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Journal of Zhejiang University SCIENCE B 2009 Vol.10 No.12 P.902-911

http://doi.org/10.1631/jzus.B0920173


Population growth, trophic level, and reproductive biology of two congeneric archer fishes (Toxotes chatareus, Hamilton 1822 and Toxotes jaculatrix, Pallas 1767) inhabiting Malaysian coastal waters


Author(s):  K. D. SIMON, Y. BAKAR, A. SAMAT, C. C. ZAIDI, A. AZIZ, A. G. MAZLAN

Affiliation(s):  Marine Science Programme, School of Environmental and Natural Resource Sciences, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor D.E., Malaysia; more

Corresponding email(s):   skdas_maa@yahoo.com, magfish05@yahoo.com

Key Words:  Archer fish, Toxotidae, Mangrove, Estuary, Predator, Growth, Reproduction


K. D. SIMON, Y. BAKAR, A. SAMAT, C. C. ZAIDI, A. AZIZ, A. G. MAZLAN. Population growth, trophic level, and reproductive biology of two congeneric archer fishes (Toxotes chatareus, Hamilton 1822 and Toxotes jaculatrix, Pallas 1767) inhabiting Malaysian coastal waters[J]. Journal of Zhejiang University Science B, 2009, 10(12): 902-911.

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author="K. D. SIMON, Y. BAKAR, A. SAMAT, C. C. ZAIDI, A. AZIZ, A. G. MAZLAN",
journal="Journal of Zhejiang University Science B",
volume="10",
number="12",
pages="902-911",
year="2009",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.B0920173"
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%T Population growth, trophic level, and reproductive biology of two congeneric archer fishes (Toxotes chatareus, Hamilton 1822 and Toxotes jaculatrix, Pallas 1767) inhabiting Malaysian coastal waters
%A K. D. SIMON
%A Y. BAKAR
%A A. SAMAT
%A C. C. ZAIDI
%A A. AZIZ
%A A. G. MAZLAN
%J Journal of Zhejiang University SCIENCE B
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T1 - Population growth, trophic level, and reproductive biology of two congeneric archer fishes (Toxotes chatareus, Hamilton 1822 and Toxotes jaculatrix, Pallas 1767) inhabiting Malaysian coastal waters
A1 - K. D. SIMON
A1 - Y. BAKAR
A1 - A. SAMAT
A1 - C. C. ZAIDI
A1 - A. AZIZ
A1 - A. G. MAZLAN
J0 - Journal of Zhejiang University Science B
VL - 10
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SP - 902
EP - 911
%@ 1673-1581
Y1 - 2009
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.B0920173


Abstract: 
Population growth, trophic level, and some aspects of reproductive biology of two congeneric archer fish species, Toxotes chatareus and Toxotes jaculatrix, collected from Johor coastal waters, Malaysia, were studied. growth pattern by length-weight relationship (W=aLb) for the sexes differed, and exhibited positive allometric growth (male, female and combined sexes of T. chatareus; female and combined sexes of T. jaculatrix) and isometric growth (male samples of T. jaculatrix only). Trophic levels of both species were analyzed based on 128 specimens. The results show that, in both species, crustaceans and insects were the most abundant prey items, and among crustaceans the red clawed crab Sesarma bidens and Formicidae family insects were the most represented taxa. The estimated mean trophic levels for T. chatareus and T. jaculatrix were 3.422±0.009 and 3.420±0.020, respectively, indicating that they are largely carnivores. Fecundity of T. chatareus ranged from 38 354 to 147 185 eggs for females with total length ranging from 14.5 to 22.5 cm and total body weight from 48.7 to 270.2 g, and T. jaculatrix 25 251 to 150 456 eggs for females with total length ranging from 12.2 to 23.0 cm and total body weight from 25.7 to 275.0 g. Differences in values of gonadosomatic and hepatosomatic indexes calculated for both species in this study may have resulted from uneven sample size ranges.

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1] Allen, G.R., 1978. A review of the archer fishes (family Toxotidae). Records of the Western Australian Museum, 6(4):355-378.

[2] Allen, G.R., 2001. Toxotidae-Archer Fishes. In: Carpenter, K.E., Niem, V.H. (Eds.), FAO Species Identification Guide for Fishery Purposes. The Living Marine Resources of the Western Central Pacific. Volume 5. Bony Fishes part 3 (Menidae to Pomacentridae). FAO, Rome, Italy, p.3212-3215.

[3] Allen, G.R., 2004. Toxotes kimberleyensis, a new species of archerfish (Pisces: Toxotidae) from fresh waters of Western Australia. Records of the Western Australian Museum, 56:225-230.

[4] Allen, G.R., Midgley, S.H., Allen, M., 2002. Field Guide to the Freshwater Fishes of Australia. Western Australian Museum, Perth, Western Australia, p.394.

