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Vertebrates subphylum vertebrata

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Biomechanical properties in sharks. Fish Skin. Mucous formed in epidermis cells ... Found in elasmobranchs (sharks & rays) 'teeth like', same composition ... – PowerPoint PPT presentation

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Title: Vertebrates subphylum vertebrata


1
Vertebrates (subphylum vertebrata)
  • Possess a backbone (aka vertebral column, spine)
  • VertebraeDorsal row of hollow skeletal elements
    (usually bone)
  • Nerve cordspinal cord, protected by vertebrae,
    (part of nervous system), ends in brain
  • Bilateral symmetry, endoskeleton

2
Fish Form Function Goals for this lab
  • Learn about fish Topics
  • Skin/scales
  • Coloration
  • Locomotion
  • Fins
  • Muscles
  • Discuss 3 classes of fish
  • Dissect different fish- up to 3 different forms
  • Write paper comparing different fish forms
  • Due next Monday/Tuesday
  • Details to follow

3
Global Habitats
41.2
58.2
39.9
4
Fish importance
  • Appeared gt 500 mya
  • Comprise half of vertebrate species
  • Feed on all types of marine organisms
  • some organisms previously discussed use fish as
    their home (bacteria to crustaceans)
  • Some animals eat fish
  • Most economically important marine organism
  • Vital source of protein to millions of humans
  • Ground up for chicken feed, fertilizer, leather,
    glue, vitamins obtained from them
  • Some kept as pets

5
Fish Morphology
  • Skin
  • Color
  • Bioluminescence
  • Swimming Locomotion
  • Fins
  • Muscles

6
Skin
  • Organ of the body
  • Consists of connective tissue
  • Muscles pull against skin tissue skeleton
  • Key component of the muscle-tendon-tail fin
    system
  • Layers
  • Epidermis
  • Typically 250 ?m thick ? 10-30 cell layers
  • Range 20 ?m 3 mm
  • Dermis

7
Fish Skin
  • Function
  • Hold fish together
  • Serves as barrier against abrasive agents
  • Osmoregulation (what does this mean?)
  • Permeable ? respiratory function
  • Biomechanical properties in sharks

8
Fish Skin
Derivatives
  • Mucous formed in epidermis cells
  • Protect against infection
  • Constantly shed to remove bacteria and fungus
  • Ex. Clingfish lack scales, protect their bodies
    by a thick layer of mucous
  • Bone is also skin derivative
  • scales, most important

9
Fish Scales
  • First appear as dermal bone
  • Found in fossil of Cambrian period (570 mya)
  • Layered bone, solid armor-constrained movement
  • Evolved smaller and reduced into scales
  • 5 types of scales (examples with images to
    follow)
  • Placoid
  • Cosmoid
  • Ganoid
  • Cycloid
  • Ctenoid

10
Fish Scales Placoid
  • Found in elasmobranchs (sharks rays)
  • teeth like, same composition
  • As fish grows, do not increase in size, instead
    new scales are added

11
Fish Scales Cosmoid
  • In the Sarcopterygii (fish with fleshy lobe
    fins), primitive fish
  • Less evolved than Elasmobranchs and
    Actinopterygii (fish with rayed fins)
  • Scales found in fossil record but not in any
    living fish,
  • Except in simplified version of coelocanth and
    lungfish

12
Fish Scales Ganoid
  • In primitive Actinopterygii
  • Found in reedfish, polypterus, gar, bowfin, and
    sturgeons
  • Were thick heavy scales when first appeared
  • Rhomboid-shaped
  • Developed into teleost scales

13
Fish Scales Teleost scales
  • Two types
  • Ctenoid-higher fish
  • Cycloid-soft-rayed, anchovies, sardine
  • Mineralized surface layer inner collagenous
    layer
  • Scales surrounded by dermis, in dermal pockets
  • Grow from top, bottom, and insides overlap
    lower part
  • Scales grow with fish
  • Characterized by concentric ridges (growth
    increments)

14
Coloration
15
Coloration
  • Fish display a multitude of patterns involving
  • 2 or more colors,
  • in many tints and shades,
  • arranged in spots, stripes, patches, and
    blotches
  • 3 Types of coloration predominant in oceans
  • Silver pelagic, upper zone
  • Red deeper zone ( 500 m)
  • Black or violet deep sea
  • Countershaded near shore and colorful in coral
    reefs

