IntroductionFishing is the largest

Introduction
Fishing is the largest extractive use of wildlife in the
world with demand exceeding the supply. This system of
resource extraction is expected to continue in the coming
years as the human population increases in the next ten
years. In Bicol, Sorsogon Bay (SB) and San Miguel
Bay (SMB) are important fishing grounds for small
pelagic, demersal fishes and shellfish. Marine crabs such
as the blue swimming crab (Portunus pelagicus) and the
Christian crab (Charybdis feriatus) have been abundantly
harvested in the area. Live trade for high valued species
including grouper, wrasses, crustaceans, and lobster are
common in SMB and SB because of the booming export
market which provided significant economic incentive
among fishers. Unfortunately, very little work has been
carried out in regard to management of wild populations.
Given the unregulated resource extraction coupled with
the alarming impacts of climate change, the future of
these species is extremely threatened.
Considering its contribution to the economy and
the livelihood and income of those who depend on its
fisheries, it is imperative that research efforts towards the
development of resource management be given utmost
attention in order to sustain an appropriate number of
parent stock to maintain populations of valued marine
species. An assessment of the resources is therefore
necessary to determine its present status and formulate
doable management and enhancement strategies for
future long-term use.
The present research work is designed to assess the
status of commercially important marine crab fisheries
in SB and SMB. Specifically, it seeks to do the following:
determine commercially important species of
marine crabs; estimate the growth, mortality parameters
and exploitation rate; determine fishing gears exploitingthe species and their catch rate; estimate the annual production
and describe the marketing system. Research
output derived from the local research was presented to
the concerned local government unit (LGU’s) and the
fishers’ group as input for the development of sustainable
management plans for the crab fishery. Without proactive
moves to manage our resources, the chance of a collapse
in the wild crab population is not far from reality.
Acting now to save important species is therefore an
urgent need.
Materials and Methods
This paper presents the output of the collaboratively
effort of Sorsogon State College-Magallanes Campus,
and Camarines Norte State College-Mercedes Campus
and LGU’s bordering the bay.
Monthly sampling and landing surveys were carried
out at major landing sites in SMB and SB. Lengthfrequency
data, individual weight (TW), carapace height
(CH) and the carapace width (CW)) measurement were
taken, species ID, estimate of production, catch data, and
catch per unit effort (CPUE) by gear were collected using
standard stock assessment tools. Simultaneously, gear
inventory and profile of fishers were also carried out.
Market and channel of distribution surveys were undertaken
using KI interview and documentary analysis. Dataanalysis made use of FISAT and SPSS.
The Study Site. SB is situated at the southern coast
of Luzon Island with approximately 201 sq km bounded
by longitude 123°50’ and 124°0’ east and 13°0’ and
13°5’ north characterized by a large horizontal and temporal
salinity variation due to strong influence of freshwater
discharged from the rivers around the bay (Villanoy
C. & Ranola M.C.1995). Specific landing sites in
Sorsogon include Magallanes, Casiguran and Cambulaga
(Fig. 1).
SMB is one of the most productive coastal fishing
grounds in Bicol (Soliman et al., 1997) and is located
in the eastern coast of the Philippines between Latitude
13 40’ and 14 09’ North and Longitude 122 59’ and 123
20’ East. The bay is about 250 kilometers southeast of
Manila on the Pacific Coast of Luzon Island. It has an
approximately surface area of 840 square kilometers
(See Fig. 1). The landing sites are located in Mercedes,
Cabusao, Calabanga and Tinambac.
Data analysis. The relationship of CH and CW
were examined through least squares linear regression
with the formula: y = a+b*x, while the relationship
between the CW and TW to its individual weight was
analyzed through power regression analysis expressed as
y = a*xb where y = the dependent variable
a = is the intercept
x= is the independent variable (or covariate)
b = is the slope of regression coefficient
All relationships were analyzed for their normality
using the Kolmogorov-Smirmov-test, also termed the
KS Lilliefors test for normality. Analysis of the growth
parameters (L∞ and k) and mortality coefficients (M,F
and Z) were estimated using FISAT Ver. 1.2.0 (FAOICLARM
Stock Assessment Tools) software (Gayanilo
et al., 1996). All other analysis were analyzed using
SPSS 17.0 (SPSS Inc., Chicago, 1996)
Results and Discussion
Commercially Important Marine Crab Species
Blue crab (Portunus pelagicus) constitutes the
majority (75-98%) of the catch in both fishing grounds
with Christian crabs (Charybdis feriatus) comprising
only 2% of the total catch and the rest comprising threespotted
swimming crabs (Portunus sanguinolentus) (Fig.
2). The latter are caught mainly by gill net with a mean
catch of 3.5 kg. Meanwhile, Christian crab is mainly
caught (80%) by crab pot 80% with mean catch rate is 9.0
kg.
