03 - Fish Biology- Migration.pptx

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What is fish
migration?

Mass movement of fish from one

Types of Fish
Migration
1.Diadromous
- Anadromous
- Catadromou
s
- Amphidrom
ous
2.Potamodrom

Diadromo
us

Etymology: Greek; dia- (“across”) + -dromous
(drómos, “running”, “race”)
Migrations of fishes between fresh waters and
the sea; these migrations are regular, physiologically
mediated movements which occur at predictable life
history phases in each diadromous species, they
involve most members of a species' populations, and
they are usually obligatory.

Anadromous
Fishes
thatAncient
livesGreek
in ἀνάδρομος (anádromos),
Etymology:
the ocean but
migrates to the
river to spawn
from ἀνά (aná, “up”) + δρόμοs (drómos, “running”,
(e.g. salmons and

Anadromous
migration

Catadrom
ous

Etymology: Greek katadromos, ( kata, ”down” ) +
δρόμοs (drómos,
“running”, “race”).

Fishes that lives in the river but
migrates to the ocean to spawn
(e.g. anguillid eels)

Catadromous
Migration

Amphidromou
s

Fishes
that
migrates
between
the
Etymology:Ancient Greek ἀμφί (amphí, “on both
ocean
and
the river
in“running”,
some part
sides”)
+ δρόμοs
(drómos,
“race”).of
their life cycle but not to spawn
(e.g. sicydiine gobies)

Amphidromous
Migration

Potamodromou
s
Etymology:Ancient Greek ποταμός (potamós,
migration
from (drómos, “running”, “race”).
“river”) + δρόμοs

one freshwater
fish habitat to
another

Oceanodrom
ous
migration
of fish
within seawater
habitat
in
search
of
suitable feeding
and
spawning

Types fish migration on the basis
of needs:

•Alimentary or Feeding migration (trophic):
migration for search of feeding ground. It occur when
food resources get exhausted.
•Climatic or seasonal migration: migration in
search for suitable climatic condition.
•Osmo-regulatory migration: migration for water
and electrolytes balance from sea to fresh water
and vice-versa.
•Juvenile migration: it is larval migration from
spawning ground to the feeding habitats of their

•Gametic or spawning migration: it
occur during breeding season in search
for the suitable spawning ground.
Spawning grounds are usually
located far from areas where the
adult fish gather food
-Distance between feeding and
breeding areas helps ensure the
survival of the baby fish
- Baby fish have different diets

Purpose of Fish
•to findMigrations
suitable
feeding and
spawning ground
•for protection
from predators
•survive from
extreme climatic
conditions
•increases

Vertical fish
The movement of fishes towards
migration
upper
surface of sea during night and
towards bottom during day
for
various endogenous and exogenous
reasons
1. Endogenous factors:- which originate
from organism itself like sex, age
biological rhythms, etc.
2. Exogenous factors:- These are the

Significance of vertical
•Predator
Avoidance:- Organisms come up to shallow
migrations
waters at night to feed
while it’s dark out because their predators cannot see them as
easily as in day.

•Metabolic Advantage:-By feeding in the warm surface

waters at night and residing in the cooler deep waters during
the day they can conserve energy. Alternatively, organisms
feeding on the bottom in cold water during the day may migrate
to surface waters at night in order to digest their meal at
warmer temperatures.

•Dispersal and Transport:- Organisms can use deep and
shallow currents to find food patches or to maintain a
geographical location.

•Avoid UV Damage:-The sunlight can penetrate into the

water column. If an organism, especially something small like a

Life History of the Giant Mottled Eel Anguilla
marmorata in the Northwestern Pacific
Nico Jose S. Leander, Yu-San Han and Wann-Nian Tzeng
Institute of Fisheries Science, College of Life Science
National Taiwan University

There are 16 species and 3
sub-species of freshwater
eels (genus Anguilla)
distributed in the tropical,
subtropical and temperate
waters around the world.

Luzon Mottled
Eel

• The tropical eel A. marmorata and the
temperate eel A. japonica are just 2 of
the many anguillid eel species found in
East Asia.
• Anguillid eels in the Philippines: A.
marmorata, A. luzonensis, A. bicolor
pacifica, A. celebesensis and A.
japonica
• They provide food and livelihood to a
lot of fisher folks in the region wherein
they are harvested and consumed
several thousands of tons every year.

