Intro_Ichtho.pdf

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ICHTHYOLOGY:
An Introduction
 What is Ichthyology?
 Study of fishes
 Scientific study started in Europe
 HISTORY OF ICHTHYOLOGY
Carl Linnaeus – designed Binomial nomenclature
(classification – Genus & species)

Peter Artedi – father of Ichthyology, helped Linnaeus

Approximately 30,000 known species are classified and about 100-
200 new discoveries each year.
Fish Fact Sheet NUMBER OF FISH TAXA

Species,

 Cold-blooded animals 12.80%

 Numerous vertebrates
Genera, Orders
Orders,
23.47% Families
71.66%
Genera
Families, Species
43.30%

Philippines World
Orders ˜43 ˜60
Families ˜210 ˜485
Genera ˜1000 ˜4260
Species ˜3,280 ˜32,200
 Fish Fact Sheet
Ichthyofauna of the Philippines

Total species +3,280
Freshwater 347
Seawater 3,029
Introduced 44
Endemic 120
Threatened 97
Dangerous 348
Reef associated 1,772
Pelagic 19
Deep water 350
Game fish 276
Commercial 3,280

Fishbase 2012
 Fish Fact Sheet
Priapiumfishes Catfishes
Gobies
Eels
Pipefishes

Needlefishes

Sleepers

Cyprinids Perciforms and others
211 lakes
18 major rivers
22 marshlands
Characteristics of Fish
Aquatic Vertebrate

With gills for breathing

Have scales and fins

Cold blooded

Mostly lay eggs
 Fish v.s. Fishes

Fish Fishes
“There are twelve fish in this aquarium, representing five fishes”
 Fish Fact Sheet

Aquatic Biodiversity in the
Southeast Asia:

Fishes >5000 species
Amphibians >300 species
Aquatic reptiles >350 species
Decapod crustaceans >300 species
Aquatic insect >250 species
Zooplankton >1000 species
Benthos >1500 species
Water plants >400 species
Fish Fact Sheet
Photocorynus spiniceps – 6.2 mm male; 46 mm female by
Ted Pietsch

Schindleria brevipinguish – 6.5-7.0 mm male; 7.0-8.0 mm
female

Paedocypris progenetica – 7.9 mm female by Maurice
Kottelat and Tan Heok Hui (P. micromegethes)

Pandaca pygmea – 15 mm
Mistichthys luzonensis – 25 mm

Rhincodon typus – 18-21 m; 25 MT
COELACANTH
 CLASSIFYING FISHES
SYSTEMATICS – Study of
Kingdom: Animalia fish diversity and
evolutionary relationships
Phylum: Vertebrata (plesiomorphies and apomorphies)
Class : Osteichthyes
Order: Perciformes Taxonomy – theory & practice
Nomenclature – naming of
Family:Badidae taxonomic groups
Genus: Badis Classification – organizing into
taxa
Species: badis
Rank (International
nomenclature code): Common name: Chameleon fish
1. Kingdom
2. Phylum/Division
3. Class
4. Order
5. Family
6. Genus
Oreochromis niloticus L.
7. Species (subspecies)
Allum cepa (L.) R. (botany)
Classification of Fish
 Three Classes of modern fish

Agnatha – primitive jawless fish.
e.g. lampreys and hagfish

Chondrichthyes – jawed fished with cartilaginous skeleton
e.g sharks, rays

Osteichthyes – fish with bony skeletons
e.g. milkfish, tilapia, tuna
 Class Agnatha
Characteristics
 No jaws
Primitive
Lack true bones
(cartilaginous skeleton)
Scaleless skin
Oral sucker
Predators and filter feeders
Found in both fresh and salt
waters
Some anadromous (fish live
in the ocean mostly and breed
in fresh water)
 Class Chondrichthyes
Characteristics
“cartilage-fish”
Skin covered with
denticles, placoid scale
5-7 gill slits per side
No swim bladder
Internal fertilization
Spiral valve intestines
5-7 gill arches
 Sharks
 Highly adapted to environment
Carnivores or scavengers
Possess keen sense of smell, large brain, good sight and
Highly specialized mouth and teeth
Body is heavier than water
No swim bladder (buoyancy)
Asymmetric tail
Few venture in freshwater and been found in rivers
 Class Osteichthyes
Characteristics
Largest section of the
vertebrates with over 20,000
species worldwide
Bony fishes because of
calcified bones making much
harder compared to cartilage
bones
Great maneuverability and
speed
Highly specialized mouth
equipped with protrude jaws
Has swim bladder for
buoyancy
 Fish General Anatomy

3

8
7 1 3
5 2 4

9 3

6 3
3

(1) Eye and its parts; (2) Operculum or gill cover; (3) Fins (median and paired);
(4) Lateral line; (5) Mouth and its parts; (6) Genital papilla (anus and urinary
pore); (7) Nare or nostril; (8) Scales; (9) Barbels
Eyes
 Well developed

 Sharks have pupils that dilate and constrict (good
eyesight)

 Presence of eyelid (closes bottom to upward)

Bony fishes do not have pupils and eyelids
Mouth
 The mouth parts of a fish will vary in size
and may or may not contain teeth.

