Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-27T22:14:52.509Z Has data issue: false hasContentIssue false

The spatio-temporal pattern of Argentine shortfin squid Illex argentinus abundance in the southwest Atlantic

Published online by Cambridge University Press:  23 December 2005

Mar Sacau
Affiliation:
Instituto Español de Oceanografía, PO Box 1552, 36200 Vigo, Spain
Graham J. Pierce
Affiliation:
Department of Zoology, School of Biological Sciences, University of Aberdeen, Tillydrone Avenue, Aberdeen, AB24 2TZ, UK
Jianjun Wang
Affiliation:
Department of Zoology, School of Biological Sciences, University of Aberdeen, Tillydrone Avenue, Aberdeen, AB24 2TZ, UK
Alexander I. Arkhipkin
Affiliation:
Fisheries Department, Falkland Islands Government, PO Box 598, Stanley, Falkland Islands
Julio Portela
Affiliation:
Instituto Español de Oceanografía, PO Box 1552, 36200 Vigo, Spain
Paul Brickle
Affiliation:
Fisheries Department, Falkland Islands Government, PO Box 598, Stanley, Falkland Islands
María B. Santos
Affiliation:
Instituto Español de Oceanografía, PO Box 1552, 36200 Vigo, Spain Department of Zoology, School of Biological Sciences, University of Aberdeen, Tillydrone Avenue, Aberdeen, AB24 2TZ, UK
Alain F. Zuur
Affiliation:
Highland Statistics Ltd., 6 Laverock Road, Newburgh, Aberdeenshire, AB41 6FN, UK
Xosé Cardoso
Affiliation:
Instituto Español de Oceanografía, PO Box 1552, 36200 Vigo, Spain
Get access

Abstract

The Argentine shortfin squid (Illex argentinus) is a common neritic species occurring in waters off Brazil, Uruguay, Argentina, and the Falkland/Malvinas Islands in the southwest Atlantic. Illex argentinus is the most important fished cephalopod species in the area and plays a significant role in the ecosystem. It is object of major fisheries using both trawlers (mostly from European countries) and jigging vessels (mainly from Asian countries) and estimated total annual average catch for the last 15 years (1988-2003) is about 700 000 tons. The present paper aims to develop predictive models of squid abundance in relation to physical and environmental conditions, models that could ultimately be applied to fishery forecasting. Fishery and biological data collected by scientific observers aboard commercial trawlers between 1988 and 2003 were analysed in relation to physical and environmental factors to establish the spatio-temporal pattern of the species' distribution and quantify the influence of environmental variables (e.g. SST, depth) on local abundance. The data included 26 168 fishing haul records, of which 11 103 were positive for Illex. CPUE (Catch Per Unit Effort, kg h−1) was used as abundance index. The analyses were based on time-series maps created using Geographical Information Systems (GIS). GIS maps showed that highest CPUE values were recorded during the first four months of the year (the Austral summer-autumn), with peak values higher than 5000 kg h−1 mainly located within 42° S, 46° S and MN (North part of Malvinas/Falkland) areas. Generalised additive models (GAMs) were used to describe variation in Illex argentinus abundance in relation to geographical and environmental variables. The presence/absence (PA) of Illex and its abundance (CPUE) in areas of presence were modelled separately. Predictors retained in the optimal models included SST, latitude, longitude, month, average fishing depth and year. Both models suggest a clear seasonal effect: maximum catchability was found during March (PA model) and the maximum abundances were found during the first quarter of the year (CPUE model). GAM models also demonstrated that higher catches and maturity of squid were related, in general terms, to warmer and deeper water.

