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Revista de Biología Tropical

On-line version ISSN 0034-7744Print version ISSN 0034-7744

Rev. biol. trop vol.60  suppl.1 San José Mar. 2012

 

Growth and population assessment of the queen conch Strombus gigas (Mesogastropoda: Strombidae) by capture mark-recapture sampling in a natural protected area of the Mexican Caribbean

Joanne Rebecca Peel1* & Dalila Aldana Aranda1

*Dirección para correspondencia


Abstract

The Inlet of Xel-Ha is used as a park for ecotourism, representing a sanctuary for the conservation of Pink Queen Conch. Increasing fishing pressure has led to the inclusion of the species in CITES. Most knowledge about the growth of the queen conch was generated through aquaculture, ocean enclosures or obtained using estimates derived from population dynamics. In this study we estimated the growth rate of juvenile S. gigas in a natural protected area by direct methods, during the period of April 2009 to January 2011. Data was obtained by capture-mark-recapture sampling. 1418 individuals were tagged and growth of 714 conchs was analyzed. Population size and  density was estimated using Schnabel’s method. The average density was estimated  at 0.1694 ± 0.0996ind. m-2, while the highest density was estimated for September 2010 (0.3074ind. m-2). The highest growth rate (0.27 ± 0.10mm day-1) was detected in juveniles with an initial size between 100-149mm, followed by conch <100mm, with an increase of 0.24 ±  0.05mm day-1. The growth rate decreased for individuals with an initial size between 150-199mm (0.18 ± 0.09mm day-1) and for organisms > 200mm (0.08 ± 0.07mm day-1). Variability in growth rate was high in conch 100-149mm and showed seasonal differences, with the highest growth rate in May 2010. Recruitment of juveniles was highest in October 2009 and February 2010. The population of Xel-Ha has grown in size and more large and juvenile conch could be found than in previous studies, indicating that Xel-ha park is working as a sanctuary for the conservation of the queen conch in Mexico’s Riviera Maya. The growth rate of juvenile conch in Xel-Ha is high and exhibits large variations in individuals, reflecting the natural conditions of foraging and aggregation. Seasonal differences in growth rate may be associated with water quality and availability of nutrients for primary production. We conclude that the direct method is useful for the assessment of growth in juvenile S. gigas and that growth in natural conditions may be higher than in aquaculture systems. This information may be applied to fishery management as well as rehabilitation programs and aquaculture. Rev. Biol. Trop. 60 (Suppl. 1): 127-137. Epub 2012 March 01.

Keywords: Population size, Population density, Growth, Mark-Recapture, Recruitment, Nursery, Xel-Ha.

Resumen

La Ensenada de Xel-Ha es usada como parque para ecoturismo y representa un santuario para la conservación del caracol rosado. El incremento en la presión de la pesca ha llevado a la inclusión de esta especie en CITES. Mucho del conocimiento acerca del crecimiento del caracol rosado ha sido generado a través de la acuicultura, encierros oceánicos o usando estimaciones derivadas  de las dinámicas poblacionales. En este estudio estimamos la tasa de crecimiento de  Strombus gigas juvenil en un área natural protegida, por métodos directos durante el período de abril 2009 a enero 2011. Los  datos  fueron obtenidos por muestras de  captura-marca-recaptura. Un total de 1 418  individuos fueron marcados y el crecimiento  de 714 caracoles fue analizado. La talla de  la  población y la densidad relativa fue estimada usando el método de Schnabel. La densidad promedio relativa fue estimada en 0.1694±0.0996ind. m-2, mientras que la densidad más alta fue estimada para septiembre 2010 con 0.3074ind. m-2. La tasa de crecimiento más alta (0.27±0.10mm día-1)  fue  detectada en juveniles con una talla inicial entre 100-149mm, seguida por juveniles <100mm, con un incremento de 0.24±0.05mm día-1. La tasa de crecimiento disminuyó para individuos con una talla inicial entre 150-199mm (0.18±0.09mm día-1) y para organismos >200mm (0.08 ± 0.07mm día-1). La variabilidad en la tasas de crecimiento fue alta en individuos entre 100-149mm y mostró diferencias estacionales; con la tasa de crecimiento más alta en mayo  2010. El reclutamiento de juveniles más alto se dio en octubre 2009 y en febrero 2010. La población de Xel-Ha ha crecido en tamaño y se pudo encontrar más adultos y  juveniles que en estudios anteriores, lo que demuestra que el Parque de Xel-Há está funcionando como un santuario para la  conservación del caracol rosado del Caribe en la Riviera Maya de México. La tasa de  crecimiento de juveniles en Xel-Ha es alta y presenta  grandes  variaciones  en  los  individuos,  lo  cual refleja las condiciones  naturales de la alimentación y la agregación.  Las diferencias estacionales en las tasas de crecimiento pueden estar asociadas con la  calidad  del agua y la disponibilidad de nutrimentos para la producción primaria. Concluimos que el método directo es útil parar monitorear el crecimiento en juveniles de S. gigas y que el crecimiento en condiciones naturales es mayor que en sistemas de acuicultura. Esta información puede ser aplicada al manejo de pesquerías así como también en programas de rehabilitación y acuicultura.

