Lec 8/9

Question 1

Evolution of Jaws: Origination

Answer 1

First appear in Placoderms and acanthodian fishes

Question 2

Early Jawed Vertebrates

Answer 2

Placoderms “plate skin”

• -Appeared >400mya but NO descendents
• -Some got large (10m)

Acanthodians

• -Contemporary with placoderms but persisted longer
• -Clade possibly gave rise to extant cartilaginous or bony fishes (maybe paraphyletic)

Question 3

Major Clades of Gnathostomes

Answer 3

Placodermi - Placoderms (extinct)

Chondrichthyes - sharks, rays, chimaeras

Acanthodii (extinct)
–UNCERTAIN placement on tree

Osteichthyes - bony fishes (paraphyletic)
–Historically did not include tetrapods

Tetrapoda
–Humans closer to goldfish than those goldfish are to sharks

Approximately HALF of described extant chordate species are fishes

Question 4

Class Chondrichthyes

Answer 4

2 major groups:

1) Elasmobranchii: Sharks and rays
2) Holocephali: Chimaeras

Cartilaginous skeleton (NOT a synapomorphy)

~1200 species

External gill slits (operculum in holocephalians)

LACK lungs/gas bladder

SYNAPOMPORHY:

• -Internal fertilization via claspers in males
• –Claspers: type of intromittent organ
• —Placoderm fossils show vivipary; most basal EXTINCT lineage with internal fertilization
• -Placoid scales

Oviparous or viviparous

Lateral line system and electroreception (various other lineages too)

Teeth:

• -Homologous to placoid scales
• –Developmentally derived from skin denticles (epidermal and dermal components)

Spiral valve in intestine:

• -Increases time food is in intestine to prolong digestion (also some other lineages - Petromyzontiformes, basal bony fishes, lungfish)
• -UNCLEAR origination; NOT a synap

Question 5

Chondrichthyes: Elasmobranchii

Answer 5

Sharks (45%) and rays (55%)

Appear ~420mya (good fossils by 370mya)
–Teeth fossilize very well (enamel is hardest substance in chordates)

~1150 species

Body fusiform in SHARKS

Body depressed (dorsoventrally flattened) in RAYS

Heterocercal caudal fin with upturned vertebral column for support
–Lateral ungulations with tail: Upturned tail prevents sinking

Ventral mouth
–Most fish have terminal mouths: sharks and rays have rostrum at end

Spiracle (ancestral: gnathostome synap)

• -Constricted opening homologous to first pharyngeal slit
• -Present in rays and SOME sharks
• -Unobstructed water intake for gill ventilation in rays
• -Removes substrate for rays (bottom feeders)
• -Purpose UNCLEAR in sharks

Sharks:
–Range in size from 25cm (green dogfish) to >12m and >20 tons (whale shark)

Rays:

• -Includes skates (one group of rays)
• -Benthic in shalow waters
• -Dorsoventrally flattened (depressed)
• -Wings are enlarged pectoral fins and locomotion via waves through fins
• -Teeth flattened for crushing hard invertebrates (manta ray is filter feeder)
• –Molariform teeth: Flat, used to crush
• -Tail defensive lash in some (e.g. stingrays)
• –Hard cartilaginous structure contains VENOM

Question 6

Chondrichthyes: Holocephali

Answer 6

Chimaeras or ratfishes

Sister to sharks/rays
–Split ~420mya

~40 extant species

Retain notochord (REVERSAL)

Venomous dorsal spine in some

Question 7

Lateral Line System

Answer 7

Long recessed grooves with neuromasts

Also in other fishes and aquatic amphibians (larval and some adult)

Arises from ectodermal placodes (vert synap)

Functions in mechanoreception

• -Info on direction of movement by detecting water movement along body
• -Prey and/or predator detection
• -Navigation (blind cave fish)

Can be thought of as a PAIRED sensory system

Neuromasts provide mechanoreception
–These neuromasts have hair cells for detection and acts as mechanoreception (bending of hairs)

Neuromasts with hair cells

Gelatinous cap over hair cells

Movement of hair cells changes receptor membrane potential thus providing neural signal

Signal sent to sensory nerve and brain

Question 8

Lineages with lateral line system

Answer 8

Cyclostomata

Ostracaderms and placoderms

Chondrichthyes

Osteichthyes “bony fishes”

Stem tetrapods (extinct ones)

