BIOL 321 LAB

Question 1

a diagram of a hierarchical system of nested sister groups of taxa

Answer 1

cladogram

Question 2

meaning of ‘dissection’

Answer 2

exposing to view

Question 3

what are dissecting microscopes used for

Answer 3

viewing are, relatively opaque objects

Question 4

dissecting microscope lens system is designed to

Answer 4

maximize working distance between object lenses and the subject

Question 5

illumination in a dissecting microscope

Answer 5

above
side
below

Question 6

side illumination

Answer 6

reflected light

Question 7

illumination from below

Answer 7

transmitted light

Question 8

compound microscope is used for

Answer 8

observing fine details in small specimens that have been rendered transparent

Question 9

compound microscope illumination

Answer 9

generally transmitted light

built-in illuminator concentrates light beams through condenser

Question 10

compound microscope objecties

Answer 10

scanning (4x)
low power (10x)
high power (40x)
oil immersion lens (100x)

Question 11

most frequent objective used for studying invertebrates

Answer 11

low power 10x

Question 12

primary magnification power

Answer 12

objective lens

Question 13

Parfocal

Answer 13

objects remain in focus when a different objective is rotated into position

Question 14

what does the ocular lens do

Answer 14

convert the magnified real image from objective lens into a magnified virtual image

Question 15

objects remain in the centre of the field when a different objective is rotated into position

Answer 15

parcentral

Question 16

how to obtain maximum resolution

Answer 16

Koehler illumination

center and focus illumination system

Question 17

10x objective field diameter

Answer 17

1.6mm

Question 18

40x objective field diameter

Answer 18

0.4mm

Question 19

calculate magnification of a drawing

Answer 19

size of drawing / size of object

Question 20

calculating scale bar

Answer 20

(drawing length)/(specimen length) = (scale bar length)/x

Question 21

Phylum Porifera Classes

Answer 21

Class Calcarea
Class Hexactinellida
Class Demospongiae

Question 22

Sponges lack

Answer 22

mouth
digestive cavity
nerves
muscles

Question 23

how sponges eat

Answer 23

most capture bacteria/phyto. and digest in intracellular food vacuoles

Question 24

‘carnivorous’ sponges

Answer 24

Cladorhizidae

eat small zooplankton - break into small pieces, phagocytize, digest with intracellular vacuoles

Question 25

sponge symmetry

Answer 25

some radially symmetric, most asymmetrical

Question 26

sponge body plan

Answer 26

two photo-epithelial layers sandwiching a layer of connective tissue

Question 27

outer surface of sponge body

Answer 27

pinacoderm

Question 28

internal surfaces (canals and chambers) of sponge body

Answer 28

choanoderm

Question 29

connective tissue layer of sponge body

Answer 29

mesohyl

Question 30

cells in outer layer of sponge body

Answer 30

pinacocytes

Question 31

inside of the mesohyl

Answer 31

collagen fibres, ameboid cells, skeletal elements

Question 32

cells in inner layer of sponge body

Answer 32

choanocytes

Question 33

sponge skeletal elements

Answer 33

biomineralized spicules and/or organic cord mesh

Question 34

organic mesh skeletal element of some sponges

Answer 34

spongin

Question 35

choanocyte function

Answer 35

use flagella to propel water through sponge body

capture and digest food particles suspended in water

Question 36

grades of complexity in sponges

Answer 36

Asconoid
Syconoid
Leuconoid

Question 37

Asconoid

Answer 37

minute
vase-shaped
choanocytes line a central spongocoel

Question 38

central spongocoel

Answer 38

atrium

Question 39

Syconoid

Answer 39

larger
vase-shaped
choanocyte-lined chambers each open directly into central spongocoel

Question 40

Leuconoid

Answer 40

massive form

spongocoel replaced with extensive system of choanocyte-lined chambers interconnected by canals

Question 41

advantage to sponges increasing surface area

Answer 41

increased efficiency in filter water and capturing food

Question 42

Class Calcarea features

Answer 42

exclusively marine
CaCO3 spicules
all 3 architecture types
individuals can cluster, but live independently
buds occasionally appear at base of mature specimens

Question 43

asconoid Calcarea observed in lab

Answer 43

Leucosolenia

Question 44

syconoid Calcarea observed in lab

Answer 44

Grantia

Scypha

Question 45

Class Demospongiae

Answer 45

All freshwater sponges
Most marine sponges
Leuconoid
most local intertidal sponges have encrusting growth

