no E expenditure

Answer 521

A

[Echinodermata s.g. Hemichordata]
s.g.
Chordata (Cephalochordate s.g. Urochordata s.g. Craniate)

Answer 522

A

perforated pharynx
notochord
dorsal hollow nerve cord
muscular post-anal tail

Answer 523

A

Class Ascidiacea
Class Larvacea
Class Thaliacea

Answer 524

A

also Tunicata
Tunic
no metamerism
eucoelom as pericardium

Answer 525

A

tunicin cellulose-like fibrous material

Answer 526

A

sea squirts
sessile suspension feeders
solitary and colonial forms

Answer 527

A

epidermis secreted tunicin + protein
hemal channels w/ wandering blood cells
spicules, fibrous material

Answer 528

A

cartilaginous structure supporting the gills in protochordates and lower vertebrates
buccal siphon, atrial siphon
w/ pharyngeal mucus net to catch particles that go through perforated pharynx

Answer 529

A

zooids interconnected by stolons
zooids rise from basal mat of shared tunic
zooids entirely embedded in shared tunic

Answer 530

A

invasive species of colonial tunicate, aggressive space competitior

Answer 531

A

Ascidian, source of anti-cancer drug ‘yondelis’ - PharmaMar, now synthetically manufactured

Answer 532

A

hermaphroditic
broadcast spawn
eggs w/ self/non-self recognition
tadpole larva

Answer 533

A

tadpole
short-lived, non-feeding
tail w/ notochord, dorsal hollow nerve chord, muscles
adhesive papillae
start of branchial basket

Answer 534

A

tadpole attaches to substrate w/ adhesive papillae (anterior end)
retraction of tail (apoptosis)
90º rotation of viscera

Answer 535

A

internal organs in the main cavities of the body, especially those in the abdomen

Answer 536

A

planktonic, 1-2mm
disposable gelatinous house
pharynx w/ 2 stigmata, mouth, anus, gut all in ‘head’
tail w/ notochord and dorsal hollow nerve chord

Answer 537

A

secreted by epidermal epithelium (4-8/day)
blown up by tail thrashing 
captures food particles
escape opening
pre-filters
food-concentrating filters
animal (mouth, tail)
excurrent opening

Answer 538

A

evolutionary change in time of appearance or rate of development of a character relative to other characters
e.g. somatic tissues vs reproductive tissues

Answer 539

A

somatic tissue arrested development, reproductive tissue development = sexually mature ‘juvenile’
possibly why larvacean looks similar to Ascidian tadpole

Answer 540

A

paedomorphosis

peramorphosis

Answer 541

A

adult of a descendant is similar in appearance to the juvenile (larva) of its ancestor

Answer 542

A

pelagic, colonial (at least some stages)
pharyngeal cilia for swimming and feeding
individuals resemble adults ascidians

Answer 543

A

pyrosomes, up to 10+m long
hollow pelagic tubes, closed at one end, walls contain many zooids
communal tunic
bioluminescent

Answer 544

A

perforated pharynx, siphons, like mini ascidian

exhaling water released into lumen of colony - expelled out colony aperture - propels colony along

Answer 545

A

no interconnected neurons but coordinated movements

chain rxn - organism hits something - flashes- neighbour detects w/ photoreceptor - flashes - propagate message

Answer 546

A

Class Enteropneusta

Also Class Pterobranchia but not for our purposes

Answer 547

A

Acorn worm (anterior looks like acorn)
live in soft sediment
secrete a lot of mucus
eucoelomate

Answer 548

A

tripartite: proboscis, collar, trunk

tricoelomic (enterocoely similar to echinoderm)

Answer 549

A

peristaltic muscular contractions of proboscis
proboscis w/ cilia, mucus - pick up particles and carry posteriorly to move sed out of way - start burrowing motion- muscularly continue burrowing

Answer 550

A

crawl up burrow to surface, lay proboscis on surface, cilia ensnare particles, carry to mouth
back up to surface to release fecal casting

Answer 551

A

2 sets of perforations in external body wall = gill pores, perforated pharynx in dorsal region
ingested water travels out branchial pores and then external gill pores

Answer 552

A

D and V intraepithelial nerve cords (like sea star)
intra-epithelial nerve plexus (nerve tails run out to all parts of body)
hollow dorsal nerve cord in collar

Answer 553

A

ciliary activity and muscular contractions

Answer 554

A

Peramorphosis

Answer 555

A

short region in collar

intraepithelial nerve cord sinks down and pinches off to become a d.h.n.c.

