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Sexual development and reproductive pattern of the Mutton hamlet, Alphestes afer (Teleostei: Epinephelidae): a dyandric, hermaphroditic reef fish

Abstracts

There is little knowledge on the reproduction of the genus Alphestes. The reproduction of the Mutton hamlet, Alphestes afer, sampled in Pernambuco reefs (Brazil) was studied based on macroscopic analysis during reproductive period and histological analysis of gonad material from March 2008 to October 2009. This study showed that A. afer is a diandric, protogynous hermaphrodite. Sex change followed protogynous mode in two pathways: primary males formed from immature female individuals or secondary males formed from resting, ripe or spent female individuals. The numerical distribution of gonad classes by size indicated that females from 11-18 cm L T were immature while females from 16-25 cm L T and males from 12-22 cm L T were in various stages of gonadal development. Individuals identified as immature bisexual and transitional (presenting both ovarian and sperm tissue) were sized from 16-24 cm L T. Size of first reproduction for females was 18 cm L T and for males was 12 cm L T. Alphestes afer showed multiple spawning, with spawning season period from August to December 2008 and from August to October 2009. The sex-ratio (females: males) in 2008 and 2009 was 0.94:1 during the months of spawning season. Males were smaller than females, reaching maximum size of 22 cm compared to 25 cm observed for females. Males showed a high sperm competition rank (3.8), suggesting intense sperm competition. This latter is a possible indication of a shift in the mating group structure from paired to group spawning. The presence of small males added to high sperm competition index, suggest that this species, while retaining the protogynous pattern, has a reproductive strategy similar to gonochorist epinephelids.

Juvenile sex change; Protogynous hermaphrodite; Reproduction


Há pouco conhecimento sobre a reprodução do gênero Alphestes. A reprodução do sapé Alphestes afer coletado nos recifes de Pernambuco (Brasil) foi estudada baseada em análises macroscópicas durante o período reprodutivo e análises histológicas das gônadas de março de 2008 a outubro de 2009. Esse estudo mostrou que Alphestes afer é uma espécie hermafrodita diândrica. A mudança de sexo seguiu o modo protogínico em dois caminhos: machos primários transformados de fêmeas imaturas ou machos secundários transformados de fêmeas em repouso, maduras ou esgotados. A distribuição numérica por classe de tamanho indicou que fêmeas de 11-18 cm L T foram imaturas; fêmeas de 16-25 cm L T e machos de 12-22 cm L T foram de vários estádios de desenvolvimento gonadal. Indivíduos identificados como imaturos bissexuais e transicionais (ambos apresentando tecido ovariano e espermático) foram de 16-24 cm L T de comprimento. O tamanho de primeira maturação da fêmea foi 18 cm L T e do macho foi 12 cm L T. Alphestes afer mostrou desova múltipla, com período de desova de agosto a dezembro de 2008 e de agosto a outubro de 2009. A proporção sexual (fêmeas: machos) em 2008 e 2009 foi 0,94:1 durante os meses de desova. Machos foram menores que as fêmeas, alcançando o tamanho máximo de 22 cm L T comparados ao tamanho máximo de 25 cm L T das fêmeas observadas. Machos tiveram o rank de competição espermática alto (3,8) sugerindo intensa competição espermática, o que é uma possível indicação da mudança na estrutura do grupo de acasalamento de desova em pares para desova em grupo. A presença de machos pequenos com alto índice de competição espermática sugere que esta espécie, enquanto retém o padrão protogínico, possui uma estratégia reprodutiva similar aos epinefelídeos gonocoristas.


Universidade Federal de Pernambuco, Departamento de Oceanografia, Recife 50740-550, PE, Brazil. simonemarbio@gmail.com