Question 46

Demosponge skeleton

Answer 46

anastomosing ropes of proteinaceous spongin and/or siliceous spicules
NO CaCO3

Question 47

Class Hexactinellida

Answer 47

glass sponges

pinacoderm and choanoderm are syncytial

Question 48

Hexactinellida skeleton

Answer 48

chitin

6-pointed silica dioxide spicules

Question 49

syncytium

Answer 49

a multinucleate animal tissue without internal cell boundaries

Question 50

Hexactinellid observed in lab

Answer 50

Aphrocallistes

Question 51

Gemmules

Answer 51

a dormant structure entered in to mostly by freshwater sponges, during times of unfavourable conditions

Question 52

significance of gemmules

Answer 52

more resistant to desiccation/freezing/anoxia

protect sponge

Question 53

secondary metabolites

Answer 53

organic molecules not part of biochemical pathways involved in metabolism of nutrient molecules

Question 54

Poriferans manufacture secondary metabolites to

Answer 54

deter predators
deter competitors for living space
inhibit pathogens

Question 55

Halichondria secondary metabolites

Answer 55

unpleasant odour when rubbed

local species

Question 56

why sponges are rarely overgrown by other sessile organisms

Answer 56

defensive chemicals (secondary metabolites)

Question 57

importance of sponge spicules

Answer 57

support- body would collapse without

taxonomy - shape and mineral composition distinguish species

Question 58

easy way to tell if sponge is Calcarea

Answer 58

acid test (dissolves CaCO3)

Question 59

spicule shapes, axes

Answer 59

suffix -axon
# of axes
monoaxons
triaxons

Question 60

spicule shapes, number of points

Answer 60

suffix -actine
# of points
triactine
hexactine

Question 61

demosponge spicules

Answer 61

most are monoaxons

Question 62

Grantia spicules

Answer 62

triaxon and triactine

Question 63

glass sponge spicules

Answer 63

triaxon and hexactine

Question 64

Carnivorous sponges tend to inhabit

Answer 64

the deep sea

Question 65

shallow-water Cladorhizidae in Salish Sea

Answer 65

Asbestopluma occidentalis
18m
co-occur w/ hexactinellid sponges

Question 66

Asbestopluma occidentalis reproduction

Answer 66

adult disassociates tissues facilitating larval release and dispersal
larvae have actively beating cilia (no swimming observed)
parent reaggregates into spherical balls of undifferentiated tissue that can disperse and settle

Question 67

Asbestopluma occidentalis feeding

Answer 67

observed capturing Artemia nauplii using anisochelae spicules

Question 68

nauplii

Answer 68

first larval stage of many crustaceans, having an unsegmented body and a single eye

Question 69

Subphylum’s in Phylum Cnidaria

Answer 69

Medusozoa

Anthozoa

Question 70

Class’s in Subphylum Medusozoa

Answer 70

Staurozoa s.g. to
Hydrozoa s.g. to
Scyphozoa s.g. w
Cubozoa

Question 71

Class’s with free-floating Medusae

Answer 71

Hydrozoa
Scyphozoa
Cubozoa

Question 72

Example of Class Hydrozoa from lab

Answer 72

Obelia

Siphonophores

Question 73

Example of Class Scyphozoa from lab

Answer 73

Aurelia

Question 74

Class’s in Subphylum Anthozoa

Answer 74

Octocorallia

Hexacorallia

Question 75

Class Octocorallia includes the

Answer 75

soft corals

sea pens

Question 76

Example of Class Hexacorallia from lab

Answer 76

Anthopluera

Question 77

Class Hexacorallia includes the

Answer 77

sea anemones

stony corals

Question 78

Cnidarian size

Answer 78

1mm - 2m in diameter

Question 79

Cnidaria germ layers

Answer 79

epidermis covers body surface
gastrodermis lines body cavity (GVC)
Mesoglea between

Question 80

Mesoglea

Answer 80

collagen fibres
extracellular matrix
ameboid cells (in most clades)

Question 81

What do Cnidarians have that Poriferans do not

Answer 81

true gut
nerve cells
cnidocysts (unique to them)

Question 82

Cnidarian GVC

Answer 82

digests ingested food

circulate nutrients and gases throughout body

Question 83

Cnidarian symmetry

Answer 83

most radial

sea anemones, corals = biradial

Question 84

biradial symmetry

Answer 84

similar parts are located to either side of a central axis and each of the four sides of the body is identical to the opposite side but different from the adjacent side

Question 85

Alternation of generations

Answer 85

in most Medusazoans
asexual polyp stage
sexual medusa stage
polyp, medusa both diploid, only egg is haploid