Type
Research Article
Copyright
© EDP Sciences, IFREMER, IRD, 2005

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Acha, E.M., Mianzan, H.W., Guerrero, R.A., Favero. M., Bava J., 2004, Marine fronts at the continental shelves of austral South America Physical and ecological processes. J. Mar. Syst. 44, 83-105. CrossRef
Arkhipkin A.I., Scherbich Z.N. 1991, Crecimiento y estructura intraespecifica del calamar Illex argentinus (Ommastrephidae) en invierno y primavera en el Atlántico Sudoccidental. Scient. Mar. 55, 619-627.
Arkhipkin A. 1990, Edad y crecimiento del calamar (Illex argentinus). Frente Marít. 6 A, 25-35.
Arkhipkin A. 1993, Statolith microstructure and maximum age of Loligo gahi (Myopsida: Loliginidae) on the Patagonian shelf. J. Mar. Biol. Assoc. UK 73, 979-982.
Arkhipkin, A.I., 2000, Intrapopulation structure of winter-spawned Argentine shortfin squid, Illex argentinus (Cephalopoda, Ommastrephidae), during its feeding period over the Patagonian Shelf. Fish. Bull. 98, 1-13.
Basson, M., Beddington, J.R., Crombie, J.A., Holden, S.J., Purchase, L.V., Tingley, G.A., 1996, Assessment and management techniques for migratory annual squid stocks: The Illex argentinus fishery in the Southwest Atlantic as an example. Fish. Res. 28, 3-27. CrossRef
Bellido, J.M., Pierce, G.J., Wang, J., 2001, Modelling intra annual variation of squid Loligo forbesi in Scottish waters using generalised additive models. Fish. Res. 52, 23-39. CrossRef
Brunetti N.E., 1988, Contribución al conocimiento biológico-pesquero del calamar argentino (Cephalopoda, Ommastrephidae, Illex argentinus ). Tesis, Mar del Plata, Argentina.
Brunetti, N.E., Ivanovic, M.L., 1992, Distribution and abundance of early life stages of squid (Illex argentinus) in the south-west Atlantic. ICES J. Mar. Sci. 49, 175-183. CrossRef
Caddy J.F., 1983, The Cephalopods: factors relevant to their population dynamics and to the assessment and management of the stocks. In: Caddy J.F. (Ed.), Advances in Assessment of World Cephalopod Resources. FAO Tech. Pap. 231, Rome.
Csirke J., 1987, Los recursos pesqueros patagónicos y las pesquerías de altura en el Atlántico Sud-occidental. FAO, Rome Doc. Tec. Pesca. 280.
Daskalov, G., 1999, Relating fish recruitment to stock biomass and physical environment in the Black Sea using generalized additive models. Fish. Res. 41, 1-23. CrossRef
Denis, V., Lejeune, J., Robin, J.P, 2002, Spatio-temporal analysis of commercial trawler data using General Additive models: Patterns of Loliginid squid abundance in the north-east Atlantic. ICES J. Mar. Sci. 59, 633-648 CrossRef
Haimovici M., Brunetti N.E., Rodhouse P.G., Csirke J., Leta R.H., 1998, Illex argentinus. In: Rodhouse P.G., Dawe E.G., O'Dor R.K.(Eds.). Squid Recruitment Dynamics. Rome, FAO, pp. 27-58.
Hastie T., Tibshinari R., 1990, Generalized additive models. London, Chapman & Hall.
Hatanaka, H., Kawahara, S., Uozumi, Y., Kasahara, S., 1985, Comparison of live cycles of five ommastrephid squids fished by Japan: Todarodes pacificus, Illex illecebrosus, Illex argentinus, Nototodarus sloani sloani and Nototodarus sloani gouldi. NAFO Sci. Counc. Stud. 9, 59-68.
Hatanaka, H., 1986, Growth and life span of short-finned squid Illex argentinus in the waters off Argentina. Bull. Jpn. Soc. Sci. Fish. 52, 11-17. CrossRef
Hatanaka, H., 1988, Feeding migration of short-finned squid Illex argentinus in the waters off Argentina. Nippon Suisan Gakkaishi 54, 1343-1349. CrossRef
Lipinski M., 1979, Universal maturity scale for the commercially important squids. The results of maturity classification of the Illex illecebrosus population for the years 1973–77. Int. Comm. Northwest Atlantic Fisheries, Res. Doc. 79/2, 38, Ser. 5364.