Materials and methods
•To understand its early life
history, glass eel samples
were collected from various
estuaries and rivers in East
Asia
and their sagittal
otoliths were extracted for
age and growth analyses. The
results were compared with
that of A. japonica.

EAR-STONES OR OTOLITHS
brain

circular
canals

asteriscus

lagena

lapillus
utriculus
sagitta
sacculus

ted light

ted light

• First use by Reibisch in 1899 to
age fish (annuli)
• Pannella discovered daily growth
increment (1971)
• Grow throughout the fish’s life
• Reliable and accurate method to
age fish

Otolith Microchemistry
• Otoliths are also environmental recorder.
• Trace-element signatures in otolith-growth bands provide a
powerful tool for fish biologists to track fish movements,
discriminate fish populations, and monitor aquatic environments
• A total of 31 elements have been detected in fish otoliths to date.
• Strontium (Sr) is of special interest because it is an indicator of
salinity.
• Sr is about 100 folds higher in seawater than in freshwater

Anguillid glass eel otolith microstructure

Migration cycle of the
giant mottled eel

Spawning ground:
West Mariana
Ridge

Silvering Process

Migration cycle of the
giant mottled eel

Kurio River
145.0 ± 17.8
days
Hsiukuluan
River
144.8 ± 14.2
days
Cagayan
River
134.0 ± 15.4
days

Anguilla marmorata
age at recruitment

Ya-lu
River
199.3
± 15.6
days

Chyan-tarng
River
194.9 ± 18.6
days

Donggang
River
177.7 ± 17.8
days

Ming-chiang
River
172.1 ± 14.1
days

Anguilla japonica age
at recruitment

Shuang-shi
River
174.4 ± 17.7
days

The larval growth rate and the metamorphosis timing may play an important
role in the geographical distribution of the sympatric anguillid eel species A.
japonica and A. marmorata in the northwestern Pacific

Sr:Ca measurement in the otolith of adult
A. marmorata: Aurora, Philippines

After reaching the coastal
waters, the elvers
immediately migrate further
inland as evidenced by low
Sr:Ca ratios (<4x10-3) after
the elver check until the
otolith edge.

Determination of the life history patterns of gobies
(Gobiidae) in Luzon, Philippines using otolith analysis
Nico Jose S. Leander1, Apolinario V. Yambot1, Tereso A. Abella1, Mei-yu Chang2, Yoshiyuki Iizuka3, Wann-Nian Tzeng2
1

College of Fisheries, Central Luzon State University, Science City of Muñoz, Nueva Ecija, Philippines
2Institute of Fisheries Science, College of Life Sciences, National Taiwan University, Taipei, Taiwan
3 Institute of Earth Science, Academia Sinica, Nankang, Taiwan

SAMPLING
• Glossogobius aureus
• Rhyacichthys aspro
• Awaous melanocephalus
• Sicyopterus lagocephalus
• Eleotris melanosoma
• Ophieleotris sp.

Bangui, Ilocos Norte

Magat Dam, Isabela
Aurora

Pangasinan

Otolith samples were taken to National
Taiwan University and Academia Sinica
for analysis

Pantabangan, Nueva Ecija

Gen. Nakar, Quezon

Results
Glossogobius aureus
Pangasinan

Nico AMagat Dam, Isabela and Pantabangan
Dam, Nueva Ecija
11

Nico A9

1.6

1.6

1.
4

1.4
1.2
1.0
Ratios

Ratios

1.
2
1.
0

0.6

0.
8

0.4

0.
6
0. 0
4
0.
2

0.8

0.2
0.0
20
0

40
0

60
0

800
2000

1000

1200

core to edge, 
m

1400

1600

1800

0

200
1600

400

600

core to edge, 
m

800

1000

1200

1400

Rhyacichthys aspro
Nico-4 D-2

Gen. Nakar, Quezon
1.
8

Ratios

1.
6
1.
4
1.
2
1.
0
0.
8
0.
6 0
0.
4

10
0

20
0

300
core to edge, 
m

40
0

50
0

60
0

Awaous melanocephalus
Nico B6

San Luis, Aurora
1.8
1.
6

Ratios

1.
4
1.
2
1.
0
0.
8
0.
6
0.
4

0

20
0

40
0

60
0

800
core to edge, 
m

100
0

120
0

140
0

160
0

Sicyopterus lagocephalus
Nico B5

Bangui, Ilocos Norte
1.8
1.
6

Ratios

1.
4
1.
2
1.
0
0.
8
0.
6
0.
4
0.