Question 86

Polymorphism

Answer 86

colonial individuals develop differently morphologically
preform different specialized jobs (feeding, reproduction, defense)
genetically identical - express diff. parts of the genome

Question 87

Cnidarian lifestyle

Answer 87

All carnivorous

prey capture facilitated by cnidocytes (in high density on tentacles)

Question 88

Nematocyst function

Answer 88

prey capture
defense
aid in digestion

Question 89

Hydra

Answer 89

freshwater
class Hydrozoa
no medusa stage
2 germ layers, cnidocytes only in epidermis

Question 90

Hydra morphology

Answer 90

mouth at apex of hypostome 
ring of tentacles at base of hypostome 
body column, gastric region, stalk
basal disk (adhesive)
budding zone

Question 91

hypostome

Answer 91

the oral tip surrounded by tentacles in hydrozoan cnidarians (cone-shaped)

Question 92

Hydra budding zone

Answer 92

junction of gastric region and stalk

where new polyps arise as asexual buds

Question 93

Hydra reproduction

Answer 93

bud forms on stalk as simple evagination - distal end of bud forms mouth + tentacles - bud drops off

Question 94

acontia

Answer 94

thread-like pieces of the body found near the pedal disc, attached to septal filaments inside the body, at times flow in/out of GVC

Question 95

Medusazoans that stray from typical alternation of generations homology

Answer 95

Staurozoans - free-living medusa completely absent

Hydrozoa - some members exhibit secondary loss of medusa stage (e.g. Hydra)

Question 96

Morphological character in common with all Medusazoans

Answer 96

linear mitochondrial chromosome

other Cnidarians, most eukaryotes have circular

Question 97

Scyphozoa

Answer 97

scyphomedusa larger, more conspicuous life stage 
some freshwater
cnidocytes in epidermis + gastrodermis
gametes originate from gastrodermis
ameboid cells in mesoglea 
frilly oral arms 
thick mesoglea

Question 98

cnidarian medusa swimming

Answer 98

rhythmic contraction of epitheliomuscle cells (circular muscle sheet on underside of bell)

Question 99

manubrium

Answer 99

a tubular structure that contains the mouth

Question 100

Scyphozoa digestion

Answer 100

prey captured with cnidocytes on tentacles/oral arms, transferred to mouth at end of manubrium, ingested, conveyed to stomach, distributed to 4 gastric pouches, partially digested enzymatically - digestion completed intracellularly w/i gastrodermal cells – then circulated via ciliated gastrovascular canals

Question 101

Scyphozoa gastric pouces

Answer 101

contain short gastric filaments (tentacles) that secrete digestive enzymes

Question 102

Scyphozoa gastrovascular canals

Answer 102

adradial (unbranched)
interradial, perradial (branched)
GV canals connect gastric pouces to ring canal (around periphery of bell)

Question 103

common moon jellyfish

Answer 103

Aurelia 
floats close to surface
local
short tentacles and manubrium 
feeds on small plankton 0.2-2mm

Question 104

Aurelia feeding

Answer 104

slow contraction of bell – draws prey toward medusa – recovery stroke – sucks prey into subumbrellar cavity – captured, subdued by nematocysts in oral arms
feed on smaller organisms than other scyphomedusae b/c of short oral arms

Question 105

sensory cells around bell of Scyphomedusae

Answer 105

rhopalia
8 small ‘knobs’
statocyst, pigment spot, cluster of photoreceptor cells, chemoreceptor cell

Question 106

Statocyst

Answer 106

gravity receptor

Question 107

Initiates swimming in Scyphomedusae

Answer 107

rhopalia - neurons in cell bodies - send neurites to swim muscle - initiate swimming pulsation

Question 108

subumbrellar

Answer 108

located beneath the umbrella

Question 109

gonochoristic

Answer 109

dioecious

male and female reproductive organs in separate individuals

Question 110

Scyphozoan gametes

Answer 110

gonochoristic
gametes arise from gastrodermal epithelial cells in gastric pouches
mature gametes exit through mouth
eggs lodged if pits of oral arms, fertilized, develop into planulae

Question 111

Scyphozoa planulae

Answer 111

ciliated
non-feeding
brief free-swimming stage
settle to bottom, attach to substrate, develop into scyphistoma

Question 112

Scyphistoma

Answer 112

polyp scyphozoa form
feeds
reproduces asexually (budding, strobilation)

