Week 8

Question 1

The lophophorates

Answer 1

Benthic, suspension feeders

Question 2

Lophophorate phyla

Answer 2

Phoronida, Bryozoa, Brachiopoda

Question 3

Spiralia

Answer 3

-Largest clade in protostomes
-Also called lophotrochozoa

Question 4

Protostomes

Answer 4

Include three major clades, the largest being spiralia

Question 5

Lophophore

Answer 5

• Crown of tentacles with a coelomic lumen
• Used for suspension feeding
• Food grooves pass trapped particles from tentacles to mouth opening

Question 6

Phylum Phoronida

Answer 6

• Triploblastic
• Coelomate
• Bilaterally symmetrical
• Unsegmented
• Has lophophore
• U-shaped gut
• Closed circulatory system (anoxic environment, runs through tentacles)
• Nervous system is diffuse
• Metanephridia
• Radial cleavage
• Blastopore forms mouth (protostomy)
• Marine, benthic tube dwellers
  -Sessile or colonial
  -Actinotroch larva (free swimming, metamorphosis)

Question 7

Phylum Bryozoa

Answer 7

• Triploblastic
  -Coelomate
  -Bilaterally symmetrical
• Unsegmented
• Lophophore
• U- shaped gut with anus outside lophophore
• Circulatory and respiratory structures present
• Colonies, asexual budding, zooids
• Radial cleavage; mixed or indirect development
• Blastopore does not form mouth
  -Sessile, marine or freshwater

Question 8

Bryozoa zooids

Answer 8

-Zooids bear tubular tissue cord, funiculus

Question 9

Zoecium

Answer 9

• In Bryozoans, may be chitonous, gelatinous, or calcareous
• A retractor muscle enables zooid to take shelter in zoecium

Question 10

Bryozoan muscles

Answer 10

• Three sets of muscles operate the lophophore
  1. Atrial sphincter
  2. Retractor muscles
  3. Atrial dilator muscles

Question 11

Polymorphic zooids in colony

Answer 11

Autozooids and Heterozooids

Question 12

Autozooids

Answer 12

Typical zooids bearing the lophophore

Question 13

Heterozooids

Answer 13

Atypical zooids: Kenozooids, Avicularia, and Vibraculum

Question 14

Kenozooids

Answer 14

Reduced individuals for attachment

Question 15

Avicularia

Answer 15

Operculum modified to form a jaw for defense

Question 16

Vibraculum

Answer 16

Flagellum-like operculum

Question 17

Bryozoan larvae

Answer 17

The cyphonautes larva (unique to bryozoans)

Question 18

Bryozoan reproduction

Answer 18

• The free living cyphonautes larva metamorphoses into ancestrula
• Asexual reproduction gives rise to daughter zooids, which continues to divide and form a colony

Question 19

Phylum Brachiopoda (lamp shells)

Answer 19

• Triploblastic
• Coelomate
• Bilaterally symmetrical
• Unsegmented
• Body enclosed between two valves or shells (dorsal and ventral)
• Usually attached to substratum by pedicel or stalk
• Lophophore
• U-shaped gut, anus present or absent
• Metanephridia
• Circulatory is open
• Radial cleavage
• Blastopore closes; both mouth and anus form secondarily
• Sessile, marine, solitary

Question 20

Brachiopods vs bivalves

Answer 20

• Bivalves have a dorsal ligament; brachiopods do not
• Brachiopods have lophophore
• Brachiopods have a U-shaped gut (or a blind gut)
• Plane of symmetry

Question 21

Articulate Brachiopods

Answer 21

• Articulate brachiopods have pedicles (for attachment to substrate) that enter the hinged valves through a space in the larger, ventral valve
• Articulate brachiopods also have a pair of diductor muscles for opening the valves
• The pedicle lacks muscles and coelum

Question 22

Inarticulate Brachiopods

Answer 22

• Inarticulate brachiopods lack a hinge; the valves are held together by muscles only
• Inarticulate brachiopods have a pedicle connected to both valves (does not enter shell)
• The pedicle is muscular and has coelomic cavity

Question 23

Brachiopods larva

Answer 23

Lobate larva

Question 24

Timeline of Brachiopoda

Answer 24

• Less than 500 species but more than 12,000 described fossil species
  -Major reef builders of the Paleozoic; replaced by bivalves after the end-Permain mass extinction