16
Coloration
  • Chromatophores
  • Colored cells from which light is reflected
    off
  • Located in the skin (dermis), eyes
  • Various colors/hues-combination of different
    chromatophores
  • Functional Roles of Colors in Fishes-examples of
    each to follow
  • Social Roles
  • Advertisement
  • Mimicry
  • Hiding
  • Protection from sun (especially larvae)


17
Coloration Social roles
Cleaner Fishdistinctive markings recognized by
larger fish
18
Coloration
Advertisement Bright, bold and showy males
indicate Reproductive availability, either
permanently or seasonally, e.g. cichlids,
wrasses, minnows, sunfish Unpalatable or
venomous, e.g. lionfishes Mimicry
Disguise Disguises look like something in
habitat, e.g. leaffish, sargasso fish Mimicry
mimic distasteful species
19
Coloration Concealment
General color resemblance resemble
background Variable color resemblance change
with background, e.g. flatfish Obliterative
shading countershading, dark above, light below
(invisible fish) Disruptive coloration
disruptive contours that breakup outline bold
stripes, bars, false eye spots Coincident
disruptive coloration joining together of
unrelated parts of the body to reduce
recognition e.g. sea dragon
20
Coloration
21
Bioluminescence
  • Most luminous fish found 300-1000 m depths, few
    shallow
  • 3 Types of light producing methods
  • Self-luminous (on/off)
  • Symbiotic bacteria nurtured in special glands
  • Acquire from other bioluminescent organisms-
    diet contains light-emitting compounds
  • Function
  • Concealment by counter-illumination - ventral
    placement matches background from above, against
    attack from below
  • Dorsal photophores safeguard against predators
    from above
  • Advertisement for courting, maintaining
    territory, to startle and confuse predators, and
    feeding

22
Fish Locomotion
Means of Locomotion
  • Simplest form Passive drifting of larval fish
  • Many can
  • Burrow
  • Walk, hop, or crawl
  • Glide
  • Fly
  • Most can
  • Swim in a variety of ways

23
Fins
  • Types of fins
  • Paired fins pectoral and pelvic
  • Median fins dorsal, caudal, anal, adipose

24
Fins
  • Main functions
  • Swimming increase surface area w/o increasing
    mass
  • Stabilizers yaw, stability-dorsal and anal
    fins
  • - brake, pitch, roll, reverse -pectoral/pelvic
  • thrust with caudal fin
  • Modifications in fins
  • Defense spines, enlarge fish
  • Locomotion modified for crawling, flying,
    gliding
  • Hunting lures, sensory organs
  • Respiratory organ lungfish, supply oxygen to
    eggs

25
Fins
Soft rays vs. Spines
  • Spines
  • Usually hard and pointed
  • Unsegmented
  • Unbranched
  • Solid
  • Soft rays
  • Usually soft and not pointed
  • Segmented
  • Usually branched
  • Bilateral, w/left and right halves

26
Fish Muscles
  • Muscles provide power for swimming
  • Myomersbands of muscle, run along sides of body,
    attached to backbone
  • Constitute up to 80 of the fish itself
  • Much hardly used except during emergencies
  • Dont have to contend with same effect of
    gravity
  • Fish muscle arrangement not suitable on land
  • Cow 30 muscle/wt
  • Tuna 60 muscle/wt
  • Contraction causes oscillation of body and tail
  • Body bends as one side contracts b/c of an
    incompressible
  • notochord or vertebral column
  • Caused by bands of muscle myomeres

27
Fish Muscles
  • Major fibers (see handout)
  • Red, pink, and white
  • Pink intermediate between red and white
  • Muscle types do not intermingle
  • Different motor systems used for different
    swimming conditions
  • Red cruising
  • White short duration, burst swimming
  • Pink sustained swimming, used after red and
    before white

28
Fish-Body shapes-see textbook for images (Figure
8.9)
  • Fusiform-spindle shaped, e.g. tuna
  • Compressiform-laterally compressed, angelfish,
    butterfly fish
  • Anguilliform-eel-like
  • Filiform-even smaller anguilliform, e.g. snipe
    eel

29
Body shapes continued
  • Depressiform-flatfish, rays, flounder
  • Taeniform-gunnel
  • Sagittiform-e.g. pike
  • Globiform-e.g. lumpsucker