Question 113

Strobilation

Answer 113

sequential transverse fissions of oral end of strobila

strobila is reproducing form of scyphistoma

Question 114

Immature medusae released from strobila

Answer 114

ephyrae

Question 115

Aurelia life cycle

Answer 115

medusa – egg – fertilization – planula – scyphistoma – possibly budding – strobila – ephyra – development – medusa

Question 116

Class Hydrozoa characteristics

Answer 116

polyps usually form colonies
mesoglea lacks cells, cnidocytes
gametes arise from epidermis
no oral arms

Question 117

Hydrozoan medusa

Answer 117

Hydromedusae
smaller, deeper bell 
many have velum 
no rhopalia 
concentration sensory cells at base of tentacles (photoreceptor and statocyst)

Question 118

velum

Answer 118

rim of muscular tissue projecting inward at peripheral margin of bell
controls size of subumbrellar aperture

Question 119

why do medusa have more sophisticated sensory structures than polyps

Answer 119

because they are motile, they have to constantly monitor their surroundings for danger

Question 120

hydrozoan polyp colony

Answer 120

hydroid
buds remain attached
may exhibit polymorphism

Question 121

feeding hydroid polyps

Answer 121

gastrozooids

Question 122

reproductive hydroid polyps

Answer 122

gonozooids

Question 123

defensive hydroid polyps

Answer 123

dactylozooids

Question 124

living tissue of hydroid

Answer 124

coenosarc (polyp + stem tissue)

Question 125

protective hydroid covering

Answer 125

perisarc

chitinous sheath surrounding coenosarc

Question 126

hydroid connected to substrate by

Answer 126

stolons - network of horizontal tubes

Question 127

Hydroid in lab

Answer 127

Obelia

Question 128

gonozooid structure

Answer 128

stalk w/ saucer-like medusa buds

enclosed in transparent, chitinized, vase-shaped theca w/ opening at top

Question 129

Obelia life cycle

Answer 129

dioecious adult medusa - spawn gametes - fertilization - zygote - planula larva - settles - metamorphosis - budding – form hydroid colony – gonozooid produces medusa w/ 8 statocysts – grow/develop tentacles and gonads

Question 130

Class Staurazoa characteristics

Answer 130

no alternation of generations
elaborate polyp stage 
stalk on exumbrellar surface 
tentacles organized in to clusters around bell margin
basal plate secretes adhesive
anchors

Question 131

Staurazoa anchors

Answer 131

small knobs around bell
may form temporary substrate attachment
facilitate looping movement

Question 132

Subphylum Anthozoa characteristics

Answer 132

all marine
no medusa
gullet
mesoglea contains amoeboid cells (like Scyphozoa)
GVC subdivided by nematocyst-bearing septa (folds of gastrodermis)
mostly dioecious

Question 133

gullet

Answer 133

actinopharynx
Anthozoan body turns in at mouth to form gullet
muscular
runs down from mouth to GVC

Question 134

Anthozoa coelenteron

Answer 134

GVC

Question 135

siphonoglyph

Answer 135

ciliated groove at one or both ends of mouth
extends into pharynx
used to create currents of water into the pharynx

Question 136

Anthozoa acontia

Answer 136

threads at end of mesenteries below the filaments, other end free, extraordinarily numerous nematocysts, can be protruded through the mouth or special pores in body-wall for defense or paralyses of prey

Question 137

Anthozoan Classes

Answer 137

Class Octocorallia

Class Hexacorallia

Question 138

Octocorallia

Answer 138

aka Alcyonaria
8 complete septa 
8 tentacles 
all colonial 
polyps connected by mesoglea + gastrodermal tube
pinnate tentacles

Question 139

Hexacorallia

Answer 139

aka Zoantharia
septa in multiples of 6
non-pinnate tentacles
solitary or colonial

Question 140

solitary Hexacorallia

Answer 140

sea anemones

Question 141

colonial Hexacorallia

Answer 141

hermatypic corals

Question 142

pinnate

Answer 142

side branches

Question 143

Anthozoa reproduction

Answer 143

swimming planula – settles on substrate – metamorphosis – young polyp – grows to become sexually mature
colonial corals - original polyp buds in to the entire colony
anemones can also reproduce asexually

Question 144

Have cnidocytes in gastrodermis

Answer 144

Scyphozoa - Yes
Anthozoa - Yes
Hydrozoa - No
(secrete digestive enzymes to aid digestion)

Question 145

where is calcareous biomineral deposited in Anthozoans

Answer 145

Hexacorallia - external CaCO3 skeleton under polyps

Octocorallia - internal CaCO3 spicules w/i mesoglea

Question 146

hydromedusa Aglantha digitale

Answer 146

uniquely evolved giant axons, used to swim in 2 distinct ways (escape, slow)