Palabras  clave: Strombus  gigas, Área  Marina  Protegida, densidad poblacional,  crecimiento, marcaje-recaptura, reclutamiento


The queen conch (Strombus gigas Linnaeus, 1758) is a large gastropod which represents an important food and economic resource in the Caribbean, being the second largest fishery after the spiny lobster (Appeldorn 1994) with landings of 6 000 metric tons, worth $60 million Dollars (Chakalall & Cochrane 1997). The increasing fishing pressure caused populations to decline in the 1980’s and led to the inclusion of this mollusk in the Convention on International Trade of Endangered Species (CITES)  and the list of commercially threatened species. In Mexico, on the Peninsula of Yucatan, the conch fisheries reached a peak in 1983, with landings of 1 250 tons. In the late 1980’s the majority of the stocks were reported to be overexploited, especially in the state of Yucatan where a permanent fishing ban was implemented in 1988 (Baquiero-Cárdenas 1997). In Quintana Roo captures reached their maximum in the early eighties and by the end of the decade  catch  volumes  started  to  show  signs of overexploitation (Carta Pesquera Nacional 2006). This has led on one hand to the implementation of different management programs to  protect  the  conch  (INP-SAGARPA  2008) and on the other hand, to the development of its aquaculture (Berg 1976, Brownell 1977, Brownell & Stevely 1981, Rathier 1987, Glazer et al. 1997, Davis 2000, Moreno de la Torre & Aldana-Aranda 2007). The inlet of Xel-Ha is a natural marine protected area, which has been used since 1995 as a park for ecotourism. The main attraction is the observation of marine fauna in its natural environment; hence the removal of any flora or fauna is prohibited. Xel-Ha is considered a sanctuary for the conservation of the queen conch in the Mexican Riviera Maya, hosting an important number of juvenile conch (Peel et al. 2010).

Sound  management  of  a  resource  such as S. gigas, as well as its rehabilitation, protection and the development of aquaculture require  biological  and  ecological  knowledge of  the  species,  including  growth  rate,  density and population structure. In this study we determined the rate of growth of juvenile S. gigas by direct methods in a natural protected area. Data was obtained through capture-markre-capture methods, allowing the natural foraging behavior, resource selection and dispersal of the animals.

Material and Methods

Study Site: Xel-Ha is located on the east coast of the Yucatan  Peninsula (20°19’15’’-20°18’50’’N and 87°21’41’’-87°21’15’’W). The main oceanic current is the Caribbean Current (Organismo de Cuenca Península de Yucatán Dirección Técnica 2008).   The area is characterized by medium wave energy and input of fresh water by underground rivers due to karstic conditions in the Peninsula (Organismo de Cuenca Península de Yucatán Dirección Técnica 2008). Xel-Ha is a creek that consists of a mix of fresh groundwater with seawater. The Inlet is connected to the Caribbean Sea by a 100 m wide channel and has a total surface of 14 Ha with a center area and three appendices:  Bocana, North Arm  and  South Arm.  Depth ranges from 1.75-4.0m (Organismo de Cuenca Península de Yucatán Dirección Técnica 2008). The climate in the region is warm and subhumid, with rains during summer and winter. The average annual temperature is 26°C. Average annual rainfall is 1 079mm (Organismo de Cuenca Península de Yucatán Dirección Técnica 2008). The sampling site “Cueva” is located in the south-arm of the Inlet and includes a small bay surrounded by mangroves (Rhizophora mangle). Persistent upwelling of cold freshwater from underground caves, maintains a permanent thermo-and halocline (1.25m). The site has a depth 1.5-3.5m. The bottom is composed of  fine  mud  and  sand  formed  of  fragments of  calcareous  algae,  mixed  with  rocks  and dense isolated patches of macroalgae (Padina sp., Halimeda sp. Penicillus sp. Amphiroa sp. Acanthophora sp., Caulerpa sp., Dictyota sp.), decaying mangrove leaves and inverted jellyfish (Cassiopea sp.) may be found.