Extant emphibians:
–Only aquatic stages and some specialized adult aquatic forms

Lost in lineage leading to Amniota

• -CROWN is EXTANT only and is a clade
• -NO amniote has a lateral line

Question 9

Electroreception

Answer 9

The ability to detect electric potentials

Animals give off small electric potentials during neuromuscular activity

• -VERY small
• -Primary role: Prey detection
• -Secondary: Navigation and communication
• -Likely role in navigation (sensing Earth’s magnetic field) in some taxa

Present in:

• -Petromyzontiformes (but NOT myxini)
• -Chondrichthyes
• -Some osteichthyes
• –Retained in basal lineages of Actinopterygii, then lost, then evolved at least 2X in teleosts
• –Extant non-tetrapod Sarcopterygii
• -Some extant amphibians (aquatic)
• -Lost in lineage leading to Amniota
• –Evolved independenlty (with different underlying mechanisms) in platypus (on bill) and dolphins (some)
• —Evolutionary REVERSAL and ANALOGY: Analogous to electroreceptive cells

Question 10

Electroreception: Ampullae of Lorenzini

Answer 10

Specialized sensory cells in pits along snout and head

Pits filled with gelatin (good conductor)

Detect electric currents

Impulses carried to brain

Question 11

Electric Organs: Electrical Discharge

Answer 11

A lineage of rays and some lineages of actinopterygians have evolved ability to discharge high-amperage currents

Electrocytes: Electricity producing cells

• -Modified muscle cells (homologous to muscle cells) concentrated into masses called electric organs
• —Retain electric potentials only
• -Do not contract like typical muscles
• -Cells arranged in stacks that discharge (depolarize) simultaneously: thousands discharge at once, one won’t harm prey

Electric rays (Torpedo) generate high electrical output (nearly one kW)

Question 12

Primary Functions of Electric Organs

Answer 12

Stun prey

Protection from predators

Secondary: Navigation and communication

Question 13

Animals with Electric Organs

Answer 13

Chondrichthyes
-Electric ray (Torpedo)

Actinopterygii:

• Electric catfish (Africa)
• Electric eel (South America)
• Stargazer (eastern seaboard)

ALL INDEPENDENTLY EVOLVED

NOT due to common ancestry

Question 14

Combined Electrical Discharge and Electroreception

Answer 14

Some species generate relatively weak pulsating electric field to NAVIGATE (electrolocalization)

Some species use weak electrical signals to COMMUNICATE (i.e. females and males may discharge different signals)

Question 15

Reproduction in Chondrichthyes

Answer 15

Internal fertilization:

• Males with specialized pelvic claspers extending from cloaca (synap)
• Clasper inserted into female’s cloaca for fertilization

Question 16

Reproduction in Elasmobranchs

Answer 16

Oviparous

• Egg-laying
• Some sharks and rays deposit eggs into egg case (“mermaid’s purse”) and eggs develop in 6 months to 2 years (depending on species)
• Egg case often have tendrils for attachment to objects
• Other species release eggs into environment

Viviparous

• Live-bearing
• Young may derive nutritive materials from mother while in her reproductive tract
• -Some have extensions of oviducal wall into embryo’s mouth that secrete milky substance
• -Some ovulate eggs that embryos eat in utero (or they eat siblings in utero)
• -Some develop a placenta-like structure with an umbilical cord that provides direct exchange between the maternal and embryonic blood

Question 17

Water Balance in Elasmobranchs

Answer 17

Constant threat of losing water to environment

How to cope?

• Blood maintaint close to isosmotic with seawater (like marine inverts)
• High urea concentration in blood (from liver) pushes blood solute concentration higher so shark gains water
• Rectal gland helps eliminate excess salts (Na+ and Cl-_ taken in with food and swallowed seawater

Question 18

Integument of Elasmobranchs

Answer 18

Tough skin contains placoid scales (denticles)
-Most sharks and some rays (lost in many rays)

Closely resemble teeth of other vertebrates

• Internal pulp cavity
• Middle dentine (fibers and calcium-like crystals)
• Covered by enamel

Functions:
–Protection and turbulence reduction to reduce drag from water

Question 19

Elasmobranch teeth

Answer 19

Loosely attached to jaws and constantly being replaced (multiple rows at any time):
–Polyphiodont

Variation in tooth form for different functions:

• Sharp cusped teeth
• Serrated teeth
• Blunt/molariform teeth
• A tremendous variety of form and function!