[5] Anderson, R., Gutreuter, S., 1983. Length, Weight, and Associated Structural Indices. In: Nielsen, L., Johnson, D. (Eds.), Fisheries Techniques. American Fisheries Society, p.283-300.

[6] Bagenal, T.B., Tesch, F.W., 1978. Age and Growth. In: Bagenal, T. (Ed.), Methods for Assessment of Fish in Freshwaters, 3rd Ed. IBP Handbook No. 3. Blackwell Scientific Publications, Oxford, UK, p.101-136.

[7] Barbin, G.P., McCleave, D.J., 1997. Fecundity of the American eel Anguilla rostrata at 45° N in Maine, USA. Journal of Fish Biology, 51(4):840-847.

[8] Beverton, R.J.H., Holt, S.J., 1996. On the Dynamics of Exploited Fish Populations. Chapman and Hall, London, p.568.

[9] Blaber, S.J.M., 2000. Tropical Estuarine Fishes Ecology, Exploitation and Conservation. Blackwell Science Ltd. London, p.106-107.

[10] Clavier, J., 1992. Fecundity and optimal sperm density for fertilization in the ormer (Haliotis tuberculata L). In: Shepherd, S.A., Tegner, M.J., Guzmán del Próo, S.A. (Eds.), Abalone of the World: Biology, Fisheries and Culture. Fishing News Books, Oxford, p.86-92.

[11] Froese, R., 1998. Length-weight relationships for 18 less studied fish species. Journal of Applied Ichthyology, 14(1-2):117-118.

[12] Gartner, J.V.Jr., 1993. Patterns of reproduction in the dominant lantern fish species (Pisces: Myctophidae) of the eastern Gulf of Mexico, with a review of reproduction among tropical-suptropical Myctophidae. Bulletin of Marine Science, 52(2):721-750.

[13] Gonçalves, J.M.S., Bentes, L., Lino, P.G., Ribeiro, J., Canario, A.V.M., Erzini, K., 1997. Weight-length relationships for selected fish species of the small-scale demersal fisheries of the south and south-west coast of Portugal. Fisheries Research, 30(3):253-256.

[14] Gunn, J.S., Milward, N.E., 1985. The food, feeding habits and feeding structures of the whiting species, Sillago sihama (Forsskal) and Sillago analis Whitley from Townsville, North Queensland, Australia. Journal of Fish Biology, 26(4):411-427.

[15] Hunter, J.R., Macewicz, B.J., Lo, N.C.H., Kimbrell, C.A., 1992. Fecundity, spawning, and maturity of female Dover Sole, Microstomus pacificus, wit an evaluation of assumptions and precision. Fishery Bulletin, 90:101-128.

[16] Hyslop, E.J., 1980. Stomach contents analyses: a review of methods and their application. Journal of Fish Biology, 17(4):411-429.

[17] Jennings, S., Kaiser, M.J., Reynolds, J.D., 2001. Marine Fisheries Ecology. Blackwell Science, Oxford, p.417.

[18] Joyce, W.N., Campana, S.E., Natanson, L.J., Kohler, N.E., Pratt, H.L., Jenson, C.F., 2002. Analyses of stomach contents of the porbeagle shark (Lamna nasus Bonnaterre) in the northwest Atlantic. Journal of Marine Science, 59(6):1263-1269.

[19] Karpouzi, V.S., Stergiou, K.I., 2003. The relationships between mouth size and shape and body length for 18 species of marine fishes and their trophic implications. Journal of Fish Biology, 62(6):1353-1365.

[20] Kolher, N., Casey, J., Turner, P., 1995. Lengthweight relationships for 13 species of sharks from the western North Atlantic. Fishery Bulletin, 93:412-418.

[21] Mazlan, A.G., Rohaya, M., 2008. Size, growth and reproductive biology of the giant mudskipper, Periopthalmodon schlosseri (Pallas, 1770) in Malaysian waters. Journal of Applied Ichthyology, 24(3):290-296.

[22] Özaydin, O., Taskavak, E., 2007. Length-weight relationships for 47 fish species from Izmir Bay (eastern Agean Sea, Turkey). Acta Adriatica, 47(2):211-216.

[23] Pauly, D., 1984. Fish population dynamics in tropical waters: a manual for use with programmable calculators. ICLARM Studies and Reviews, 8:52-80.

[24] Pauly, D., Christensen, V., 1995. Primary production required to sustain global fisheries. Nature, 374(6519):255-257.

[25] Pauly, D., Christensen, V., 2000. Trophic Levels of Fishes. In: Froese, R., Pauly, D. (Eds.), Fish Base: Concepts, Design and Data Sources. ICLARM, Manila, Philippines, p.181.