Population  Parameters:  Between April 2009 and January 2011, nine surveys were conducted at the site of Cueva in the Inlet of Xel-Ha sampling a total area 6 000m². Three samplings were conducted during 2009, five in 2010 and one in January 2011. All organisms were collected in free-dive, by three divers during 3 hours. We used mark-recapture method, marking all individuals with a plastic Dymo® tag, bearing a consecutive number, which was fixed to the spire of the conch with a plastic cable binder. In order to evaluate the size distribution and growth rate, shell length (SL) was determined for each individual, as well as lip thickness, using a precision vernier caliper (1mm). With the abundance data of recaptured and unmarked individuals we estimated population size using Schnabel’s method (Schnabel 1938):

Nt = Σ (Ct   Mt)/ Σ Rt

Relative density of conch in Cueva was derived  from  population  size.  To  determine the growth rate of conch per day, we only used the measurements of individuals which were recaptured for the first time after being marked in the previous sample (n=706).

Environmental parameters: Parameters for dissolved oxygen (O2), water temperature (°C), salinity, total nitrogen (N total), total phosphates (P total), nitrate (NO3-) and nitrite (NO2-), measured at the study site between February 2009 and September 2010 were provided as a courtesy of Xel-Ha Park and were used to aid interpretation of growth rates over time. Data was obtained through the laboratory  LAB-ACAMA  (Laboratorio  de Análisis de Calidad de Agua y Medio Ambiente S.A. de C.V) applying the procedures specified by the Mexican Normative for Water quality NMX-AA-26-SCFI-2001 for sampling and analysis.

Statistical Analysis: Using the program Infostat/S, we calculated the mean daily growth and standard deviation per size class (<100mm, 100-149mm, 150-199mm and ≥200mm) and the average growth per day in each class over time. Growth data was subjected to analysis of variance (ANOVA) to detect significant differences in growth rate over time and between classes, with a confidence level of 95%, followed by Tuckey’s  honestly  significant  difference  test (Saville 1990). Population structure was determined using histograms, with 10mm intervals for size classes from 45-245mm. We calculated the percentage of individuals with flaring lip per size class. A correlation analysis using Pearson coefficient (Pearson 1896) between average growth rates from each sample and corresponding density was executed.

Results

An average of 52.83%, of a total of 1418 individuals tagged, was recaptured in each sample.  The  recapture  success  was  lowest in October 2009 with 19.93% and highest in November 2010 with 74.74% (Table 1). Using the method of Schnabel, population size was estimated for each month as well as the relative density of conch in the Cueva. The relative average density was estimated at 0.1694 ±  0.0996ind.  m-2,  while  the  highest  density was estimated for September 2010 with 0.3074 conches per square meter (Table 1).

Conches with SL less than 100mm were the  scarcest  in  Cueva  representing  less  than 5%,  except  in  October  2009  and  February 2010, when 11.32% and 42.81% were captured, respectively. Relative abundance was highest  for  the  class  of  conch  between  150 and  199mm,  which  made  up  an  average  of 51.18% ±  19.57% of the population. Conch between 100 and 149mm represented on average 22.13% ± 18.69% of the population. Their abundance was highest in February 2010 with 66.50%. Organisms with length ≥ 200mm contributed on average 19.73% ± 11.80% to the population. This class had the least variation in  abundance  compared  with  other  classes. 48.01% ± 12.90% of the organisms ≥200mm showed a formed lip (Fig. 1).