Question 147

how Aglantha digital can swim in two distinct ways

Answer 147

axons can conduct Ca and Na spikes (at separate times)

Question 148

Phylum Platyhelminthes taxonomy

Answer 148

Class Turbellaria s.g. to
Class Cestoda s.g. to
Class Trematoda

Question 149

Lab examples of Class Turbellaria

Answer 149

Dugesia

Question 150

Lab example of Class Cestoda

Answer 150

Taenia

Question 151

Lab example of Class Trematoda

Answer 151

Opisthorchis sinensis

Question 152

Platyhelminthes characteristics

Answer 152

bilaterally symmetric
dorsoventrally flattened
acoelomate
GVC (digestion + circulation)
no anus 
mm's - m's
free-living/parasitic

Question 153

Platyhelminthes reproduction

Answer 153

hermaphroditic
complex reproductive system
gametes arise from mesoderm
gametes fill space between epidermal epithelium and gastrodermal epithelium

Question 154

Platyhelminth mesothelium gives rise to

Answer 154

gametes
muscle cells
parenchymal cells

Question 155

Platyhelminthe excretion

Answer 155

protonephridium

Question 156

Platyhelminthe locomotion

Answer 156

muscles

ventral cilia

Question 157

Class Turbellaria

Answer 157

mostly free-living
rhabdite
regenerate lost body parts

Question 158

Class Turbellaria name meaning

Answer 158

whirlpool

swirling motion of particle near ciliated epidermis

Question 159

rhabdite (Turbellaria)

Answer 159

rod-like epithelium secretions
unique to Turbellaria
swells on contact w/ water, forms thick mucus
adhesion, locomotion, defensive

Question 160

neoblasts

Answer 160

Turbellaria
undifferentiated pluripotent cells in parenchyma
responsible for regeneration

Question 161

pluripotent

Answer 161

cells having the capability to differentiate into a large number of different cell types
‘stem cells’

Question 162

Turbellaria reproduction

Answer 162

asexually -budding, transverse fission

sexually

Question 163

Turbellaria sexual reproduction process

Answer 163

non-self fertilizing hermaphrodites
penis - genital pore - sperm deposited in to copulatory bursa - sperm moves up oviducts to ovaries - fertilizes egg - egg passes down oviduct - invested w/ yolk cells - discharged from yolk gland - encapsulated - passed out genital pore - fastened to objects (e.g. rocks)

Question 164

Turbellarian post-reproduction

Answer 164

after breeding reproductive system degenerate and is regenerated at next sexual period

Question 165

Important Turbellarian body parts

Answer 165

Intestinal caeca
eye spots
auricles
pharynx
pharyngeal cavity

Question 166

Turbellarian guts

Answer 166

Syndesmis - commensal Turbellarian in echinoderm gut- simple unbranched gut cavity
Dugesia - 3 principle branches (caeca) with short side-branches
Leptoplana (marine polyclad) - many branches

Question 167

Turbellarian feedings

Answer 167

largely carnivorous
mid-ventral mouth at end of protrusible pharynx
pharyngeal enzymes initiate digestion
intestinal enzymes continue digestion

Question 168

Turbellarian excretion

Answer 168

ammonia diffused across body surface

protonephridia assist excretion and osmoregulation

Question 169

Turbellaria locomotion

Answer 169

much-ciliary gliding
muscular crawling
swimming

Question 170

Class Trematoda

Answer 170

entirely parasitic

2-3 hosts

Question 171

Opisthorchis sinensis

Answer 171

Oriental/Chinese liver fluke
bile ducts of humans (definitive host)
intermediate hosts - snails, fish
prevalent in Southeast Asia

Question 172

Trematode major body parts

Answer 172

mouth surrounded by oral sucker
ventral sucker
excretory pore (nephridiopore)
muscular pharynx, short esophagus, 2 intestinal caeca

Question 173

Trematode reproductive organs

Answer 173

2 multi lobed testes
seminal receptacle (sperm storage)
single ovoid ovary (ova production)
vitelline glands (yolk)
coiled uterus (filled with encapsulated, fertilized eggs)