Estimate of Population, Growth, Mortality and
Exploitation
Population structure of P. pelagicus and C. feriatus.
A total of 8,272 Portunus pelagicus were measured for
length-frequency and about 721 individuals measured for
length-weight relationship in SB. Mean carapace width
CW (±SD) of P. pelagicus was 11.4±1.1 cm (combined
sexes) with a range from 4.0 to 16.7 cm.
A total of 1,971 marine crabs were measured for
length-frequency in SMB, and was comprised of 223 C.
feriata and 1,748 P. pelagicus. The distribution of carapace
width of C. feriata and P. pelagicus are 4.8 cm to
16 cm and 3.6 cm to 17 cm, respectively. In addition,
mean (±SD) values for CW are 9.4 (±1.6) for C. feriata
and 10.8 (±1.2) for P. pelagicus. Noticeably, berried
crabs were also captured during crab fishing which canbe a factor leading to overfishing (Ingles, J.A., 2004).
The linear regression between carapace width (CW) and
total weight (TW) for berried female and combined sexes
were calculated as shown in Figs. 3 - 5.
Regression between CW and TW for berried female
in Sorsogon Bay resulted in a positive linear regression
with a very high correlation coefficient (r) of 0.96. The
same results were obtained between CW and TW forto determine exploitation, mortality, L∞, and k (see Table
1). In SB, the asymptotic carapace width (CW∞) was
17.61 with a growth constant (k) value of 1.3 implying a
faster growth for the species. Findings of the mortality
estimation in SB showed a natural mortality (M) value
of 2.54 and fishing mortality (F) of 2.08 per year. The
current exploitation rate (Ecur = 0.45) is higher than the
optimum exploitation rate (E50) of 0.393, indicating more
highly exploited stock than what it should be. Olańo et
al. (2009) of NSAP BFAR-V also reported that exploitation
rate of P. pelagicus in 2001-2002 was higher with
values 0.69 and 0.64 for male and female, respectively.
In SMB, population parameters (Table 1) of C.
feriata were Z=4.10 yr-1, M=1.70 yr-1, F=2.40 yr-1 and
exploitation rate (E) = 0.59. While for the P. pelagicus,
Z=4.41 yr-1, M=1.82 yr-1, F=2.59 yr-1 and exploitation
rate (E) = 0.59, these high E values indicates overexploitation
of the species (Gulland, 1971).
Estimate of Annual Production
Production. A total of 524.90 mt was estimated as
the annual production in San Miguel Bay (Table 2). The
production constitutes 3.11% of the 16,879 mt fisheries
annual production in San Miguel Bay (Soliman, V.S. and
Dioneda, R.R., 1997). Catches in the Philippines have
been around 34,000 t in recent years and evidence has
shown the abundance of swimming crabs has declined
(www.fao.org).
The annual marine crab production in Sorsogon
Bay is shown in Table 3. In Casiguran and Sorsogon an
annual production of 713.66 mt was estimated during
peak season and about 192.71 mt of P. pelagicus during
lean season. Fishermen usually start fishing around 5:00
A.M. spending an average of 8 hours fishing per day
with an estimated average income from crab fishing of
Php 4,404.00.
Fishing Gears Exploiting the Species and Catch Rate
Fishing Gears and CPUE. Figure 6 presents the frequently
used crab catching gears. There are 9 different
fishing gears available for crab fishing in SB, the most
common are crab gillnet (CGN) , crab lift net CLN) andcrab pot (CP) (Table 3). The preferred (88.04%) fishing
gear across SB is CGN because it does not need bait in
catching crabs; the least used is CP.
The cost of bait also represents an additional
expense for crab fishers. In regard to gear efficiency,
CLN had a better mean catch of 6 kg/trip/day compared
to CGN with 4 kg/trip/day. However, in aggregate terms
CGN has the highest aggregate total catch (P. pelagicus)
volume estimated at 324 kg/trip/day. C. feriata on the
other hand are mainly caught using CP with an average
catch of 2-3 kg/day. Observation also showed that crab
fishing in SB is year round with an average fishing days
of 25 to 30 days/month (Table 4). The major crab fishing
gears in SB are shown in Table 4. In SMB, the majority
of the gear used includes CGN and CP. The mean catch
for CGN and CP is 6.0 kg/trip and 12.5 kg/trip, respectively.
Figure 7 presents the catch composition, 94.06% of
the catch in CGN is P. pelagicus, 0.58% C. feriata, 0.12%
P. sanguinolentus, and about 5.24% by-catch species.
The catch composition of by-catch in SMB is
shown in Table 5. The by-catch from CGN was consisted
of 52.75 % Mantis shrimp, 25.08% tonguefish
and the remaining percentage comprised other fish species,
mollusks and shrimp. A greater proportion of bycatch
in CP consists of Mantis shrimps (74.08%), shrimp(14.81%) and grouper (11.11%).
In Samar and Letye,