Open-access Relative growth and morphological sexual maturity of Chasmagnathus granulatus (Crustacea, Varunidae) from a mangrove area in southeastern Brazilian coast

Crescimento relativo e maturidade sexual morfológica de Chasmagnathus granulatus (Crustacea, Varunidae) de uma área de manguezal no sudeste do Brasil

Abstracts

The relative growth and morphological sexual maturity of Chasmagnathus granulatus Dana, 1851 are presented for the first time to a mangrove population. The crabs were obtained during low tide periods, in the mangrove of Jabaquara Beach, Paraty, Rio de Janeiro, Brazil. All crabs in intermolt stage were sexed and had their body parts measured as follows: body height (BH), carapace length (CL) and width (CW), major cheliped propodus height (PH) and length (PL) for each sex, gonopod length (GL) and abdomen width (AW) for males and females, respectively. The relative growth was described using the allometric equation y=ax b and the size at onset sexual maturity was achieved using the software Mature I. The size of specimens ranged from 4.1 mm to 39.5 mm CW. The growth pattern was different between sexes in the cheliped relationships; the relationships BH vs. CW evidenced positive allometry for juveniles; PL vs. CW and PH vs. CW positive allometry for most crabs except juvenile females; AW vs. CW and GL vs. CW evidenced positive allometry for juveniles and isometry for adults. The relationships that best indicated the change from the juvenile to the adult phase were PH vs. CW for males and AW vs. CW for females. The size in which 50% of males from this population are mature is at 19.7 mm of CW (F=144.14; p<0.05) and for females it is at 19.2 mm of CW (F=166.54; p<0.05). The sizes obtained in this mangrove population are larger than those from previous studies, that could be attributed to a species plasticity concerning the habitat structure.

Grapsoidea; semiterrestrial crabs; morphometric relationships; allometric growth


O crescimento relativo e a maturidade sexual morfológica de Chasmagnathus granulatus Dana, 1851 são apresentados pela primeira vez para uma população de manguezal. Os caranguejos foram obtidos durante os períodos de maré baixa, no manguezal da praia do Jabaquara, Paraty, Rio de Janeiro, Brasil. Todos os caranguejos em estágio de intermuda foram classificados quanto ao sexo e as seguintes medidas lineares foram tomadas: altura do corpo (AC), altura do própodo do quelípodo maior (APQ), comprimento da carapaça (CC), comprimento do própodo do quelípodo maior (CPQ), largura da carapaça (LC), comprimento do gonopódio (CG) e largura do abdome (LA) para machos e fêmeas, respectivamente. O crescimento relativo foi descrito a partir da equação alométrica y=ax b e o programa Mature I utilizado para a estimativa do tamanho na maturidade. O tamanho dos espécimes variou de 4,1 mm a 39,5 mm de LC. O padrão de crescimento foi diferente entre os sexos nas relações com o quelípodo, as relações AC vs. LC evidenciaram alometria positiva para juvenis, CPQ vs. LC e APQ vs. LC alometria positiva para quase todos caranguejos exceto fêmeas jovens e LA vs. LC e CG vs. LC evidenciaram alometria positiva para jovens e isometria para adultos. As relações que melhor evidenciaram a mudança da fase juvenil para a adulta foram APQ vs. LC para machos e LA vs. LC para fêmeas. O tamanho no qual 50% dos machos da população encontram-se maduros foi estimado em 19,7 mm de LC (F=144,14; p<0,05) e para as fêmeas em 19,2 mm LC (F=166,54; p<0,05). Os tamanhos obtidos nesta população de manguezal são maiores do que aqueles obtidos em estudos anteriores, o que pode ser atribuído a plasticidade da espécie em relação a estrutura do habitat.