ABSTRACT

There is little knowledge on the reproduction of the genus Alphestes. The reproduction of the Mutton hamlet, Alphestes afer, sampled in Pernambuco reefs (Brazil) was studied based on macroscopic analysis during reproductive period and histological analysis of gonad material from March 2008 to October 2009. This study showed that A. afer is a diandric, protogynous hermaphrodite. Sex change followed protogynous mode in two pathways: primary males formed from immature female individuals or secondary males formed from resting, ripe or spent female individuals. The numerical distribution of gonad classes by size indicated that females from 11-18 cm LT were immature while females from 16-25 cm LT and males from 12-22 cm LT were in various stages of gonadal development. Individuals identified as immature bisexual and transitional (presenting both ovarian and sperm tissue) were sized from 16-24 cm LT. Size of first reproduction for females was 18 cm LT and for males was 12 cm LT. Alphestes afer showed multiple spawning, with spawning season period from August to December 2008 and from August to October 2009. The sex-ratio (females: males) in 2008 and 2009 was 0.94:1 during the months of spawning season. Males were smaller than females, reaching maximum size of 22 cm compared to 25 cm observed for females. Males showed a high sperm competition rank (3.8), suggesting intense sperm competition. This latter is a possible indication of a shift in the mating group structure from paired to group spawning. The presence of small males added to high sperm competition index, suggest that this species, while retaining the protogynous pattern, has a reproductive strategy similar to gonochorist epinephelids.

Key words: Juvenile sex change, Protogynous hermaphrodite, Reproduction.

RESUMO

Há pouco conhecimento sobre a reprodução do gênero Alphestes. A reprodução do sapé Alphestes afer coletado nos recifes de Pernambuco (Brasil) foi estudada baseada em análises macroscópicas durante o período reprodutivo e análises histológicas das gônadas de março de 2008 a outubro de 2009. Esse estudo mostrou que Alphestes afer é uma espécie hermafrodita diândrica. A mudança de sexo seguiu o modo protogínico em dois caminhos: machos primários transformados de fêmeas imaturas ou machos secundários transformados de fêmeas em repouso, maduras ou esgotados. A distribuição numérica por classe de tamanho indicou que fêmeas de 11-18 cm LT foram imaturas; fêmeas de 16-25 cm LT e machos de 12-22 cm LT foram de vários estádios de desenvolvimento gonadal. Indivíduos identificados como imaturos bissexuais e transicionais (ambos apresentando tecido ovariano e espermático) foram de 16-24 cm LT de comprimento. O tamanho de primeira maturação da fêmea foi 18 cm LT e do macho foi 12 cm LT. Alphestes afer mostrou desova múltipla, com período de desova de agosto a dezembro de 2008 e de agosto a outubro de 2009. A proporção sexual (fêmeas: machos) em 2008 e 2009 foi 0,94:1 durante os meses de desova. Machos foram menores que as fêmeas, alcançando o tamanho máximo de 22 cm LT comparados ao tamanho máximo de 25 cm LT das fêmeas observadas. Machos tiveram o rank de competição espermática alto (3,8) sugerindo intensa competição espermática, o que é uma possível indicação da mudança na estrutura do grupo de acasalamento de desova em pares para desova em grupo. A presença de machos pequenos com alto índice de competição espermática sugere que esta espécie, enquanto retém o padrão protogínico, possui uma estratégia reprodutiva similar aos epinefelídeos gonocoristas.

Introduction

The groupers (now Epinephelidae, reclassification of Serranidae by Smith & Craig, 2007) exhibit at least three different sexual patterns: protogynous hermaphroditism, gonochorism and bi-directional sex change (Sadovy de Mitcheson & Liu, 2008). Although it is often assumed that most of groupers present reproductive strategy of protogynous hermaphroditism, a number of reports have yet to be substantiated and confirmation of sexual pattern is still lacking for many species (Sadovy & Colin, 1995, Sadovy de Mitcheson & Liu, 2008). The criteria to diagnose hermaphroditism in fishes in different survey areas have varied widely, but need care to not generate misinterpretations (Sadovy & Shapiro, 1987). The growing number of reports of hermaphroditic species over the last decade, new perspectives on phylogeny in some groups emerging from molecular studies and clearer criteria for distinguishing functional from non-functional, invite a re-examination of hermaphroditic sexual patterns in teleosts (Sadovy de Mitcheson & Liu, 2008).

Hermaphroditic fishes could be defined in two categories: i) simultaneous, when the male and female sex cells ripen at the same time; and ii) sequential, which could be protogynous hermaphrodite that function first as females and them transform to males, or protandrous hermaphrodite that transform males into females (Smith, 1959; Yamamoto, 1969; Chan & Yeung, 1983). The protogynous mode of reproduction is complicated in certain species by the occurrence of some large females that do not change sex and some small males that are mature at the same size as the smallest females (Heemstra & Randall, 1993, Liu & Sadovy, 2004).