In April 2009, 94% of the conchs were ≥145mm (Fig. 2). The size classes with highest frequency  of  abundance  in  that  month were  the  animals  with  SL  between  215mm and 225mm, and the animals between 185mm and 195mm, making up 26% of the population.   In June 2009 a significant increase in organisms <145mm was observed, representing 24% of the organisms sampled. Throughout October 2009 and February 2010 abundance of individuals <145mm increased dramatically, recording 63.42% and 67.73%. Modal class in October was 85-95mm (16.34%) and 125-135mm (17.24%) in February. In May the number of conch <145mm captured decreased again, with 22.5% and the modal class were juveniles between 145mm and 155mm, which represented 25.65% of the population. Modal class shifted in July to the class of 155-165mm (22.79%) and the abundance of conch <145mm continued to decline, reaching 9.35%. In September of the same year, we could detect the emergence of new recruits, with 21.65% of conch  <145mm  and  modal  class  was  185-195mm  (16.88%).  Recruits  kept  emerging throughout November, with 20.05% of the animals <145mm and modal class shifted to 195- 205mm (16.7%). In January 2011 no conchs smaller than 115mm were found and 97.37% of the sampled population had a size ≥145mm and the class with highest frequency was 195- 205mm (17.74%).

For the growth rate analysis the population was divided into 4 size classes (Fig. 3). Growth was highest in animals of 100-149mm (n=306) with an average growth of 0.27 ± 0.1mm day-1. The animals of this size class showed at the same  time  the  greatest  variation  in  growth rates, with values between 0.01 and 0.63mm day-1. The growth rate  had normal distribution (Shapiro-Wilks p=0.0856) and the median coincided with the mean. In juvenile conch smaller than 100mm (n=96) we calculated a growth rate of 0.24 ± 0.05mm day-1. Growth rate decreased to 0.18 ± 0.08mm day-1 in the class of 150 - 199mm (n=268) and was lowest with 0.08 ± 0.07mm day-1  in conch with a size ≥ 200mm (n=36) (Fig. 3). The growth rate showed significant differences between size classes (ANOVA F 3, 705  = 80.08, p <0.0001), but was similar between the classes <100mm and 100-149mm (Tuckey, p< 0.05).

The growth showed significant differences over time in classes of <100mm (F5,95 = 8.01,  p <0.0001), 100mm to 149mm (F 7, 305 = 36.98, p <0.0001) and 150mm to 199mm (F 7,  267  = 9.14;  p  <0.0001). There were  no  significant differences in the class of animals ≥ 200mm (F 6, 35 = 1.46; p = 0.2262). The highest growth rate was observed in May 2010, while the lowest growth was observed in October 2009 and November 2010 (Fig. 4 and Table 2).

No significant association was detected between growth rate and the relative density of conch (R=0.17; p = 0.69).

Xel-Ha Park occasionally carries out surveys to monitor water quality. The results corresponding to the area of Cueva are shown in Figure 5.

Discussion

In the present work conch larger than 210mm were present in all samples and a total of 268 observations could be made, representing 8.42% of the population. Aldana-Aranda et al. (2005) reported the absence of animals larger than 210mm at  Cueva  in  the  majority of the samples taken in a study conducted between 2001 and 2002. Xel-Ha initiated the Monitoring Program, as well as the actions for conservation and rehabilitation of the queen conch in October 2001. The conch population of Xel-Ha has grown in size and more large and juvenile conch could be found than in previous studies, suggesting that the park of Xel-Ha is providing effective protection for the species.

Apparent recruitment was detected throughout most of the year, but was highest from June 2009 to May 2010 and September 2010 to November 2010. Aldana-Aranda et al.  (2003)  documented recruitment throughout most of the year and high recruitment during October 2001. In a subsequent study Aldana-Aranda et al. (2005) documented higher  recruitment  in  October  2002,  February 2002 and February 2003, consistent with recruitment peaks observed in this study, in February and October.

In the present study population structure was: <100mm = 7.0%; 100-149mm = 22.1%; 150-199mm = 51.2%; ≥200mm = 19.7%. Aldana-Aranda et al. (2005) reported 4.2% of the population <100mm, 23.8% in the class of 100-150mm,  51.2%  conch  150-200mm  and 23.4% of the population >200mm in the period from November 2001 to August 2003, applying the same methodology. It can be noted that relative proportion of adults and juveniles has remained similar in comparison with previous studies,  despite  the  increase  in  numbers  of individuals, indicating the population is in an equilibrium state.