Grapsoidea; caranguejos semiterrestres; relações morfométricas; crescimento alométrico


Rafael Augusto Gregati; Maria Lucia Negreiros-Fransozo

NEBECC (Grupo de Estudos em Biologia, Ecologia e Cultivo de Crustáceos), Departamento de Zoologia - Universidade Estadual Paulista, UNESP, 18618-000 Botucatu, SP, Brazil. (gregati@ibb.unesp.br; mlnf@ibb.unesp.br)

ABSTRACT

The relative growth and morphological sexual maturity of Chasmagnathus granulatus Dana, 1851 are presented for the first time to a mangrove population. The crabs were obtained during low tide periods, in the mangrove of Jabaquara Beach, Paraty, Rio de Janeiro, Brazil. All crabs in intermolt stage were sexed and had their body parts measured as follows: body height (BH), carapace length (CL) and width (CW), major cheliped propodus height (PH) and length (PL) for each sex, gonopod length (GL) and abdomen width (AW) for males and females, respectively. The relative growth was described using the allometric equation y=axb and the size at onset sexual maturity was achieved using the software Mature I. The size of specimens ranged from 4.1 mm to 39.5 mm CW. The growth pattern was different between sexes in the cheliped relationships; the relationships BH vs. CW evidenced positive allometry for juveniles; PL vs. CW and PH vs. CW positive allometry for most crabs except juvenile females; AW vs. CW and GL vs. CW evidenced positive allometry for juveniles and isometry for adults. The relationships that best indicated the change from the juvenile to the adult phase were PH vs. CW for males and AW vs. CW for females. The size in which 50% of males from this population are mature is at 19.7 mm of CW (F=144.14; p<0.05) and for females it is at 19.2 mm of CW (F=166.54; p<0.05). The sizes obtained in this mangrove population are larger than those from previous studies, that could be attributed to a species plasticity concerning the habitat structure.

Keywords: Grapsoidea, semiterrestrial crabs, morphometric relationships, allometric growth.

RESUMO

O crescimento relativo e a maturidade sexual morfológica de Chasmagnathus granulatus Dana, 1851 são apresentados pela primeira vez para uma população de manguezal. Os caranguejos foram obtidos durante os períodos de maré baixa, no manguezal da praia do Jabaquara, Paraty, Rio de Janeiro, Brasil. Todos os caranguejos em estágio de intermuda foram classificados quanto ao sexo e as seguintes medidas lineares foram tomadas: altura do corpo (AC), altura do própodo do quelípodo maior (APQ), comprimento da carapaça (CC), comprimento do própodo do quelípodo maior (CPQ), largura da carapaça (LC), comprimento do gonopódio (CG) e largura do abdome (LA) para machos e fêmeas, respectivamente. O crescimento relativo foi descrito a partir da equação alométrica y=axb e o programa Mature I utilizado para a estimativa do tamanho na maturidade. O tamanho dos espécimes variou de 4,1 mm a 39,5 mm de LC. O padrão de crescimento foi diferente entre os sexos nas relações com o quelípodo, as relações AC vs. LC evidenciaram alometria positiva para juvenis, CPQ vs. LC e APQ vs. LC alometria positiva para quase todos caranguejos exceto fêmeas jovens e LA vs. LC e CG vs. LC evidenciaram alometria positiva para jovens e isometria para adultos. As relações que melhor evidenciaram a mudança da fase juvenil para a adulta foram APQ vs. LC para machos e LA vs. LC para fêmeas. O tamanho no qual 50% dos machos da população encontram-se maduros foi estimado em 19,7 mm de LC (F=144,14; p<0,05) e para as fêmeas em 19,2 mm LC (F=166,54; p<0,05). Os tamanhos obtidos nesta população de manguezal são maiores do que aqueles obtidos em estudos anteriores, o que pode ser atribuído a plasticidade da espécie em relação a estrutura do habitat.

Palavras-chave: Grapsoidea, caranguejos semiterrestres, relações morfométricas, crescimento alométrico.

The estuarine crab Chasmagnathus granulatus Dana, 1851 has an important role in the intertidal areas, moving great amounts of sediment to catch food and for the maintenance of the burrows, influencing the quality, penetrability and transport of the substratum (BOTTO & IRIBARNE, 2000). Several authors have studied C. guanulatus concerning many biologic subjects up to date, including its relative growth and sexual maturity (RUFFINO et al., 1994; LÓPEZ et al., 1997; LÓPEZ-GRECO & RODRÍGUEZ, 1999; LUPPI et al., 2004), but none has investigated a mangrove population.

Information about growth frequently is used to evidence changes in the development stages of the animals, for example, size in the sexual maturity (VANINI & GUERARDI, 1988). The size in which a certain species reaches its sexual maturity represents an important parameter for the understanding of the brachyuran's life cycle (HARTNOLL & GOULD, 1988).