The location of the mouth on a fish’s body
can also give us a clue as to what may be the
fish’s diet.
 Nares
 All fish possess a sense of smell.

 Paired holes called nares, are used for
detecting odors in the water, and are located on
a fish’s snout.

 Some fish, such as some shark species, catfish,
and eels, have a very sharp sense of smell.
Lateral Line
 Running down the length of a fish’s body is
the lateral line. It is made up of a series of
microscopic holes located just under the
scales of the fish.

 One of the fish's primary sense organs, the
lateral line can sense low vibrations in the
water, and is capable of determining the
direction of their source.
Scales
 Most fish have scales covering the length of their
body.

Scales protect fish from injury, much like skin on
the human body.

On top of these scales is a mucous covering
known as the slime layer.

Slime protects fish from bacteria and parasites in
the water.
Genital Papilla
 Fish General Anatomy
(Barbels in Catfish)

1

2 4
3

(1) Nasal barbel; (2) Mandibulary barbel; (3) Mental or Chin barbel;
(4) Maxillary barbel
Fish General Anatomy

(Keel)
Fish General Anatomy

(Scutes)
Fish General Anatomy
 Fish General Anatomy
Illicium

Esca
 Fish Fins

1
6
5

3 4

1 5
7

4
2 3

(1) Dorsal fin; (2) Pectoral fin; (3) Pelvic fin; (4) Anal fin; (5) Caudal
fin;(6) Adipose fin; (7) Second dorsal fin
 Functions of Fins
Propulsion – most Fish
Stabilization – sea Horse

So that’s Stabilization – Bass, salmon
what they Propulsion - Eels
do

Station keeping
Propulsion
Stabilization – most fish
Finlet
 Fish Fins

1. Paired Fins
a. Pectoral fins
b. Pelvic fins
Fin Rays (Soft/Lepidotrichia)

Branch ray

Simple ray
 Fish Fins
2. Median Fins
a. Dorsal fin
b. Anal fin
c. Ventral(adipose and finlets)
d. Caudal fin
Fin Rays (Spine/Actinotrichia)

Serrate spine

Non-Serrate spine
 Positioning of Pelvic Fin
Abdominal – pelvic fins are attached midway down
the belly

Thoracic – pelvic fins are below the pectoral fins

Jugular – pelvic fin is attached under the gills
Positioning of Pelvic Fin
Thoracic

Jugular

Abdominal
Types of Caudal Fin
Isocercal—last vertebrae modified (cods)
 Gephyrocercal—”bridge tail”
Dorsal and anal fins have grown around
posterior end of fish. (Mola)
Shapes of Caudal Fin

Crescent or
lunate

Rounded
Shapes of Caudal Fin

Forked Truncated
Shapes of Caudal
Fin

Emarginated Pointed
Diversity of Mouth
Mouth Positions

Superior
 Mouth Positions

Sub-Terminal Inferior

Terminal
Mouth Diversity in
Cyprinids
 Mouth Shapes

Rostral
Mouth Shapes

Elongated beak
Mouth Shapes

Short beak
Mouth Shapes

Tube
 Mouth Shapes

Retractable (protrusible)

Suction disc
BODY SHAPES
 BODY SHAPES
Fusiform – streamlined with pointed ends, shaped like
plane, helps to lower frictional resistance, and allows to
move through the water extremely fast

Anguiliform/Attenuated – fish that are long, and
skinny, fish slither like snakes, allows to maneuver into
narrow openings and resist the force of current

Globiform – fish that are almost round or lobe-shaped
 BODY SHAPES
Compressiform – fish that are laterally compressed, tall,
thin body shape that allows fish to enter vertical crevices,
allows for quick burst of speed and quick turns

Depression – wide, flat body shapes that all fish rest on
the bottom.
 Scales in Fishes
Dermal plates
Microscopic to large, tissue thin
to plate-thick, simple to
complex, partial to complete,
non-bony to bony, loosely
deciduous to firmly attached
Do All Fishes Have Scales?