30
Fish Locomotion
Swimming classified into 2 generic
categories Periodic (or steady or sustained)-
e.g. running marathons, for covering large
distance at constant speed Transient (or
unsteady) e.g. like running sprints, used for
catching prey or avoiding predators
31
Isolate and move only fin(s)
pectoral
Rajiform - pectoral
Labriform -pectoral oscillate
Diodontiform - pectoral
anal
Gymnotiform -anal
dorsal
Tetraodontiform analdorsal
Balistiform analdorsal
Amiiform -dorsal
Ostraciform-rigid body, caudal main propulsion
Flex caudal portion, fast swimmers
Thunniform-rigid body, caudal main propulsion
Carangiform
Subcarangiform
Undulate the body eels, elongate fish
Anguilliform
(Wavelike)
(fanlike)
32
http//www.oceanfootage.com/stockfootage/Titan_Tri
gger_Fish//?DVfSESSCKIE7305db92882366fd26c463edc2
09393f8e25bdc9
33
Tuna Ultimate Living Swimming MachineSwim
continuously feeding, courtship, rest,
reproduction
34
Tuna Ultimate Living Swimming Machinehydrodynami
c adaptations
  • Big size-high performance engine
  • Streamlining-spindle shaped rigid body
  • Small structures at various parts of the body to
    improve swimming efficiency and reduce drag, e.g.
  • Eyes flush with body dont protrude
  • Adipose eyelid - smooth, reduce drag
  • Depression grooves for dorsal, pelvic,
    pectoral fins at high speed
  • Keeled peduncle - cutting through water
  • Finlets for cross-flow - delayed separation

35
Tuna Ultimate Living Swimming Machine
  • Must swim to survive
  • No gas bladder, rigid body, ram ventilation
  • High blood volume, large heart, maintain warm
    core (25oC)
  • School to utilize vortices generated by other
    fish (like race car driver who slipstreams and
    then slingshots past leading car)
  • Adopt swim-glide for energy savings (like birds)
  • High narrow tails propulsion with least effort,
    used to design efficient propulsion systems for
    ships

Slipstream The area of reduced pressure or
forward suction produced by and immediately
behind a fast-moving object as it moves through
air or water.
36
Fish-mouth types (some)
  • Large mouth with teeth (e.g. barracuda)
  • Long snout/small mouth (e.g. butterfly fish)
  • Protrusible mouth (e.g. slipmouth)
  • Beak-like mouth (e.g. parrotfish)
  • Large mouth (e.g. herrings)

37
Fish
Three Classes Agnatha Chondrithyes Osteicthyes
38
Class Agnatha
  • Jawless fishes
  • Ex. Hagfish, lampreys
  • No paired fins
  • Gill holes, no slits or operculum
  • Large sucking mouth with teeth
  • Scavengers
  • As a defense mechanism, secrete slime then tie
    itself in knots to escape predators
  • Also tie in knots for pulling food off
    carcasses, and cleaning slime from body

39
Class Agnatha
Hagfishs mouth
http//www.soest.hawaii.edu/oceanography/faculty/c
smith/index.html
40
Class Chondricthyes
  • Sharks and rays
  • Skeleton cartilage, not bone
  • Paired fins-efficient swimming
  • Gill slits exposed,
  • no operculum
  • Large oil-filled liver
  • Heterocercal tail (upper longer than lower lobe)
  • Placoid scales-skin like sandpaper

41
Class Osteichthyes
  • Bony fish
  • Largest group of living vertebrates
  • Bones for skeletons
  • Gill covering (operculum)
  • Swim bladder (balloon-like)
  • Homocercal tails (even)
  • Cycloid Ctenoid scales

42
Dissection Worksheet
  • Working in groups of 2 or 3 people,
  • dissect 1 fish following the worksheet and
    writing the answers to the questions in your
    notebook as you go.
  • Need to draw 3 external illustrations in your
    notebooks
  • 1 of the fish you are dissecting, before you
    dissect it
  • 2 others that have specialized mouths and caudal
    fins
  • label the type of mouth and caudal fin each has
  • Label the following structures on each
    illustration
  • gill cover, pectoral fins, pelvic fins, dorsal
    fin,
  • anal fin, adipose fin (if present), lateral line
  • give the head length, total length, and the fork
    length (of the dissected one ONLY, see handout)
  • look at a scale under a microscope and draw it.

43
Dissection Worksheet continued
  • Cut through body cavity
  • Find the following
  • Heart
  • Liver
  • Stomach/intestines
  • Swim bladder (if applicable)
  • Spine
  • Cut cross section, 2/3 down the body
  • Red muscle
  • White muscle

44
Scales- use slides
  • Draw
  • Placoid
  • Ganoid
  • Cycloid
  • Ctenoid
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