Question 174

Trematode life cycle characteristics

Answer 174

complex
1+ intermediate host
several larval forms that undergo asexual division

Question 175

asexual reproduction by embryonic larval stages

Answer 175

polyembryony

Question 176

Trematoda life cycle

Answer 176

adult in bile ducts - eggs in feces - eaten by freshwater snail - ciliated miracidium - hatches, burrows through intestinal wall - sporocyst - polyembryony - redial - polyembryony - cercariae - rupture body wall - free-swimming - burrow in to fish (carp) within 24-48hrs - encyst - metacercariae - human eat raw fish

Question 177

Class Cestoda

Answer 177

tapeworms
endoparasites
specialized for life w/i host intestine
scolex, neck, proglottids (strobila)

Question 178

Cestode specializations

Answer 178

no cilia
tegument
no mouth
no digestive cavity

Question 179

tegument

Answer 179

syncytial epidermis specialized for direct absorption of nutrients

Question 180

scolex

Answer 180

Cestoda head region

anchor for adhering to intestine

Question 181

Cestoda neck

Answer 181

generates proglottids

Question 182

Cestoda strobila

Answer 182

series of proglottids

body segments that contain full m+f reproductive organs

Question 183

tapeworm life cycle

Answer 183

most have 2 hosts
adult in carnivore - gravid proglottid released in feces - encysted cysticercus in herbivore - larvae burrows in to blood vessel - carried to muscle - herbivore eaten by carnivore - scolex everts – attaches to gut

Question 184

Trematoda vs Cestoda attachment structures

Answer 184

Trematoda - 2 suckers (oral, ventral)

Cestoda - hooks (end of scolex) + 4 suckers

Question 185

Trematoda vs Cestoda offspring numbers

Answer 185

Cestoda - eggs –> 2 stages of polyembryony

Trematoda - multiple sexual proglottids w/ many larvae each, no polyembryony

Question 186

Turbellarian vs Cestoda epidermis

Answer 186

Turbellarian - ciliated, glands, rhabdite

Cestoda - no cilia, syncytial (absorptive) - seems more ‘basic’ but is actually specialized

Question 187

Should production of proglottids by cestodes be considered a form of asexual reproduction

Answer 187

not in species that do not self-fertilize
1 proglottid can fertilize with another proglottid on the same worm (or with a different worm) but not within that proglottid
some species can self-fertilize w/i the same proglottid

Question 188

Phylum Rotifera

Answer 188

microscopic, aquatic, mostly freshwater
head, neck, trunk, foot
corona
mastax, trophi

Question 189

corona

Answer 189

Rotifera crown of cilia

swimming, feeding

Question 190

mastax

Answer 190

Rotifera pharynx

has trophi jaws to grind up food

Question 191

Rotifer epidermis

Answer 191

contains thick layer cytoskeletal filaments (not moulted)

makes outer surface rigid

Question 192

Rotifer trunk

Answer 192

stomach
gonad (usually an ovary)
protonephridia
(anus at trunk/foot junction)

Question 193

Rotifer toes

Answer 193

at end of foot

contain cement gland ducts (attachment)

Question 194

unique reproduction in Rotifers

Answer 194

pathogenesis

part of their amictic/mictic life cycle

Question 195

possible value of parthenogenesis

Answer 195

don't have to find a mate
boosts population (only produce more f's)
genetic stability

Question 196

how do rotifers survive ephemeral/freezing water bodies

Answer 196

In mictic stage of life cycle they reproduce asexually and the fertilized eggs secretes a protective coating and enters diapause

Question 197

Phylum Annelida phylogeny

Answer 197

Errantia - Neriedidae

Sedentaria - Clitellata, Terebellidae, Echiuridae, Sabellidae, Siboglinidae

Question 198

Errantia and Sedentaria taxa

Answer 198

were abandoned in 1970s

now appear to be monophyletic, true clades

Question 199

Phylum Annelida characteristics

Answer 199

extremely diverse
eucoelomate
most have metameric body
mouth and anus, unidirectional gut

Question 200

Annelid habitat

Answer 200

diverse

most marine

Question 201

Annelid past phylogeny

Answer 201

thought to be closely related to arthropods (metamerism, nervous system)
3 Subclasses - Polychaeta, Oligochaeta, Hirudinea

Question 202

molecular data

Answer 202

nucleotide sequences of slowly evolving nuclear and mitochondrial genes
amino acid sequences of proteins

Question 203

major revisions of Annelid phylogeny

Answer 203

1. metamerism found to be convergent
2. Echiuran, Sipuncula, Pogonophora found to belong within Phylum Annelida
3. Polychaeta = paraphyletic

Question 204

results of major revision 1. in Annelid phylogeny (metamerism convergent)

Answer 204

-Arthropods moved to Ecdysozoa w/ other moulters -Annelids + Mollusks placed in Lophotrochozoa