NO

Clingfishes (Gobiesocidae) and Agnathans (lamprey, slime eels and hagfish)
Why Do Fishes Have
Scales?
 Protection
 Classification
 Natural history
 Derivatives
Are All Scales the Same?
 Freshwater eels- tiny embedded scales
 Tunas- tiny scales
 Coral snapper- medium-sized scale
 Tarpon, Megalops cyprinoides- large scales
 Indian Maheer, Tortor- 10 cm length
How Old is a Fish Scale?
Can a Fish Have More Than
One Type of Scale?

IN SOME

Flounder and soles
Can Scale Type Vary
with Sex?

IN SOME
(Flatfish)
 Types of Scale (Placoid)
 Consists of flattened rectangular base
plate which is embedded in the fish, and
variously developed structures such as
spines.
 Composed of a vascular (supplied with
blood) inner cone of pulp, a middle
layer of dentine and a hard enamel-like
outer layer of vitrodentine.

 Examples: sharks, rays and relatives
Types of Scale (Cosmoid)
Consist of two basal layers of
bone, a layer of dentine-like
cosmine and an outer layer of
vitrodentine.

Lung fish (Family Ceratodidae)

 Examples: lung fish and fishes belong
to Family Ceratodidae
 Types of Scale (Ganoid)
 Have articulating peg and socket.
 Consist of bony basal layer, a layer
of dentine and an outer layer of
ganoine (inorganic bone salt)

Examples: bichirs (Polypteridae),
bowfin (Amia calva), paddlefish
(Polyodontidae), gars (Lepisosteidae)
and sturgeons (Acipenseridae)
 Types of Scale (Ctenoid)
 Overlapping scales.
 Has variously developed spiny posterior
margin.
 Consist of two main regions, a surface
"bony" layer, composed of an organic
framework impregnated largely with
calcium based salts, and a deeper fibrous
layer composed mainly of collagen.
 Derived from ganoid scales that have lost
the ganoine and thinned the bony
embedded plate.
 Ctenii – tiny, comblike projections on the
exposed (posterior) edge of scales
Paradise fish, Macropodus opercularis

 Examples: male burbot (flounder and
soles), trout, perch and paradise fish.
 Types of Scale (Cycloid)
 Overlapping scales.
 Has circular , smooth margin.
 Consist of two main regions, a
surface "bony" layer, composed of
an organic framework
impregnated largely with calcium
based salts, and a deeper fibrous
layer composed mainly of
collagen.
 Derived from ganoid scales that
have lost the ganoine and thinned
the bony embedded plate.

Red fire fish

 Examples: red fire fish, flounder and
soles (blind side), carp.
 Swimbladder
Gas filled bag that sits in a
fish’s body cavity above its
guts.
By body volume,
5% in MF; 7% in FF
Density (FW = 1.0, SW = 1.026, Fish = 1.076)
Not all fish has swimbladder.
SB of bony fish is neutrally buoyant at a particular
depth
1 ATM (14.7 psi) increase for every 10 m depth
 Sharks buoyancy
Sizeable liver (25-30% of body)
Squalene (low density, low specific gravity
= 0.855)
Cartilaginous skeleton (1.1 vs 2)
Fins (for continuous swimming)
 Buoyancy and Gaits
Negative Buoyancy
Advantage: Hold to bottom

Disadvantage: Energy required to maintain in

water column and move
Density pushes down
Im
Back

Energy to provide lift
 Buoyancy and Gaits
Neutral Buoyancy
Advantage: Hold in position

Disadvantage: Energy required to move up or

down in water column

Fun

Weight not a problem

Energy to provide lift
 Buoyancy and Gaits
Positive Buoyancy
Advantage: Hold to surface

Disadvantage: Energy required to maintain in

water column and move (can’t dive)
weight Buoyancy holds up
Need

Energy to dive
 Negative Aspects
Icthyotoxin – generally, any poison originating from
fishes
Ichthyosarcotoxin – poison found in flesh of fishes

Ciguatera – caused by eating various marine
fishes of tropical and subtropical areas.

toxin: ciguatoxin, maitotoxin, scaritoxin,
palytoxin
affected fish: barracuda, snapper, moray eels,
parrotfish, triggerfish, amberjacks
effects: gastrointestinal and neurological,
allodynia (severe)
Negative Aspects
Scombroid poisoning –caused by eating
improperly preserved scombroid fishes

toxin: histamine (Morganella morganii)
(histidine = histamine)
fish: mackerel, tuna, mahi-mahi, bonito,
sardines, anchovies

effect: severe allergic responses
(symptoms
can show minutes to 2 hours)
 BIOACCUMULATION & BIOMAGNIFICATION