Many protogynous groupers could exhibit either the monandric or diandric form of protogyny. The first occurs when males develop via only adult sex change (secondary male), while the diandric form is when males develop directly from juvenile sex change (primary male) (Sadovy de Mitcheson & Liu, 2008).

The importance of determining the mode of reproduction of a species is enhanced by the fact that fishery management is considerably complicated by sequential hermaphroditism (Shapiro, 1987). Since males in protogynous species tend to be larger, older and less numerous than females, fishing may remove more males than females (Ferreira, 1993). There is little knowledge of sexual behavior of small groupers hermaphrodites exploited in fisheries.

The Mutton hamlet, Alphestes afer (Bloch, 1793), is a small grouper (Epinephelidae), shallow-water, cryptically colored fish that is easily overlooked in their typical seagrass habitat (Heemstra & Randall, 1993). They rarely reach 30 cm LT in size and are common in waters between 2 and 50 meters deep (Craig et al., 2006). This small grouper has been recorded from Bermuda, south Florida to southern Brazil (Carvalho-Filho, 1999) and in the Gulf of Guinea, western Africa (Craig et al., 2006).

Apart from the work by Smith (1959) which considered A. afer as protogynous hermaphrodite, based in histological analysis of only 8 individuals, there is little knowledge on the reproduction of the genus Alphestes.

The purpose of this work was to assess the reproductive biology of A. afer, including description of size distribution of individuals, seasonality of reproduction, sex ratio, and occurrence of sex-change in Brazilian reefs.

Material and methods

Sampling

The coast of Pernambuco State, in the Brazilian Northeast, is 187 km long and characterized by the presence of mangroves, coral reefs and seagrass beds. This coast represents a highly productive system that supports intense artisanal fisheries (Ferreira & Maida, 2006). In Pernambuco State, the Mutton hamlet, Alphestes afer, is caught frequently by traps and hook and line in costal reefs and over the continental shelf.

Alphestes afer was sampled monthly in four localities on the coast of Pernambuco State: 1) Itamaracá (7º44'S, 34º49'W), 2) Recife (8º04'S, 34º52'W), 3) Tamandaré (8º45'S, 35º05'W) and 4) São José da Coroa Grande (8º53'S, 35º08'W) between March 2008 and October 2009. Most samples were obtained during landings from trap fisheries operating over the continental shelf in depths between 30 to 50 m. A smaller percentage of the sample (13%) was obtained from landings from hook and line fisheries and spear fisheries operating in shallow reefs between depths of 3 to 5 m.

Each fish was measured and weighted. Total length (LT) was measured in centimeters (cm) and total weight (Wt) in grams (g). Gonads for each individual were removed, weighed (in grams), and fixed in FAAC (formaldehyde 4%, acetic acid 5%, calcium chloride 1.3%) (Ferreira, 1993). Alternatively, inspection of fresh gonads was conducted macroscopically in order to determine the sex. In this latter case, individuals were classified as either ripe female or male.

After fixation in FAAC, each gonad sample was rinsed with fresh water and then preserved with alcohol 70º. Gonadal tissue was cut from the middle part of the gonadal lobe. After the dehydration process, the gonads were embedded in paraffin, sectioned transversally at 4-5 µm and stained with haematoxylin-eosin (Beçak & Paulete, 1976).

Maturity stages were determined from histological observations to assess the development of the ovary and testis. Oogenesis and spermatogenesis stages classification followed Nagahama (1983) and Ferreira (1993, 1995); and developmental stages classification followed Chan & Sadovy (2002) and Liu & Sadovy (2004).

The spawning season was determined through histological analyses. Gonadosomatic index (IG) was calculated as IG = WGo /Wt x 100, where WGo = gonadal weight, and Wt = total weight.

The amount of fat deposited in the mesenteries was estimated following a relative scale from 1 to 3, which indicated the proportion of fat covering the viscera (1: no visible fat; 2: increasing amounts of fat, and 3: fat completely covering the viscera). This scale was chosen after an observation of the variation in the amounts of mesenteric fat during reproductive cycle. The estimation was always made by the same observer. This scale was transformed in percentage to compare with IG.