Martos, P., Piccolo, M.C., 1988, Hydrography of the Argentine continental shelf between 38 $^{\circ}$ and 42 $^{\circ}$ S. Cont. Shelf Res. 8, 1043-1056. CrossRef
McCullagh P., Nelder J.A., 1989, Generalized Linear Models. Chapman and Hall, London.
Nesis K.N., 1987, Cephalopods of the world. Neptune City, TFH Publications. p. 351.
Pierce, G.J., Boyle, P.R., 2003, Empirical modelling of interannual trends in abundance of squid (Loligo forbesi) in Scottish waters. Fish. Res. 59, 305-326. CrossRef
Pierce G.J., Wang J., Bellido J.M., Robin J.P., Denis V., Koutsoubas D., Valavanis V., Boyle P.R., 1998, Relationship between cephalopod abundance and environmental conditions in the northeast Atlantic and Mediterranean as revealed by GIS. ICES CM 1998/M:20.
Pierce, G.J., Wang, J., Zheng, X., Bellido, J.M., Boyle, P.R., Denis, V., Robin, J.-P., 2001, A cephalopod fishery GIS for the Northeast Atlantic: Development and application. Int. J. Geogr. Inform. Sci. 15, 763-784. CrossRef
Portela J.M., Arkhipkin A., Agnew D., Pierce G., Fuertes J.R., Otero M.G., Bellido J.M., Middleton D., Hill S., Wang J., Ulloa E., Tato V., Cardoso X.A., Pompert J., Santos B., 2002, Overview of the Spanish fisheries in the Patagonian Shelf. ICES CM 2002/L: 11.
Roberts, M.J., Sauer, W.H.H., 1994, Environment: the key to understanding the South African chokka squid (Loligo vulgaris reynaudii) life cycle and fishery ? Antarct. Sci. 6, 249-258.
Robin, J.P., Denis, V., 1999, Squid stock fluctuations and waters temperature: temporal analysis of English Channel Loliginidae. J. Appl. Ecol. 36, 101-110. CrossRef
Rodhouse, P.G., Hatfield, E.M.C., 1990, Dynamics of growth and maturation in the cephalopod Illex argentinus (Teuthoidea: Ommastrephidae). Phil. Trans. R. Soc. Lond. B. 344, 201-212.
Rodhouse, P.G., Barton, J., Hatfield, E.M.C., Symon, C., 1995, Illex argentinus: life cycle, population structure and fishery. ICES Mar. Sci. Symp. 199, 425-432.
Rodhouse P.G., Dawe E.G., O'Dor R.K., 1998, Squid recruitment dymanics. The genus Illex as a model. The commercial Illex species. Influences on variability. FAO Fish. Tech. Pap. 273.
Santos, R.A., Haimovici, M., 1997, Reproductive biology of winter-spring spawners of Illex argentinus (Cephalopoda: Ommastrephidae) Brazil. Scient. Mar. 61, 53-64.
Sato T., Hatanaka., 1983, A review of assessment of Japanese distant-water fisheries for cephalopods. In: Caddy J.F. (Ed.), Advances in assessment of world cephalopod resources. FAO Fish. Tech. Pap. 231, pp. 14-180.
Swartzman, G., Huang, C., Haluzny, S., 1992, Spatial analysis of Bering Sea groundfish survey data using generalized additive models. Can. J. Fish. Aquat. Sci. 49, 1366-1379. CrossRef
Swartzman, G., Silverman, E., Williamsom, N., 1995, Relating trends in walleye Pollock (Theragra halcogramma) abundance in the Bering Sea to environmental factors. Can. J. Fish. Aquat. Sci. 52, 369-380. CrossRef
Waluda, C.M., Pierce, G.J., 1998, Temporal and spatial patterns in the distribution of squid (Loligo spp.) in UK waters. S. Afr. J. Mar. Sci. 20, 323-336. CrossRef
Waluda, C.M., Trathan, P.N., Rodhouse, P.G., 1999, Influence of oceanographic variability on recruitment in the Illex argentinus (Cephalopoda: Ommastrephidae) fishery in the South Atlantic. Mar. Ecol. Prog. Ser. 183, 159-167 CrossRef
Waluda, C.M., Rodhouse, P.G., Trathan, P.N., Pierce, G.J., 2001, Remotely sensed mesoscale oceanography and the distribution of Illex argentinus in the South Atlantic. Fish. Oceanogr. 10, 207-216. CrossRef
Wang, J., Pierce, G.J., Boyle, P.R., Denis, V., Robin, J.P., Bellido, J.M., 2003, Spatial and temporal patterns of cuttlefish (Sepia officinalis) abundance and environmental influences: a case study using trawl fishery data in French Atlantic coast, English Channel, and adjacent waters. ICES J. Mar. Sci. 60, 1149-1158. CrossRef