Question 25

Index fossils

Answer 25

define major geological periods

Question 26

Sepkoski curve

Answer 26

a tabulation of fossil diversity over time

Question 27

turbulent history for life in phanerozoic

Answer 27

Assemblages of biota have changed over time in composition, not just species richness

Question 28

Dated phylogeny

Answer 28

• Branches represent living lineages all line up at the present

Question 29

Log-lineage through time plot

Answer 29

• Visualization of how lineages diversify over time
• If we take the log2 of the number of lineages at each branching point in the tree
• The slope of the log-lineage through time plot is a measure of net diversification rate of a lineage

Question 30

Net diversification rate

Answer 30

• difference is speciation rate (b) and extinction rate (d)
• slope = b - d

Question 31

Slopes of different taxa (log-lineage through time plots)

Answer 31

• The slopes of different taxa can help understand why some lineages are more diverse than others
• More diversity from older lineages (not because it is diversifying faster)
• mass extinctions leave marked signatures on the shape of phylogenies

Question 32

Adaptive radiation

Answer 32

Rapid increase and then levels off in log-lineage through time plot

Question 33

Mass extinction

Answer 33

Anti-sigmoid curve in log-lineage through time plots

Question 34

Entoprocta (=Kamptozoa)

Answer 34

• Triploblastic
• Bilaterally symmetrical
• unsegmented
• acoelomate
• Hermaphroditic or protandric
• sessile with zooids on stalks
• solitary or colonial
• visceral mass housed within a cup-shaped calyx
• zooids bear a ring of tentacles that enclose mouth and anus (anal cone)
• Complete gut and U-shaped
• Protonephridia
• Spiral cleavage results in coeloblastula, which gastrulates by invagination
• lack a brain

Question 35

Cycliophora

Answer 35

• Triploblastic
• Acoelomate
• Bilaterally symmetrical
• Unsegmented
• Body divided (buccal funnel, oval trunk, posterior adhesive disc)
• Suspension feeding using ciliary motion
• U-shaped through gut (females only)
• Dwarf males lack buccal funnel and U-shaped gut
• Cerebral ganglion lies dorsal to esophagus (females only)
• Found on the mouthparts of lobsters
• Only two described species

Question 36

Cycliophora larva

Answer 36

Two larval types: choroid and pandora larva

Question 37

Relationships between populations

Answer 37

Not hierarchical (can’t use a phylogenetic tree to depict them)

Question 38

Inferring relationships within species

Answer 38

Need fast evolving genes that can capture the signature of divergences between populations

Question 39

Haplotype

Answer 39

Unique sequence for a locus (gene) in a population

Question 40

SNP

Answer 40

Single nucleotide polymorphism (a site that is variable in the alignment)

Question 41

Haplotype Networks

Answer 41

• Count number of differences between each pair of sequences
• Construct matrix of these differences
• Construct most parsimonious network connecting haplotypes
• Each circle is a haplotype or unique sequence
• size of a circle indicates number of specimens that share that sequence
• Lines connecting circles indicate distances between haplotypes
• can reveal to biogeographic breaks (barriers to gene flow)

Question 42

Fst

Answer 42

• fixation index: measures ratio of total genetic variation in a subpopulation to the total genetic variation in the whole set of populations

Question 43

Fst=0

Answer 43

• Little to no structure in a population (lots of gene flow)
• Panmixia (no barriers to gene flow between populations)

Question 44

Fst=1

Answer 44

Lot of structure in a population

Question 45

Tajima’s D

Answer 45

A standardized measure of the total number of segregating sites (polymorphic sites in the DNA alignment) in your sequence alignment versus the average number of mutations between pairs in the sample

Question 46

D=0

Answer 46

The population is evolving neutrally (due to mutation and drift). There is no evidence of selection or demographic change

Question 47

D<0

Answer 47

There is an excess of rare haplotypes. This is caused by either a recent population expansion after a recent bottleneck or by a recent selective sweep (where an advantageous allele is quickly fixed in the population)

Question 48

D>0

Answer 48

There is a scarcity of rare haplotypes. This may be caused by either a recent population contraction or by balancing selection against new alleles