The size (LT cm) of first spawning was determined when 50% (LT50) of females and males have begun their reproductive cycle. The individuals in each size class from 12 to 26 cm LT were either in ripening or ripe gonad stage, thus were grouped per sex. Size distribution of females and males was compared between gonadal stages among reproductive period. Mature females and males were included to calculate the sex-ratio only when reproductively active.

The IG (gonadosomatic index) of reproductive active males was used as a proxy of sperm competition intensity following a review by Erisman et al. (2009). Mean IG of breeding males was used to score the intensity of sperm competition, separated in four groups of increasing levels of sperm competition ranks (SR) (Table 1).

A nonparametric Kruskal-Wallis ANOVA (P<0.05) was used to examine differences in some analysis among gonadal stages of females and males (IG, mesenteric fat, sizes distribution of gonadal stages). Spearman Rank correlation was used to analyze the relationship between IG and mesenteric fat for mature females and males, and between IG and size. A Chi-Square test (Χ2) was used to compare sex ratio (mature females:mature males) between months of reproductive period.

Results

The total number of individuals collected from landings was 249, ranging from 12.2 to 25.8 cm LT. The number of individuals analyzed per month varied between 9 and 22, depending on availability and period of the year. An additional sample of eight small juveniles (11.6 to 15.4 cm LT) was collected in shallow reefs (3 m) of Tamandaré using fence nets between March 2009 and February 2010.

Sex determination was attempted from macroscopic observations only during the reproductive period. All gonads of females and males had an ovarian structure with a lumen and numerous lamellae protruding into the lumen from the dorsal and lateral walls. Six gonadal stages were histological recognized in ovaries and four in the testes. Sex change was determined in juvenile and adult females presenting four stages, so the species was considered a protogynous hermaphrodite. Each gonad was assigned in one of the following phases: immature female; ovarian phase of resting, ripening, ripe and spent female; immature bisexual phase of females; transitional phase of resting, ripe and spent female; testicular phase of ripening, ripe, spent and resting male. Table 2 lists these phases and their corresponding macroscopic and histological characteristics.

During histological analysis, sex changing gonads were identified when sperm crypts appeared. These sperm crypts were confirmed comparing with the spermatogenesis stages of male A. afer (Fig. 3). Individuals with gonads containing previtellogenic oocytes and spermatogenic tissue without signs of previous female function were classified as immature bisexual (Table 2). Mature individuals showing both proliferation of testicular tissue and degeneration of ovarian tissue were considered transitional. Sex changing gonads presented spermatic crypts or groups with spermatides or spermatozoa, located near the edge of gonad wall and spread among ovarian tissue. Also oocytes (O1, O2 or O3) in these gonads showed signs of degeneration (Table 3). Muscle bundles (MB) were evident (Table 3; Fig. 4b). The presence of MB, surrounding the blood vessels, was most prominent after spawning in spent females and at the beginning of resting period of females. Sperm sinuses were observed only in transitional individuals on resting stage, and in those individuals larger proliferation of sperm crypts was also observed. Transitional individuals in other stages presented only few sparse sperm crypts (Tables 3, 4).




Only ten males (21% of all examined individuals) presented residuals previtellogenic oocytes intermingled with testicular tissue (Fig. 2c). These residual oocytes were probably remains from the juvenile bisexual phase with no functional significance.

Size distribution of males and females and size of first maturity

Immature females measured from 11 to 18 cm LT while mature females measured from 16 to 25 cm LT. Immature bisexual present showed a size range of 16 to 17 cm LT. Males, including the ones which had residual ovarian tissue, ranged from 12 to 22 cm LT (Table 4).

A single small specimen of immature bisexual female Fbi(Im) was identified during May 2008 (Fig. 4a). This specimen did not exhibit any sign of previous female function, such as muscle bundles or later stage oocytes (O2, O3) (Tables 3, 4). Smaller males (12 to17cm LT) did not show evidence of first reproduction as previous females function. Among twelve resting transitional female Tr (Re), only two individuals (18 to19 cm LT; June 2008 and June 2009) did not show presence of muscle bundle as evidence of previous female function (Table 4). Five individuals between 18 and 24 cm LT of ripe and spent transitional females Tr(Rp) and Tr(Sp) showed ovarian tissue with evidences of previous female function (Table 3, Fig. 5). These transitionals individuals represented 2.7% of all females observed.


