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The Reproduction, Growth, Feeding and Impacts of Exploitation of the Venus Tuskfish (Choerodon venustus) With some implications for its management.Platten, John Robert Unknown Date (has links)
This study examines the biology of the venus tuskfish Choerodon venustus from the southern Great Barrier Reef to enable better-informed management decisions. Venus tuskfish are taken almost exclusively by line fishing. The size of the catch is uncertain, but the annual Queensland commercial catch is probably about 30 t and the recreational catch much greater than this (possibly ca. 300 t). The species is not the primary target of fishers and can be regarded as by-catch taken while targeting other species. However C. venustus is the second or third most commonly retained species in the study area. Venus tuskfish are taken in habitats associated with coral and other reefs across a depth range from 5 m to 90 m. The species is a benthic predator, taking molluscs, echinoderms, annelids, arthropods, and fish (in decreasing order of importance). Feeding intensity was greatest in summer. There was evidence of complex feeding behaviours and a dominance hierarchy amongst feeding fish that may result in large males being more susceptible to fishing. The species is slow growing and long lived. Up to 38 bands were observed on the opercular bones of C. venustus. Back-calculation methods yielded von Bertalanffy growth parameters of L¥ =669 mm, K = 0.09 and t0 = -3.89. Male fish appear to grow faster than females. This may be related either to faster growing fish becoming males, growth acceleration following sex reversal, or both. Selective removal of faster growing males in heavily fished locations may result in a greater proportion of slower growing females in the remaining population. iv Choerodon venustus is a protogynous hermaphrodite; the proportion of males increases as the fish increase in size, transitional fish exist and remnant female tissue was evident in testes. The species is a serial spawner with an extended breeding season perhaps peaking in autumn and around the new and full moon. Females mature between 200 and 250 mm forklength (LCF). Venus tuskfish display sexually dimorphic colouration and appear to have a socio-sexual group structure. Fish occur in extended groups with several large males associated with a larger number of smaller females. Multiple sex-reversals may occur in the groups perhaps in response to the loss of the larger males. Large females produce over 100,000 eggs in the ovaries. The number of eggs released at each spawning is unknown. There is a direct cubic relationship between length and the weight of female gonads. Large females over 500 mm LCF are capable of producing over 20 times the number of eggs of small mature females (around 250 mm LCF). The locations sampled showed marked differences in fishing effort. The Capricorn Bunker Group was subject to much higher fishing effort than the Swains Reefs. Estimates of fishing mortality reflected this trend. Line fishing selects large male fish. The heavily fished Masthead Island had smaller males, females and transitional fish. Fish below 300 mm LCF were not captured efficiently. Venus tuskfish may be capable of modifying their life cycle in response to increased fishing mortality. Sex reversal may be related to the absence of large males in social groups. Hence sex ratio remains constant between fished and unfished locations. In heavily fished populations, females are smaller and consequently produce fewer eggs. Modeling suggests unfished areas may have a potential fecundity over six times that of those heavily exploited. Choerodon venustus are severely impacted by barotrauma during capture, and few captured and released fish are likely to survive. There are special challenges in managing venus tuskfish including: · Their status as a largely bycatch species; · The poor survival of released fish due to barotrauma; · A lack of good measures of catch and effort caused by inconsistent naming of the species and inherent errors in current data collection methods; · Their extended spawning period and likely widespread spawning sites and · The need to support group fecundity by protecting larger fish. A combination of a series of fish reserves, raising the minimum legal size to 36 cm TL, effective catch limits and an effective education program are likely to support the sustainability of the fishery.
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The biology of four tuskfish species (Choerodon: Labridae) in Western Australiad.fairclough@murdoch.edu.au, David Fairclough January 2005 (has links)
The biology of four species of Choerodon (Labridae), the blue tuskfish C. cyanodus, the bluespotted tuskfish C. cauteroma, the baldchin groper C. rubescens and the blackspot tuskfish C. schoenleinii was studied in Shark Bay in Western Australia. These species are fished commercially and/or recreationally in this large subtropical marine embayment, which is a world heritage area. The biology of C. rubescens was also studied in the Abrolhos Islands, which are located ~ 300 km to the south of Shark Bay, where this labrid is an important commercial and recreational fish species. The broad aims of this project were to determine the following for the above four Choerodon species in Shark Bay. (1) Whether they are protogynous hermaphrodites, as is the case with many labrids. (2) The biological variables required for developing management plans for these species, such as the timing of spawning, the lengths and ages at both maturity and sex change, size and age compositions and growth parameters, and (3) the habitat types occupied during their life cycles and also of the purple tuskfish Choerodon cephalotes. Finally, comparisons are made between the age and size compositions, growth and reproductive biology of C. rubescens in Shark Bay and the Abrolhos Islands. Where relevant, the underlying hypotheses for the individual studies conducted during this PhD are included in the following chapters.