Answer 556

A

dioecious
larva morphologically similar to holothurian
broadcast spawn
ciliated larval stage may feed for months

Answer 557

A

larval morphology (similar to some groups, holothurians)
intraepithelial nerve system (found in sea stars and trunk region of hemichordates)

Answer 558

A

pharyngeal perforations

dorsal hollow nerve cord (collar)

Answer 559

A

mostly planktonic, swim but not strong enough to resist current
all marine and carnivorous 
100-150spp., but large individual #'s
mm - 1.5m
often translucent

Answer 560

A

gelatinous - highly hydrated mesoglea (similar to cnidaria)
tentacles
comb rows/plates
mouth up - pharynx - stomach - anal pores
gastrovascular canals

Answer 561

A

2, originate from pits (pentacular sheaths), can be retracted, have side branches (tentilla) loaded w/ collocytes

Answer 562

A

8 rows of comb plates (ctenes), used for swimming, extend from oral surface down

Answer 563

A

large ciliary structures known
thousands of cilia in a row = plate
move in unison, out of stroke down comb row - wave propagates down comb row
cilia connected by interciliary links

Answer 564

A

up to 2mm

largest animals that locomotive by cilia

Answer 565

A

effective stroke is towards aboral end
move through water column with mouth leading
beat frequency can slow and switch directions

Answer 566

A

release sticky adhesive
single use only
differentiate from interstitial cells 
complex, used to capture prey 
head covered in intercellular granules
straight filament = elongate nucleus

Answer 567

A

myoepithelial cells in epidermis

bona fide muscle cells within ‘mesoglea’

Answer 568

A

MAY suggest that ctenophores are true mesodermal animals and therefore triploblastic (no evidence)

Answer 569

A

nerve net in epidermis and mesoglea

aboral (apical) sensory organ (rudimentary brain)

Answer 570

A

mostly statocyst (gravity sensor)
transparent CaCO3 dome over statolith on 4 balancers

Answer 571

A

bundles of hundreds of cilia

tracks bifurcate away from dome

Answer 572

A

turn - statolith moves - pressure on 1+ balancer = signal down comb row = more rapid beating of cilia to make that side move up and straighten out
detect direction of gravity to know which way is up

Answer 573

A

prey captured w/ sticky collocates on tentilla
tentacle retracts
ctenophore spins to waft tentacle over mouth

Answer 574

A

possibly cnidocyte stealer

feed on hydromedusa tentacles, place cnidocytes in ctenophore tentacles (observed in rare species)

Answer 575

A

Venus’ Girdle

long, thin, flat, ctenophore

Answer 576

A

lobate ctenophore
invasive species, invaded black sea, no natural predator, more weight than annual world fish catch
capture prey w/ muscular oral lobes

Answer 577

A

‘swimming mouth’, no tentacles, feeds on other ctenophores, introduced to bring down population of mnemiopsis

Answer 578

A

macrociliary teeth around margins of mouth, prevent prey from escaping, formed of cilia

Answer 579

A

look like flatworms

lack comb rows in adult stage

Answer 580

A

asexual - benthic ctenophore only
sexual - simultaneous hermaphrodites
-gametes from gastrodermis
-cydippid larva (look like pleurobrachia)

Answer 581

A

sessile, colonial, lophophore, defense strategies, polymorphic colonies

Answer 582

A

Avicularium

Answer 583

A

Conchifera (Cephalopoda, Scaphopoda, Bivalvia, Gastropoda)

Acquifera (Polyplacophora, Chaetodermomorpha, Neomeniomorpha)

Answer 584

A

Gastropoda

Answer 585

A

endogastric shell

representative of torsion

Answer 586

A

2 ctenidia (left, right)

Answer 587

A

Caenogastropoda (predatory, use proboscis)

Answer 588

A

mid-esophageal gland in other gastropods

Answer 589

A

adapted for suspension feeding

Answer 590

A

exogastric shell

Answer 591

A

pseudocoel

Answer 592

A

Chelicerata

Mandibulata

Answer 593

A

Merostomata (horseshoe crabs)
Arachnida
Pycnogonida (sea spiders)

Answer 594

A

Pancrustacea

Myriapoda (centipede, millipede)

Answer 595

A

Hexapoda
Malacostraca
Copepoda
Cirripedia

Answer 596

A

Euphausiacea
Stomatopoda
Pericardia
Decapoda

Answer 597

A

Caridea
Astacidea
Anomura
Brachyura

Answer 598

A

1st appendages = chelicera, feeding

2nd appendages = pedipalps, variety of fn, not very derived

Answer 599

A

head
thorax
abdomen

Answer 600

A

complete reorganization of body

Answer 601

A

Vibraculum

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BIOL 321 Part II Flashcards

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