The size of first reproduction (considered as the size in which 50% of individuals are reproductively active) was 18 cm LT for females and 12 cm LT for males, showing that reproductive males were smaller than females. The modal size of females was 22 cm LT while for males was 20 cm LT (Fig. 6). Average size of males and females was significantly different (t-test, df = 62, P < 0.05).


Seasonality and periodicity of spawning

Spawning period was evident from August to December 2008 and from August to October 2009 gonadal stages and IG. The reproductive peak in August 2009 was more intense than that in August 2008 (Kruskal-Wallis, df =1; P<0.05). There were significant differences between IG of months of resting period and months of reproductive period of 2008 and 2009 (Kruskal-Wallis, df = 19; P<0.05). There were no significant differences between IG values of mature females and males (Kruskal-Wallis, df =1; P = 0.0554). Significant differences were identified in IG values between months of reproductive peak of 2008 and 2009 (Kruskal-Wallis, df =5; P < 0.05) (Fig. 7).


The amount of fat deposited in the mesenteries of males and females had significant differences between months (Kruskal-Wallis; df =19; P < 0.05). From January to June 2009, there was an increase in the amount of fat before the reproductive peak. The amount of mesenteric fat observed in September 2008 dropped to zero and remained so until December 2008, after the end of the reproductive period. The decrease of fat was also observed in September 2009 (Fig. 7). The variation in the amount of mesenteric fat was antiphasic to the variation observed in the IG for males and females (Fig. 7), and the amount of fat was inversely correlated with gonad weight for mature females and males (Spearman rank RS= -0.254; P < 0.05).

Ripe females were found from August to December in 2008 and from July to October in 2009 (Fig. 8). Ovaries in this stage showed oocytes in maturation, mature and hydrated; previtellogenic oocytes in ripe female were also present (Fig. 1b).


Ripe males were found from July 2008 to February 2009 and from June to October 2009 (Fig. 8). Intense spermiogenesis and the presence of spermatozoa filled sinuses indicated that males could spawn several times. Since the end of reproductive period (December 2008) some mature males showed the beginning of spermatogenesis with emergence of spermatogonias and primary spermatocytes. During resting period of females, males were not found (March-June 2008; March-May 2009). Resting males were found only during January, February and June 2009 (Fig. 8). Immature males were not observed during the study.

The IG was positively related to size for mature males (Spearman rank RS = 0.51; P < 0.05) and was inversely and weakly related to size for mature females (Spearman rank RS = -0.14; P = 0.43), during reproductive period from August to October in both years. Some males were mature at 12 cm LT but IG started to increase after 15 cm LT (Fig. 9).


There were significant differences among size classes in gonadal stages of females, males (immature, ripening, ripe, spent, and resting), bisexuals females (immature) and transitional females (resting, ripe and spent) (Kruskal-Wallis, P<0.05; df = 9).

Sex-ratio (females:males) was 0.94:1 during the spawning season period (August to October) and frequency distribution of males and females did not vary between 2008 and 2009 (Χ2; P = 0.589). Sex ratio per size classes showed the trend observed in size frequency distribuition (Fig. 6), with a clear tendency for males in smaller size classes and females in larger classes. Frequency of mature females and mature males also did not vary between classes where overlap occurred (18-23 cm LT) (Χ2; P = 0.06) (Table 5).

The IG mean of breeding males was 3.8 and the Alphestes afer sperm competition rank was (3) indicating that it is an aggregating species that spawn in pair or groups. The category of sexual pattern was protogynous or unconfirmed gonochorism (Table 1).

Discussion

In low latitudes, grouper species spawn between early spring and summer (Shapiro, 1987; Ferreira, 1993; Heemstra & Randall, 1993). Gonadal stages and IG of Alphestes afer in Brazilian reefs indicated that spawning activity occurred earlier, between late winter and spring. This periodicity was confirmed by histological evidence as well as IG analysis. Multiple-spawning during this period was indicated by asynchronous oocyte development in females and continuous spermiogenesis in males, a pattern often observed in other epinephelids (Ferreira, 1995).