0

10
0

20
0

30
0

400

500

core to edge, 
m

60
0

70
0

80
0

90
0

100
0

Eleotris melanosoma
Nico A12

San Luis, Aurora
1.6
1.
4

Ratios

1.
2
1.
0
0.
8
0.
6
0. 0
4
0.
2

10
0

20
0

30
0

400
core to edge, 
m

50
0

60
0

70
0

80
0

Ophieleotris sp.
Nico-4 D11

San Luis, Aurora
1.
8

Ratios

1.
6
1.
4
1.
2
1.
0
0.
8
0.
0
6
0.
4

20
0

40
0

600
800
core to edge, 
m

100
0

120
0

140
0

Amphidromous life cycle

• At certain times of the year, the biomass of the
recruiting larvae is so great that it can support
a very valuable economic resource and
become a major source of food for local
human populations in certain human
archipelago.
• The return migration of the post-larvae of
these amphidromous gobies support postlarval fisheries found virtually throughout the
Indo-Pacific.

Areas with major goby-fry fishery

Recruiting
amphidromous
gobies in Taitung,
Taiwan

Metamorphosis for
Upstream Migration
•48 hrs. after entering FW,
the total restructuring of the
cranium has taken place
•The total body length and
the length of the head remain
unchanged.
•Tail mainly forked but
gradually becomes truncated
and body acquire pigments.

•The upper lip enlarged and the mouth moves
from a terminal to an almost ventral position.
•Enlarged lips and suction cup will be used for
climbing vertical rock faces, even waterfalls.
Frenum

Type 1

Anal
pore
Genital
papillae

Type 2

Diadromous fish return
migration

Why do we need to understand
fish migratory behavior?
Migrationmakes fish more vulnerable to
exploitation(fishing). This is clearly of
significance for commercial fisheries, and
fisheries have traditionally exploited this
migratory and aggregating behavior.

Threats to diadromous fish
migration

Barriers to fish
migration!

Migratory fish
mortality due to
hydroelectric power
plants

Fishing
pressure:
return
migration

Fishing pressure: adult fishes in
the inland waters

Other
barriers
migration:
fish
traps

to

fis
h
weir an
s
d

Other threats
to diadromous
fishes
•Pollution
•Mining/dredging
•Other anthropogenic
activities

Regulat
ory
measur
es
Fish
Ladder

Providing Fish Passage via Collection-andTransport Programs

Dam/reservoir/water impoundment
removal

Ordinance
•An ordinance declaring a total ban of the
catching14-03
of “ïpon” within the territorial

jurisdiction of the Province of Ilocos Sur
in the month of August and on the month
of February of every year thereafter and
prescribing penalties.

Other Ipon Fishery Laws in
northern Philippines

Fisheries Administrative Order (FAO) 242
Ban on the exportation of live elvers caught in
the Philippine waters in a bid to stop the rapid
and rampant exploitations of the anguillid eels
in the Philippines
FAO carries a penalty of eight
imprisonment, confiscation of catch or
equivalent to double the export value
same, and revocation of fishing and/or
permit.

years
a fine
of the
export

Last July 08, 2012, BFAR seized 46 boxes containing some 2 million elvers
(940 kg) at the Ninoy Aquino International Airport in pursuant of FAO 242
series of 2012. The shipment was bound for Hong Kong and was valued $USD
496,320.

Republic Act 10654: Amended Fisheries
Code 1998 (RA 8550)
•SEC. 114. Obstruction of Defined Migration
Paths. – It shall be unlawful for any person to
obstruct any defined migration path
of
anadromous,
catadromous
and
other
migratory species. Upon a summary finding of
administrative liability, the offender shall be
punished with an administrative fine of One
Hundred Fifty Thousand Pesos (P150,000.00) to
Five Hundred Thousand Pesos (P500,000.00),
dismantling of the obstruction at the expense

RA 10654
cont’d.

•Upon conviction by
a court of
law,
the offender shall
be punished with
imprisonment of seven (7) years to twelve
(12) years and fine of twice the amount of the
administrative fine, dismantling of the
obstruction at the expense of the offender,
and the suspension or revocation of the permit
or license.

Perspecti
ve

•Updating
current
state
of
knowledge
regarding the freshwater migratory species
of
the
Philippines:
species composition,
distribution, seasonality, life history, biology,
population structure, etc.
•Status of migratory species
•Status of Fishery Law

Thank you…