Question 205

results of major revision 2. in Annelid phylogeny (Echiuran, Sipunculan, Pogonophora belong in Annelida)

Answer 205

not all Annelids display metamerism as adults

Question 206

Echiuran metamerism

Answer 206

metameric ganglia along ventral nerve cord during early development

Question 207

Sipuncula metamerism

Answer 207

none

Question 208

Echiuran, Sipunculan reduced/lossed metamerism

Answer 208

secondary loss

Question 209

Annelid chaetae

Answer 209

not present in Hirudineans, Sipunculans

secondary loss

Question 210

an ancestral metamere contains

Answer 210

pair of ganglia 
paired peripheral nerve tracts along ventral nerve cord
paired metanephridia 
blocks of circular/longitudinal muscle
segmental blood vessels 
left/right eucoelomic compartments

Question 211

anterior part of Annelid head

Answer 211

prostomium

not a true metamere

Question 212

posterior end of Annelid

Answer 212

pygidium

not a true metamere

Question 213

eucoelom

Answer 213

internal, fluid-filled compartment lined by mesoderm derived epithelium (mesothelium)

Question 214

Annelid eucoelom

Answer 214

facilitates locomotion (like hs skeleton)
circulates body fluids
reproduction
excretion, osmoregulation

Question 215

innovation of eucoelomic secondary body compartments allows

Answer 215

efficiency of functions – evolution of active movement by large animals

Question 216

Annelid movement

Answer 216

crawling
burrowing
tube-dwelling
swimming

Question 217

Errantids

Answer 217

mobile - crawling/swimming 
well-developed parapodia, aciculae
head appendages- sensory reception
cephalic eyes
nuchal organs
eversible pharynx w/ jaws

Question 218

Sedentarids

Answer 218

sedentary - buried in substrate, inhabit tubes
reduced/lacking parapodia, no acicula
appendages for food capture not sensory
some eversible pharynx, no jaws

Question 219

Sedentarids tubes

Answer 219

sand grains
calcium carbonate
proteinaceous secretions

Question 220

acicula

Answer 220

chitinous rod

support parapodia

Question 221

active life style requires

Answer 221

capacity for sensing diverse environmental stimuli

Question 222

nuchal organs

Answer 222

non-visible chemosensory structures

Question 223

Annelid parapodia structure

Answer 223

upper lobe = notopodium
lower lobe = neuropodium
chitinous rods = acicula
chaetae at end of acicula

Question 224

Nereis locomotion

Answer 224

Errantid - active, well-developed parapodia
parapodia on either side of metamere out of phase
propagate effective stroke down length of worm
curve body for faster movement

Question 225

Lumbricus movement

Answer 225

earthworm, Sedentarid - lack parapodia

peristaltic movements

Question 226

why are the longitudinal muscles of Nereis much more massive than the circular muscles

Answer 226

longitudinal muscles for body undulations
movement is along the longitudinal axis, requiring longitudinal muscles
no peristaltic movement

Question 227

what are longitudinal and circular muscles of earthworm developed approximately equal

Answer 227

peristaltic
muscles are used antagonistically for movement - balance each other out
both are used equally for movement

Question 228

what is the role of chaetae in Nereis

Answer 228

traction in crawling

surface area/paddles for swimming

Question 229

what is the role of chaetae in Lumbricus

Answer 229

erect chaetae hold position in burrow (anchor)

Question 230

what is the role of a fluid filled compartment in Nereis and Lumbricus

Answer 230

N - structural - supports body during movement

L - movement - transmits force for peristaltic movement, hydrostatic skeleton

Question 231

between metameres in Lumbricus

Answer 231

intersegmental septa

Question 232

animals that lack efficient food processing and digestion

Answer 232

can be large but incapable of energetic locomotory movements - ambush prey, escape from predators, move from inhospitable environment

Question 233

Active movement by a large animal requires

Answer 233

high metabolic rate from:
efficient food digestion
efficient nutrient/gas circulation to tissues

Question 234

one-way gut

Answer 234

facilitates digestive efficiency

-food sequentially processed by differently specialized gut regions

Question 235

Lumbricus circulation of gases and nutrients

Answer 235

ciliated eucoelom

dorsal, ventral, segmental blood vessels

Question 236

calciferous glands

Answer 236

associated w/ earthworm esophagus
secrete CaCO3
pH adjustment of food? excretion?