During the reproductive period in Brazilian reefs, running ripe A. afer females and males were observed, indicating that spawning occurred within the fishing area. Males were absent in samples collected from March to June 2008 and from March to May 2009, a period during which they were most likely in the resting phase as observed for females and males collected during June 2009. The absence of males may be the result of a spatial segregation of sexes during non active reproductive periods. Robertson & Choat (1974) noted that temporary territorial males of Thalassoma lunare (protogynous hermaphrodite) appeared only during the spawning season. Some species of groupers have also shown co-occurrence of males and females only during the reproductive period indicating spatial segregation with females in shallow water and males in deeper areas during the resting period (Coleman et al. 1996; Sadovy, 1994; Shapiro, 1987). However, the fishing area covered in this study was broad and reached the deeper limits of the species known depth distribution, if this movement occurs, it should be to shallower areas as traps start to be deployed at 30 m depth. It was observed that A. afer disappeared altogether from shallow reefs (3 m deep) located in Tamandaré (Pernambuco Coast, Brazil), during the spawning season but individuals were observed during remaining periods of the year. As their sex was not determined it is not possible to conclude if those individuals belonged to one or both sexes.

Pathways of protogynous hermaphroditism

A single previous, available study for A. afer is that of Smith (1959) who classified it as a protogynous hermaphrodite and reported females ranging from 13.2 to 23.5 cm LT and a single male of 21.3 cm LT. Our study from Brazilian reefs showed mature males from 12 to 22 cm LT and mature females from 16 to 25 cm LT, indicating that males are in average smaller than females. Also, first maturity size of males at 12 cm LT was inferior to the size of first maturity of females at 18 cm LT. Males smaller than 17 cm LT were considered primary males because they did not show any signs of previous reproduction as females. The suggested reproductive pathways for A. afer are shown in Fig. 10. Reports of species, in which males are consistently smaller than females, have been related to the development of primary males that do not pass through a stage of functional, adult female, and develop through juvenile phase (Munday et al., 2006). This process, called juvenile sex inversion, has been previously reported for sparids (Francis & Pankhurst, 1988) as well as for serranids (Ferreira, 1995; Bhandari et al., 2004; Liu & Sadovy, 2004). These males function only as one sex during their lifetime and are not functional sex-changers according to Sadovy & Shapiro (1987). They also exhibit the same testicular morphology as large males of the genera Cephalopholis and Plectropomus (Ferreira, 1993; Chan & Sadovy, 2002; Liu & Sadovy, 2004). One individual of A. afer presented degenerating tissue of primary oocytes as well as proliferation of spermatogenic tissue, and was considered an immature bisexual female (Fig. 10). This term has been used by several authors (Smith, 1965; Chan & Sadovy, 2002; Liu & Sadovy, 2004) when gonads present a combination of immature testicular tissue and immature ovarian tissue (Sadovy de Michetson & Liu, 2008).


Alphestes afer in Brazilian reefs showed functional sex change, that is, from functional female to male. Individuals considered to be secondary males presented developing sperm crypts in ovarian tissue classified as resting, ripe and spent, this last two showing evidences of previous vitellogenic activity. The transitional females showed degeneration of vitellogenic stage oocytes, the proliferation of testicular tissue and muscle bundles (Table 3). The presence of muscle bundle was also observed, what could be an additional evidence as those structures have been considered a reliable indicator for determining previous female function in Cephalopholis boenak (Liu & Sadovy, 2004). Males were always smaller than females, but some of the transitionals individuals presented sizes close to the maximum size observed for males. It was noted however, that those were apparently in early stages of transition, with few sparse sperm crypts (Nakamura et al., 2007). A flexible mechanism that incorporates social signs about the size and abundance of conspecifics, as well as state-dependent information about the individual to achieve timing of sex change, has been proposed for hermaphroditic species as an adaptive advantage (Sattar et al., 2008). This mechanism could also explain the wide range at which A. afer individuals may change sex from female to male.