According to HARTNOLL (1982), the relative growth is defined by means of the growth of different body parts in relation to a body dimension that expresses the animal size as a whole. The level of allometry and the growth pattern can suggest the size in which the animal attains the morphological sexual maturity (GONZÁLEZ-GURRIARÁN & FREIRE, 1994).

The objective of this paper was to determine the relative growth and the size at onset of the morphological sexual maturity of a unique population of C. granulatus from a tropical mangrove area.

MATERIAL AND METHODS

The samplings were carried out monthly, from April 2003 to March 2004, in the mangrove associated to Jabaquara beach, along the Jabaquara River, Paraty, south state of Rio de Janeiro, Brazil (23º13'04"S and 44º42'47"W).

The crabs were captured manually in low tide period, inside their burrows along the principal river, by two collectors over a period of 45 minutes. The crabs were bagged, labeled and stored frozen until the morphometric analysis in the laboratory.

The sex of each crab was recorded and the following body dimensions were measured with a digital caliper (0.01 mm): body height (BH), carapace length (CL) and width (CW), major cheliped propodus height (PH) and length (PL), abdomen width for females (AW) and gonopod length (GL) for males (Fig. 1). Only intermolt crabs were used in this analysis.


The median sizes of males and females are compared by Mann-Whitney test at 5% significance (ZAR, 1996).

The morphometric data were plotted in dispersion graphics, the relative growth was described from the adjustment of the points to the alometric equation y=axb and linearized (log y = log a + b log x) (HUXLEY, 1950). The CW was used as independent variable ("x") and related with the other corporal dimensions ("y"). The "b" of the equation express the allometric coefficient and its value was submitted to t of Student test (Ho: b=1; a =5%). The slopes and the intercepts were analyzed by covariance analysis (ANCOVA, a =5%) between sexes and between development phases (ZAR, 1996).

The Mature I software (SOMERTON, 1980) was adopted to estimate the size at onset of sexual maturity for crabs, based on the regression analysis of relative growth. In this case, two values (juvenile bound and adult bound) are chosen such that the "x" axis is divided into three regions: the leftmost region (juveniles), the rightmost region (adults) and middle region (unknown mixture of juveniles and adults. Preliminary estimates of the two phase lines are made by fitting straight lines, using linear regression, to the known juvenile and adult data. The lines are extrapolated into the middle region and the difference in "y" direction between every data point and each of the two lines is calculated. According to SOMERTON (1980), the test statistic has an F distribution.

RESULTS

A total of 599 crabs (351 males and 248 females), with a size range of 4.1 mm to 39.5 mm of CW (24.4 ± 7.5) were used for the analyses of relative growth and morphological sexual maturity.

The males attained sizes greater than females (Mann-Whitney test, p < 0.05) and the growth curves of the juvenile and adult phases differed in all the regressions (ANCOVA, p < 0.05). The growth pattern was different between sexes in the cheliped relationships (PL vs. CW and PH vs. CW) and in the relationship CL vs. CW for adults (ANCOVA, p < 0.05), while the relationship CL vs. CW for juveniles and BH vs. CW for juveniles and adults also presented the same growth pattern for both sexes (ANCOVA, p > 0.05).

The relationships studied in the relative growth and allometric levels of C. granulatus are presented in Table I. The analysis of the relationship BH vs. CW evidenced positive allometry for juvenile males and juvenile females, while the adults of both sexes presented isometry. For the relationship CL vs. CW both sexes presented isometry, except adult females that presented negative allometry.

The relationships PL vs. CW and PH vs. CW indicated a positive allometry for most crabs except juvenile females, which presented isometry in the relation PL vs. CW. The relationship AW vs. CW (for females) and GL vs. CW (for males) evidenced positive allometry for juveniles and isometry for adults. The relationships that evidenced the maturity and showed a change in the growth pattern were PH vs. CW for males and AW vs. CW for females (Fig. 2).



The size of morphological sexual maturity of C. granulatus in 50% of the males in the studied population was 19.7 mm of CW, being 14.7 mm of CW the smallest mature male and 25.0 mm of CW the largest immature male (F=80.64; p<0.05) (Figs. 2, 3). For females, the size at which 50% were mature was 19.2 mm of CW, being 17.5 mm of CW the smallest mature female and 22.6 mm of CW the largest immature female (F=166.54; p<0.05) (Figs. 2, 3).