In the present study, the population was small initially; however, we observed substantial recruitment of juveniles from October 2009 onwards, reaching a maximum density of 0.3074 conches per square meter in September 2010. Aldana-Aranda et al. (2005) estimated a population size of 632.15 ± 49.40 individuals in the period from 2001 to 2003, using Schnabel’s method. Peel et al. (2010) reported average catches of 82.09 conches per sample in the period from January 2004 to January 2008 at the sampling site Cueva. The observed population growth was attributed to increased recruitment of juveniles.

The Density at Xel-Ha’s Cueva is high, compared to other areas in the Caribbean (Table 3). The densities documented at Cueva were higher than densities reported for Alacranes Reef, where conch fishery was banned in 1988 (Pérez-Pérez & Aldana-Aranda 1998, Ríos-Lara et al. 1998, Pérez-Pérez & AldanaAranda  2000,  Pérez-Pérez  & Aldana-Aranda 2003), ranging from 0.0047 to 0.018 conch m-2.

They were also higher than the densities reported  for  the  two  most  important  commercial  queen conch fishery grounds in Quintana Roo, Banco Chinchorro (0.0211 ± 0.035ind m-2) and Banco  Cozumel  (0.0079  ±  0.01653ind  m-2). In Punta Gavilán, a coastal area without commercial fishing, densities range from 0.003 to 0.0052ind. m-2 (De Jesús-Navarrete et al. 1992, De Jesús-Navarrete & Oliva-Riviera 1997). Berg & Glazer (1994) reported in the Florida Keys, USA, densities between 0.000109ind. m-2 and 0.000298ind. m-2, where a permanent fishing ban has been implemented since 1985 and sanctuaries with surveillance have been created due to the rapid depletion of stocks of Queen Conch. The density at Xel-Ha’s Cueva is similar to the relatively natural populations in the Exuma Cays (Table 4) (Stoner & Ray 1993, Stoner 1996) and can be compared to the highdensity aggregation  nursery  grounds  (Stoner & Ray 1993, Stoner & Lally 1994) in terms of population structure and density.

The growth rate of juvenile conch in Cueva was high in comparison with those mentioned by other studies (Table 4). De Jesús-Navarrete (2001) obtained an average increase of 3.21mm month-1   (~0.1052mm day-1) in Punta Gavilán and 2.30mm month-1 (~0.075mm day-1) in Banco Chinchorro, maintaining conch in enclosures at density of 0.4ind. m-2. In other areas of the Caribbean similar increases were observed (Randall 1964, Alcolado 1976, Brownell 1977, Ray & Stoner 1994). Growth  rates measured during  this  study  were  comparable  to  other studies  conducted   under   natural  conditions using  mark-recapture methods. Gibson et al. (1983) determined a rate of 7.2mm month-1 (~0.236mm day-1) in Belize, while in Venezuela an increase of 15mm month-1 (~0.492mm day-1) was measured (Weil & Laughlin 1984) and in Punta Gavilán, juveniles grew an average of 10mm month-1   (~0,327mm day-1) (De  JesúsNavarrete & Oliva-Rivera 1997). The  growth rate of juvenile queen conch at Xel-Ha’s Cueva was  comparable  to  the  growth  measured  by Moreno de la Torre & Aldana-Aranda (2007) under  experimental   conditions,  using  artificial diets, who  obtained an increase of 0.16-0.23mm  day-1.  However,  the  conch  used  in their study had an initial size inferior to 40mm and were smaller than the organisms in the present study.

Growth rates declined in the 150-199mm size class and tended towards null in conch ≥200mm (Fig. 3). Conches grow in shell length only until maturation. At this time the flared shell-lip is formed. Subsequent shell growth occurs as a progressive thickening of the shelllip (Appeldoorn 1988). Most conch reach sexual  maturation  when  the  shell  lip  is  thicker than 5mm (Appeldorn 1988, Aldana-Aranda & Frenkiel 2007). Shell morphology and maximum size  can  vary  considerably  (Alcolado 1976, Appeldoorn 1994) and may not represent a good indicator for maturity (Aldana-Aranda & Frenkiel 2007). The maximum SL observed at Xel-Ha in our study was 239mm and less than the half of the organisms in the ≥200mm class had developed a flaring lip. It may be deduced  that  more  than  half  of  the  conch ≥200mm are still immature and may represent some considerable growth.