Population structure and mechanisms of sex change

Size-advantage model proposes that selection for sex change exists when reproductive success increases with size or age more rapidly for one sex than for the other (Avise & Mank, 2009; Erisman et al., 2009). Also, sex change is favored when an individual reproduces most efficiently as one sex when young or small, and most efficiently as the opposite sex when it gets older or larger (Shapiro, 1988; Munday et al., 2006). The intensity of sexual selection for protogyny varies inversely with local population size and the ability of small males to access females in matings (Warner, 1982).

In mating with random pairing, it should be advantageous to be a male when small (thus mating with larger individuals) and female when large (high capacity for egg production) (Warner, 1984). Moreover, small males increase their reproductive success by accessing females via group spawning (Erisman et al., 2009). The mating pattern for A. afer is not known, but for the congener A. immaculatus, pair spawning has been reported by Erisman et al. (2009).

Erisman et al. (2009) proposed the sperm rank competition index (SR) to evaluate intensity of sperm competition in groupers. They also suggested that higher indexes were observed for species with higher sperm competition, where gonochorism was progressively favoured against protogyny. For A. afer, SR, determined by the relative testes weights, was 3.8; this is an index considered high and related to species that were protogynous or uncorfirmed gonochorist (Table 1). Indexes higher than 4.0 have been found in gonochoristic species. According to this model, species with intense sperm competition have large testes and losses of sex change (shifts in sexual pattern from protogyny to gonochorism) are related to shift in the mating group structure from paired to group spawning (Erisman et al., 2009).

For A. afer, the development of both primary and secondary males was found. However, males were consistently smaller than females and matured at smaller sizes. These characteristics, added to the high sperm competition index, suggest that this species, while retaining the option of a protogynous pattern, has a reproductive strategy similar to gonochorist epinephelids.

Generally, in protogynous hermaphrodites's populations bigger males represent older individuals while smaller females represent the youngest (Choat & Robertson, 2002; Shapiro, 1987). Sex related differences in growth rates have been reported for several species, and so it is possible that growth rates are reduced after sex change from female to male in A. afer. In this case, smaller males could represent older individuals for their size classes than females of the same size. Effects of fishing, truncating the size distribution, could also operate to reducing the maximum size of individuals in the population and also the size of sex transition, and thus increasing the size overlap of sexes (Sattar et al., 2008).

Variants of developmental pathways within the same species are common among protogynous hermaphrodites (Muñoz & Warner, 2004; Rogers, 2003). This work showed that A. afer is a diandric protogynous hermaphrodite with two pathways, according to which male could have juvenile sex inversion (primary male) or sex inversion by functional female to secondary male. Further studies of age structure as well as social and mating systems of A. afer could provide more insights on the strategies of reproduction and consequences of fishing on populations.

Acknowledgments

We wish to thank J. L. L. Filho for support of Laboratory of Imunopatology Keizo Asami and C. Lima for their assistance in the histological preparations (Universidade Federal de Pernambuco - UFPE). We are grateful to fishers of Itamaracá, Recife, Tamandaré and São José da Coroa Grande for their help giving access to the landings and in collecting the samples. Special thanks to Instituto Chico Mendes - Centro de Pesquisa e Gestão de Recursos Pesqueiros do Litoral Nordeste (ICMBIO - CEPENE) for Laboratorial support. We also thank S. N. Leitão (UFPE) for use of laboratory facilities. Thanks to I. Estevão for help with samples. We thank Y. Sadovy de Mitcheson for her valuable comments and suggestions. This work was supported by grants from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq - 140166/2007-6).

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Submitted October 8, 2010

Accepted June 6, 2011

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  • Sexual development and reproductive pattern of the Mutton hamlet, Alphestes afer (Teleostei: Epinephelidae): a dyandric, hermaphroditic reef fish

    Simone Marques; Beatrice Padovani Ferreira


  • Publication Dates

    • Publication in this collection
      02 Sept 2011
    • Date of issue
      2011

    History

    • Received
      08 Oct 2010
    • Accepted
      06 June 2011
    Sociedade Brasileira de Ictiologia Neotropical Ichthyology, Núcleo de Pesquisas em Limnologia, Ictiologia e Aquicultura, Universidade Estadual de Maringá., Av. Colombo, 5790, 87020-900, Phone number: +55 44-3011-4632 - Maringá - PR - Brazil
    E-mail: neoichth@nupelia.uem.br