[26] Pauly, D., Palomares, M.L., 2000. Approaches for Dealing with Three Sources of Bias when Studying the Fishing down Marine Food Web Phenomenon. In: Briand, F. (Ed.), Fishing Down the Mediterranean Food Webs? Vol. 12, CIESM Workshop Series, p.61-66.

[27] Pauly, D., Sa-a, P., 2000. Estimating Trophic Levels from Individual Food Items. In: Froese, R., Pauly, D. (Eds.), Fish Base 2000: Concepts, Design and Data Sources. ICLARM, Manila, Philippines, p.185.

[28] Pauly, D., Trites, A., Capuli, E., Christensen, V., 1995. Diet Composition and Trophic Levels of Marine Mammals. International Council for the Exploration of the Sea Conference and Meeting. 1995/N: 13, p.22.

[29] Pauly, D., Trites, A., Capuli, E., Christensen, V., 1998. Diet composition and trophic levels of marine mammals. ICES Journal of Marine Science, 55(3):467-481.

[30] Pauly, D., Froese, R., Sa-a, P.S., Palomares, M.L., Christensen, V., Rius, J., 2000. TrophLab Manual. ICLARM, Manila, Philippines.

[31] Pauly, D., Palomares, M.L.D., Froese, R., Sa-a, P., Vakily, M., Preikshot, D., Wallace, S., 2001. Fishing down Canadian aquatic food webs. Canadian Journal of Fisheries and Aquatic Science, 58(1):51-62.

[32] Pethiyagoda, R., 1991. Freshwater Fishes of Sri Lanka. The Wildlife Heritage Trust of Sri Lanka, Colombo, p.362.

[33] Petrakis, G., Stergiou, K.I., 1995. Weight-length relationships for 33 fish species in Greek waters. Fisheries Research, 21(3-4):465-469.

[34] Ricker, W.E., 1973. Linear regressions in fishery research. Journal of the Fisheries Research Board of Canada, 30:409-434.

[35] Rossel, S., Corlija, J., Schuster, S., 2002. Predicting three dimensional target motion: how archer fish determine where to catch their dislodged prey. Journal of Experimental Biology, 205:3321-3326.

[36] Schuster, S., Rossel, S., Schmidtmann, A., Jäger, A., Poralla, J., 2004. Archer fish learn to compensate for complex optical distortions to determine the absolute size of their aerial prey. Current Biology, 14(17):1565-1568.

[37] Schuster, S., Wöhl, S., Griebsch, M., 2006. Animal cognition: how archer fish learn to down rapidly moving targets. Current Biology, 16(4):378-383.

[38] Simon, K.D., Mazlan, A.G., 2008. Length-weight and length-length relationship of archer and puffer fish species. Open Fish Science Journal, 1(1):19-22.

[39] Sparre, P., 1992. Introduction to Tropical Fish Stock Assessment. Part I. Manual. FAO Fisheries Technical Paper 306/1. Rev 1, Rome, Italy, p.376.

[40] Spiegel, M.R., 1991. Théorie et Applications de la Statistique. McGraw-Hill, Paris, p.358 (in French).

[41] Stergiou, K.I., Moutopoulos, D.K., 2001. A review of length-weight relationships of fishes from Greek marine waters. Naga, ICLARM Quart, 24(1-2):23-39.

[42] Stergiou, K.I., Karpouzi, V.S., 2001. Feeding habits and trophic levels of Mediterranean fish. Reviews in Fish Biology and Fisheries, 11(3):217-254.

[43] Taskavak, E., Bilecenoglu, M., 2001. Length weight relationships for 18 Lessepsian (Red Sea) immigrant fish species from the eastern Mediterranean coast of Turkey. Journal of the Marine Biological Association of the United Kingdom, 81(5):895-896.

[44] Timmermans, P.J.A., 2000. Prey catching in the archer fish: marksmanship and endurance of squirting at an aerial target. Netherlands Journal of Zoology, 50(4):411-423.

[45] Timmermans, P.J.A., 2001. Prey catching in the archer fish: angles and probability of hitting an aerial target. Behavioural Processes, 55(2):93-105.

[46] Timmermans, P.J.A., Vossen, J.H.M., 2000. Prey catching in the archer fish: does the fish use a learned correction for refraction? Behavioural Processes, 52(1):21-34.

[47] Tyler, A.V., Dunn, R.S., 1976. Ration, growth, and measures of somatic and organ condition in relation to meal frequency in winter flounder, Seudopleuronectes americanus, with hypothesis regarding population homeostasis. Journal of the Fisheries Research Board of Canada, 33:63-75.

[48] Wootton, R.J., 1990. Ecology of Teleost Fishes. Chapman and Hall, New York, US, p.404.

[49] Wootton, R.J., 1998. Ecology of Teleost Fishes. Fish and Fisheries Series, No. 24, Kluwer Academic Publishers, Dordrecht, the Netherlands, p.425.

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