Growth rate of the queen conch showed large individual variations, especially in animals of the class of 100-149mm. Alcolado (1976) showed that growth may vary according to environmental variability between sites; however, the study area of the Cueva is a relatively small area, making it more likely that all organisms have been exposed to the same conditions. Ray & Stoner (1994) suggested that juvenile conch are vulnerable to predation and may choose lower quality habitat in terms of resources, compromising maximum ingestion and growth, by aggregating or sheltering in dense vegetation, to reduce the risk of predation and increase survival probabilities. The high growth rate of juvenile conch in Xel-Ha and the large variations in individuals likely reflects the natural conditions of foraging and aggregation.

We could detect significant variation in the rate of growth over time (Fig. 4). There was an increase in nutrients important for production of biomass (P, N and NO) in the sample of March 2010, for which it is likely that the increase in growth rate during May 2010 might be the result of higher primary productivity.

We conclude that the direct method is useful for the assessment of growth in juvenile S. gigas and that growth in natural conditions is higher than in enclosures and aquaculture systems. This information may be applied to fishery management as well as to rehabilitation programs and aquaculture.

Acknowledgments

We gratefully acknowledge financial support  by  CONACYT  through  Grant  Conacyt SEP 24210 Connectivity of the Conch in the  Caribbean,  CONACYT  student  scholarship (374674/243375) and CINVESTAV-IPN. Also we thank Xel-Ha Park’s administration, Elizabeth Lugo Monjarras and Ricardo Saenz Morales for providing unlimited access and logistic support during our field work. We thank Xel-Ha staff Enrique May, Teresa Rivas, Angel Chavarria and Mario Hoil for their field support.


References

Alcolado,  P.M. 1976. Crecimiento, variaciones  morfológicas de la concha y algunos  datos biológicos del cobo Strombus gigas L. (Mollusca, Mesogastrópoda). Acad. Cien. Cuba Ser. Oceanol. 34: 36.         [ Links ]

Aldana-Aranda, D. & L. Frenkiel. 2007. Lip thickness of Strombus gigas (Mollusca:Gastropoda) versus maturity: A management measure. Proc. Gulf Carib. Fish. Inst.58: 431-442.         [ Links ]

Aldana-Aranda, D., M. Sánchez-Crespo, V. Patiño-Suárez, A. George-Zamora, A.E.  Carillo & S. Pérez. 2003. Abundancia, frecuencia de tallas y distribución espacial del caracol rosa Strombus gigas en el parque Xel-Ha, México. P 33-37. In D. Aldana-Aranda. (ed.). El caracol Strombus gigas: Conocimiento Integral para su Manejo Sustentable en el Caribe. CYTED, Merida, Yucatán, México.         [ Links ]

Aldana-Aranda, D., M. Sánchez-Crespo, P.   Reynaga-Alvarez, V. Patiño-Suárez, A. George-Zamora & E.R. Baqueiro-Cárdenas. 2005. Crecimiento y temporada reproductiva  del  caracol  rosa   Strombus  gigas  en el parque Xel-Há,  México. Proc. Gulf Carib. Fish. Inst.56: 741-754.         [ Links ]

Appeldoorn, R.S. 1988. Age determination, growth, mortality and age of first  reproduction in adult queen conch, Strombus gigas L., off Puerto Rico. Fish. Res.
6: 363-378.         [ Links ]

Appeldorn,  R.S.  1994.  Queen  conch  management  and research: status, needs and priorities. p. 301-319. In Appeldorn,  R. S. & B. Rodriguez, (eds.). Strombus gigas  Queen  Conch  Biology,  Fisheries  and  Mariculture. Fundación Científica  Los Roques, Caracas, Venezuela.         [ Links ]

Baquiero-Cardenas, E.R. 1997. The molluscan  fisheries of Mexico, p. 39-49. In  MacKenzie, C.L Jr., V.G. Burrell, A. Rosenfield & W.L. Hobart (eds.) NOAA Tech. Rep. NMFS 129: The History, Present Condition and Future of the Molluscan Fisheries of North and  Central  America and Europe. U.S. Dept. of Commerce.         [ Links ]

Berg, C.J. 1976. Growth of queen conch, Strombus gigas, with a discussion of the particularity of its mariculture. Mar. Biol. 34: 1-36.         [ Links ]

Berg, C.J. &  R.A.Glazer. 1994. Current research on queen conch (Strombus gigas) in Florida Waters. Proc. Gulf Carib. Fish. Inst.40: 303-306.         [ Links ]