Gambierdiscus toxicus
 Negative Aspects
Icthyohemotoxin – poison found in blood of fishes
Icthyoacanthotoxin – poison secreted at the site of a
venom apparatus such as spines, stings, or teeth of
fishes
Stonefish – rank no. 6 of the most venomous

creatures
 Icthyootoxin –poison found only in roe of fishes

Tetradotoxin or tetrodox or TTX
(neurotoxin) – the poison in viscera, liver,
skin of Tetraodontiformes
Puffer fish – rank no. 10 of the most

poisonous creatures
Other sources: porcupine fish, ocean sunfish,

triggerfish
Symptoms develop within 30 minutes

(delayed up to 4 hours)
 Positive Aspects

Fishes as biological control
Scientific uses of fishes
Recreational fisheries
The aquarium trade
Fish culture
 Taxonomic Methods

A. Morphometric traits - any standard
measurement that can be made on a
fish

i.e. snout length, total length, width of eye,
length of jaw in body length, etc.
 Taxonomic Methods

B. Meristic traits - any trait that can be
counted

i.e. vertebrae, fin rays, scale rows, lateral line
pores, branchiostegal rays
 Morphometric Characteristics
Counting and measurement
for identification
dorsal height Total length
Pre-dorsal length
D. Soft fin rays

Circum-peduncular scale

Lateral-line scale

Transverse scale
Head length Anal fin base L

Point-to-point measurements Standard length
 Morphometric Characteristics

Head length

Eye length

Anal fin base length
 Morphometric Characteristics
Body depth

Standard length
Caudal peduncle length

Total length
 Morphometric Characteristics
(Exceptional cases)
Position of tail spine

Fork length

Disc length

Maximum width
Total length
Meristic Characteristics
Examples of Meristic Characteristics:
1.No. of dorsal rays/spines
2.No. of anal rays/spines
3.No. of pectoral fin unbranched/branched
rays
4.No. of lateral line scales (upper and lower)
5.Transverse line scales
6.Caudal peduncle scales
7.Cheek scales
8. Total gill rakers
9.No. of outer teeth on the lower jaw and
upper jaw
Meristic Characteristics

Lateral-line scales
 Taxonomic Methods
C. Anatomical/morphological characteristics –
descriptions of morphological (external) and
anatomical (internal) features (not
measurements or counts)

i.e. shape or lateral line, special features (lung,
etc), secondary sexual characters, position of
fins and barbels
 Taxonomic Methods
D. Molecular phylogenetics - examination of traits at the
molecular level

Cladogram - displays the inter-relatedness of
taxonomic groups, divides them by shared or not-
shared traits in a dichotomous manner, show
transition from more primitive to more advanced

Phylogenetic tree - as above + includes passage of
time between branch points

In cladogram, branch lengths are not necessarily proportional to the evolutionary
time between related organisms or sequences.
Cladogram v.s. phylogenetic tree
Taxonomic Methods
 Phylogeny of Fishes
A. Split 1: Lacking true vertebrae
vs.Vertebrata
1. Lacking true vertebrae –
hagfish
2. Vertebrata - all others
Lamprey: Petromyzontiformes
B. Split 2: Agnatha vs. Gnathostomata
1. Agnatha - lacking jaws
(lamprey)
2. Gnathostomata - bearing jaws
(all others)
Hagfish: Myxinidae
 Phylogeny of Fishes
C. Split 3: Chondrichthyes vs. Osteichthyes
1. Chondrichthyes - cartilaginous fishes
a. Holocephali - chimeras and ratfishes, upper jaw
and skull fused
b. Elasmobranchii - sharks, skates and rays

2. Osteichthyes - bony fishes (all others)
 Phylogeny of Fishes
D.Split 4: Sacropterygii vs. Actinopterygii
1.Sacropterygii - lobe-finned (coelacanth,
lungfish, ancestors of all tetrapods)

2.Actinopterygii - ray-finned (all others)
 Phylogeny of Fishes
E.Split 5: Chondrostei vs. Neopterygii
1.Chondrostei - ancient fishes (sturgeon,
paddlefishes)
a.secondarily cartilaginous
b.spiral valve intestine (as in skarks)

2.Neopterygii - modern fishes (all others)
 Phylogeny of Fishes
F. Split 6: non-teleosts vs. Teleostei
1. Non-teleosts - including gars and bowfins – formerly
grouped as Holostei, which turned out to be
paraphyletic
a. abbreviated heterocercal tail
b. ganoid scales (in gars, bowfins have cycloid scales)

2. Teleostei - including the majority of ray finned fishes
a. homocercal tail
b. cteniod or cycloid scales