DISCUSSION

The availability and the quality of the food, besides an adequate substratum in the environment are the main factors that influence the growth and size of the crabs (GENONI, 1985; COLPO & NEGREIROS-FRANSOZO, 2002). The size variations are common and it can be due to the phenotypic plasticity of the organisms or influenced by environmental factors (as photoperiod, temperature and rainfall) that also affect the food availability (CAMPBELL & EAGLES, 1983). Such factors can explain the larger size of C. granulatus specimens from Paraty, when compared with the majority of the other population of the same species (Tab. II). CONDE & DÍAZ (1989) found differences in the size among Aratus pisonii (H. Milne Edwards, 1837) populations and attributed such difference to the food availability in the environment. Thus, in the case of C. granulatus, probably the species finds more alimentary resources in the mangrove ecosystem than in other estuarine environments, as the salt marshes.

Frequently among the crustaceans, females present a slower growth after the sexual maturity, probably in function of the energy resource aiming for the egg production (HARTNOLL, 1982; DÍAZ & CONDE, 1989; HAEFNER & SPAARGAREN, 1993). It is common to find males reaching larger sizes than females, as in this study. According to WARNER (1967) and DÍAZ & CONDE (1989), such fact could be a consequence of the reproductive period that demands more energy resources for the females. Other factors as different mortality rates between sexes (WOLF et al., 1975), migration (MONTAGUE, 1980), the greater facility of one sex to support the ambient adversities, the spatial and temporal disequilibrium between sexes in the use of the environmental resources and behavior (GIESEL, 1972) can also influence the difference of size between sexes of the same species.

The size in which males of C. granulatus reached the morphological sexual maturity was higher than the value found for females, similar to the pattern proposed by SHINE (1988) for brachyurans. According to such author, the variation in the size of the maturity between sexes is, generally, explained by a differentiated reproductive needs. The females when directing its energy for reproductive purposes as spawn and incubation of eggs tend to mature with inferior sizes to the males, who invest its resources in somatic growth, reaching larger sizes, favoring cohort and coupling. This fact was registered by LÓPEZ-GRECO & RODRÍGUEZ (1999), in reproductive behavior experiments of the same species in nature and laboratory. These authors found that the males were larger females in all the registered cases.

The relations that had better evidenced the sexual maturity was GL vs. CW for males and AW vs. CW for females of C. granulatus (RUFFINO et al., 1994; LÓPEZ et al., 1997), and in Goniopsis cruentata (Latreille, 1803) (COBO & FRANSOZO, 1998) and in Sesarma rectum Randall, 1840 (MANTELATTO & FRANSOZO, 1999; SILVA & CHACUR, 2002). According to HARTNOLL (1982), the female abdomen have reproductive attributions, protecting the gonopores and the eggs during the incubation period and the gonopod is related with spermathophore transference. Thus structures can evidence the sexual maturity.

The morphological sexual maturity for C. granulatus was evidenced by the relationships PH vs. CW for males and AW vs. CW for females, corroborating the high allometric index found for the cheliped relations in the above cited papers. In fact, among the Brachyura, the sexual dimorphism is very commonly showed by the cheliped size (HARTNOLL, 1974). According to CRANE (1957; 1958), such fact can occur by behavioral reasons, in which the males are more active in territorial disputes, cohort and combats, as presented mainly in the genus Uca Leach, 1814.

Acknowledgements. The authors are indebted with FAPESP (#94/4878-8 and #98/3134-6) and CAPES (master science fellowship to the first author) and all help provided by NEBECC members. All the samplings were accomplished according to State and Federal laws concerning wild animals.

Recebido em março de 2006. Aceito em dezembro de 2006.

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  • Relative growth and morphological sexual maturity of Chasmagnathus granulatus (Crustacea, Varunidae) from a mangrove area in southeastern Brazilian coast
    Crescimento relativo e maturidade sexual morfológica de Chasmagnathus granulatus (Crustacea, Varunidae) de uma área de manguezal no sudeste do Brasil
  • Publication Dates

    • Publication in this collection
      04 Dec 2007
    • Date of issue
      Sept 2007

    History

    • Received
      Mar 2006
    • Accepted
      Dec 2006
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