Brownell, W.N., C.J. Berg, Jr., & K.C. Haines. 1977. Fisheries and aquaculture of the queen conch, Strombus gigas, in the Caribbean. FAO Fish. Rep. 200: 59-69.         [ Links ]

Brownell, W.N. & J.M. Stevely. 1981. The biology, fisheries, and management of the queen conch, Strombus gigas. Mar. Fish. Rev., U.S. Dept. Comm. 43:1- 12.         [ Links ]

Chakalall,  B. & K.L. Cochrane. 1997. The  queen conch fishery in the Caribbean–An approach to responsible fisheries management. Proc. Gulf Carib. Fish.  Inst. 49:531-554.         [ Links ]

Davis,  M.  2000.  Queen  conch  (Strombus  gigas)  culture  techniques  for  research  stock  enhancement  and growout markets, p 127-159. In Fingerman, M. & R. Nagabhushanam (eds.). Recent advances  in marine biotechnology Vol.4:  Aquaculture Part A Seaweeds and   Invertebrates. Science Publishers, Inc.,   New Hampshire, USA.         [ Links ]

De  Jesús-Navarrete, A., E. González, J. Oliva, A. Pelayo & G. Medina. 1992. Advances over some ecological aspects of queen conch  Strombus gigas, L. in the southern  Quintana Roo, Mexico. Proc. Gulf  Carib. Fish. Inst.45: 18-24.         [ Links ]

De Jesús-Navarrete, A. & J.J.Oliva-Riviera. 1997. Density, growth, and recruitment of the queen conch Strombus gigas L. (Gastropoda: Strombidae) in Quintana Roo, Mexico. Rev. Biol. Trop. 45: 797-801.         [ Links ]

De  Jesús-Navarrete,  A.  2001.  Crecimiento  del  caracol Strombus gigas (Gastropoda:  Strombidae) en cuatro ambientes  de   Quintana  Roo,  México.  Rev.  Biol. Trop., 49: 85-91.         [ Links ]

Friedlander, A., R.S. Appeldoorn & J. Beets.  1994. Spatial and temporal variations  in stock abundance of queen  conch,  Strombus  gigas,  in  the  U.S.  Virgin Islands, p. 51-60 In R.S. Appeldoorn & B. Rodriguez (eds.). Queen Conch Biology,  Fisheries and Mariculture, Fundacion  Cientifica Los Roques, Caracas, Venezuela.         [ Links ]

Gibson, J, S. Strasdine & K. Gonzales. 1983. The status of the conch industry of Belize. Proc. Gulf Carib. Fish. Inst. 35: 99-107.         [ Links ]

Glazer, R.A. & R. Jones. 1997. Temporal factors influencing survival of queen conch outplants. Final Report. U.S. Fish and Wildlife Service Project: 1-58.         [ Links ]

INP-SAGARPA. 2008. Dictamen Técnico:  Estimación de biomasa explotable de Strombus gigas en los bancos abiertos a la pesca en  Quintana Roo, México: Banco Chinchorro y Banco de Cozumel. Temporada  de Captura 2008-2009.         [ Links ]

Moreno de la Torre, R. & D. Aldana-Aranda. 2007. Crecimiento y eficiencia  alimenticia del caracol rosado Strombus gigas (Linnaeus, 1758) juvenil alimentado con nueve alimentos  balanceados conteniendo diferentes niveles de proteína y energía. Proc. Gulf Carib. Fish. Inst.58: 463-467.         [ Links ]

Pearson,  K.  1986.  Mathematical   Contributions  to  the Theory of Evolution.--On a Form of Spurious Correlation Which May Arise When Indices Are Used in the Measurement of Organs  . Proc. R. Soc. Lond. 60:489-498.         [ Links ]

Peel,  J.R., R. Saenz, E. May, J. Montero &  D. Aldana-Aranda. 2010. Importance of a Marine Protected Area in the Mexican  Caribbean on the Conservation of the  Endangered Species of Queen Conch,  Strombus gigas. GCFI Book of Abstract 63: 39.         [ Links ]

Pérez-Pérez, M. & D. Aldana Aranda. 1998. Análisis preliminar de la densidad del caracol rosado (Strombus gigas)  en  el  arrecife  Alacranes  Yucatán,  México. Proc. Gulf Carib. Fish. Inst.50: 49- 65.         [ Links ]