Question 237

typhlosole

Answer 237

internal fold of the earthworm intestine; increased SA for efficient digestion

Question 238

chloragogen tissue

Answer 238

earthworm
glycogen & fat synthesis & storage
hemoglobin synthesis
protein catabolism & urea synthesis

Question 239

Family Nereididae

Answer 239

Errantid Annelid
paired parapodia
eversible pharynx w/ jaws
sensory structures on head (prostomium + peristomium)

Question 240

Nereididae sensory structures

Answer 240

eyes
tentacles
palms
cirri
allow monitoring of environment while foraging, avoid threats

Question 241

Sedentarid Annelids

Answer 241

reduced parapodia
if eversible pharynx present - no jaws
appendages - feeding
suspension feeders (small particles/phytopl.) or deposit feeders (surface film)

Question 242

Sedentarid habitat

Answer 242

sand/mud burrows

tubes - sand grains, CaCO3, proteinaceous

Question 243

selective deposit feeders

Answer 243

grains picked-up, inspected, selectively ingested

Question 244

non-selective deposite feeders

Answer 244

bulk ingest mouthfuls of sediment indiscriminately

Question 245

Family Terebellidae

Answer 245

spaghetti worm
tubes of sand grains
very reduced parapodia 
2 types of tentacles 
selective deposit feeders

Question 246

Terebellidae tentacles

Answer 246

1.long spaghetti-like tentacles for feeding
ciliated groove down length for carrying particles via cilia+mucus
2.branchial tentacles, shorter, coiled/dendritically branched, red (hemoglobin)

Question 247

Why do Terebellids have hemoglobin

Answer 247

tubes often constructed under rocks embedded in sediment - O2 partial pressure can be very low
Hemoglobin helps pull O2 into body

Question 248

Family Sabellidae

Answer 248

feather duster worms
tubes
radioles
suspension feeders

Question 249

Sabellid tube

Answer 249

proteinaceous secretions

attached to solid substrate (often under docks)

Question 250

Sabellid radioles

Answer 250

crown of ciliated tentacles, each w/ 2 rows of short side-branches
capture suspended phytoplankton
particle moves: down side branches - to ciliated groove on central axis - - mouth

Question 251

Family Siboglinidae

Answer 251

benthic, tube-dwelling, marine
opisthosoma
trophosome
anterior branchial filaments (red, hemoglobin)

Question 252

Siboglinid opisthosome

Answer 252

posterior section
only part of worm that is metameric and has chaetae
anchor worm to tube

Question 253

Siboglinid trophosome

Answer 253

endodermal cells form non-structured mass rather than digestive tract
cells filled w/ chemosynthetic bacteria that provide organic carbon

Question 254

chemosynthetic bacteria

Answer 254

oxidize H2S to generate E for carbon fixation

Question 255

Siboglinid branchial filaments

Answer 255

contain hemoglobin

binding sites for oxygen and sulfide

Question 256

Oligochaete sister group

Answer 256

Hiurdinea

Annelida, Sedentaria, Clitellata, Hirudinea

Question 257

Hirudinea, Oligochaeta synapomorphies

Answer 257

hermaphroditic reproductive system (other annelids are dioecious)
clitellum (significance in reproduction)

Question 258

Leeches

Answer 258

ectoparasites or predators
some have thickened cuticle around mouth forming 3 blades
some have eversible pharynx w secretions
2 suckers (oral, posterior)

Question 259

Hirudinea gut

Answer 259

specialized to accommodate large meal (food is mostly water)
well-developed metanephridia (1 pr/metamere)
lateral diverticula = caeca (folded gut wall)

Question 260

Hirudinea locomotion

Answer 260

looping
alternating contraction of circular/longitudinal muscles
body pushes/pulls against suckers
swim- sinusoidal waves of long. muscle contraction

Question 261

Why are Hirudineans dorsoventrally flattened

Answer 261

flattening reduces flexual stiffness - aids in looping

Question 262

function of parapodia in tubiculous annelids

Answer 262

hide from predation
move up for feeding
hold on to tube (anchor)
move around to flush-out tube

Question 263

why do oligochaetes have pharyngeal dilator muscles

Answer 263

to suck-up large amounts of particles as they are non-selective; terebellids are selective and use tentacles to choose particles

Question 264

trends in Siboglinid evolution

Answer 264

levels of sulfide tolerance

type of substrate

Question 265

basal groups of Siboglinids

Answer 265

Lamellibrachia
inhabit soft substrate
slightly elevated sulfide levels

Question 266

derived groups of Siboglinids

Answer 266

hard substrate
high sulphide levels
elevated temperatures