Pérez-Pérez, M. & D. Aldana-Aranda. 2000. Distribución, abundancia,  densidad  y  morfometría  de  Strombus gigas  (Mesogastropoda:Strombidae) en el  Arrecife Alacranes  Yucatán,  México.   Rev.   Biol.  Trop.  48: 51-57.         [ Links ]

Pérez-Pérez, M. & D. Aldana-Aranda. 2003. Actividad de Strombus  gigas  (Mesogastropoda: Strombidae) en diferentes hábitats del arrecife  Alacranes, Yucatán. Rev.Biol. Trop. 51: 119-126.         [ Links ]

Posada, J.M., R.I. Mateo & M. Nemth. 1999. Occurrence, abundance and length frequency distribution of queen conch,   Strombus  gigas  (Gasteropoda)  in   shallow waters  of  the  Jaragua  National  Park,  Dominican Republic. Carib. J.of Sci. 35: 70-82.         [ Links ]

Randall, J.E. 1964. Contribution to the biology of the queen conch Strombus gigas. Bull.  Mar. Sci. Gulf Carib. 14:246-295.         [ Links ]

Rathier, I. 1987. Etat d’avancement des  recherches  sur l’élevage  du  lambi  Strombus  gigas  in  Martinique. Proc. Gulf Carib. Fish. Inst 38: 336-344.         [ Links ]


Ray, M. & A.W. Stoner. 1994. Experimental  analysis of growth and survivorship in a marine gastropod aggregation:  Balancing  growth  with  safety  in  numbers. Mar. Ecol. Prog. Ser 105: 47-59.         [ Links ]

Ríos-Lara, G.V., K. Cervera-Cervera, J.C. Espinoza-Méndez, M. Pérez-Pérez, C. Zetina-Moguel, & F. Chable Ek. 1998. Estimación de las Densidades de langosta espinosa (Panulirus argus) y caracol rosa (Strombus gigas) en el área central del Arrecife Alacranes, Yucatán, México. Proc. Gulf Carib. Fish. Inst.50:104-127.         [ Links ]

Saville, D.J. 1990. Multiple Comparison Procedures: The Practical Solution. Am. Stat. 44:174-180.         [ Links ]

Schnabel, Z. E. 1938. The estimation of the total fish population of a lake. Amer. Math. Month. 45:348-352.         [ Links ]

Stoner, A.W. & K.C. Schwarte. 1994. Queen conch, Strombus gigas, reproductive  stocks in the central Bahamas:  distribution and probable sources. Fish.  Bull., U.S. 92:171-179.         [ Links ]

Stoner, A.W. 1996. Status of queen conch research in the Caribbean. Proceedings  International Queen Conch Conference  Strombus gigas: 23-39.         [ Links ]

Stoner, A.W. & M. Ray. 1993. Aggregation  dynamics in juvenile queen conch  (Strombus gigas): population structure, mortality, growth and migration. Mar Biol. 116:571-582.         [ Links ]

Stoner, A.W. & M. Ray. 1996. Queen conch  (Strombus gigas) in fished and unfished locations of the Bahamas: effects of a marine fishery reserve on adults, juveniles, and  larval production. Fish. Bull. 94:551-565.         [ Links ]

Weil, M. & G. Laughlin. 1984. Biology, population dynamics, and reproduction of the queen conch, Strombus gigas  Linné.,  in  the  Archipielago  de  los  Roques National Park. J. Shellfish Res. 4:45-62.         [ Links ]

*Correspondencia:
Joanne Rebecca Peel: Centro de Investigación y de Estudios Avanzados del Instituto Politécnico Nacional, Km  6  Antigua Carretera a Progreso, Mérida, Yucatán, México; jrpeel@gmx.de
Dalila Aldana Aranda: Centro de Investigación y de Estudios Avanzados del Instituto Politécnico Nacional, Km  6  Antigua Carretera a Progreso, Mérida, Yucatán, México.

1. Centro de Investigación y de Estudios Avanzados del Instituto Politécnico Nacional, Km 6 Antigua Carretera a Progreso, Mérida, Yucatán, México; jrpeel@gmx.de


Received 14-VI-2011.    Corrected 02-XII-2011.    Accepted 20-XII-2011

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