A macroscopic and histological examination of the gonads of the full size range of C. cyanodus, C. cauteroma, C. rubescens and C. schoenleinii, together with an analysis of the length and age compositions of female, transitional (individuals changing sex) and male individuals, demonstrated that each of these species is a protogynous hermaphrodite, i.e. individuals change sex from female to male during their life cycle. The gonads of all small (< ca 100 mm) and young (< ca 1 year old) individuals of each species comprised solely ovarian tissue and thus the individuals of each species began life as a female. All individuals subsequently become sexually mature as females and then later in life some will change to males. Since this was found to be the only method of sex change in these species, they are termed monandric. Individuals that were changing sex contained undelimited type 2 gonads sensu Sadovy and Shapiro (1987). These gonads contained both ovarian and testicular tissue that was intermixed and not separated by connective tissue. The males of each species possessed secondary testes, which retained structures of the ovary they had replaced, such as a membrane-lined ovarian lumen, lamellae and ovary wall. Furthermore, histological sections indicated that sperm were transported towards the outer walls of the testes, where the multiple sperm sinuses present in that region were presumably responsible for transporting sperm to the cloaca, rather than to a singular sperm duct as is the case with gonochoristic species.
The typically large size and different colour of the males of C. rubescens, C. schoenleinii and C. cauteroma and the bias in the sex ratios of their adults towards females suggests that the males of each of these species are either haremic, i.e. permanently territorial, or form leks, i.e. are temporarily territorial during their spawning seasons. In these three species, the presence of ripe testes that are far smaller than ripe ovaries and the release by females of eggs in batches are consistent with a single male spawning with an individual female, as commonly occurs in haremic/lekking species. In contrast to the above species, C. cyanodus was not sexually dichromatic, the sex ratio was not biased towards either sex and the weight of ripe testes remained relatively constant as body weight increased. The latter implies that the relative investment of energy by males into testicular development during the spawning season declines with increasing fish size. Thus, the males of C. cyanodus may be opportunistic spawners when small, possibly spawning in groups, and may tend towards a haremic or lek mode of life when larger.
The respective lengths and ages at which 50% of the females of C. cyanodus C. cauteroma and C. schoenleinii attained sexual maturity (L50m, A50m) in Shark Bay were ca 129, 196 and 253 mm and 2.3, 2.0 and 3.5 years of age. The corresponding L50m and A50m for C. rubescens in Shark Bay and the Abrolhos Islands were ca 274 and 279 mm, respectively, and 2.7 and 4.1 years of age, respectively. The respective lengths and ages at which 50% of the females of C. cyanodus, C. cauteroma and C. schoenleinii changed to males (L50c, A50c) in Shark Bay were 221, 310 and 556 mm and 4.1, 6.4 and 10.4 years of age. The length at which C. rubescens changed sex (L50c) was significantly greater in Shark Bay (545 mm) than in the Abrolhos Islands (479 mm), whereas the reverse pertained with respect to the age at sex change (A50c), i.e. 10.5 vs 11.9 years of age. Since some females were found in the oldest age classes of each species in Shark Bay and in the population of C. rubescens in the Abrolhos Islands, some of the females of each species do not apparently change sex.
The trends exhibited by the gonadosomatic indices of females and males and the stages of ovarian development in sequential months demonstrated that the spawning periods of each species varied. Thus, C. rubescens (in both Shark Bay and the Abrolhos Islands) and C. cauteroma spawn predominantly in spring, whereas spawning occurs in late spring/early summer in C. schoenleinii and in summer in C. cyanodus. As C. schoenleinii, C. cyanodus and C. cauteroma occur predominantly within the inner gulfs of Shark Bay, the offset in the timing of their spawning periods would be likely to reduce any potential for competition between the larvae of those three species for resources.
The trends exhibited by the mean monthly marginal increments in sectioned otoliths with differing numbers of opaque zones demonstrated that, in each species, those opaque zones were laid down annually. Thus, the numbers of opaque zones in the sectioned otoliths of individuals of each species could be used, in conjunction with the birth date and time of year when those zones are delineated, to determine their approximate ages at capture. The maximum ages recorded for the four Choerodon species in Shark Bay ranged only from 12 to 16 years. However, in that environment, the maximum lengths of C. rubescens (649 mm) and C. schoenleinii (805 mm) were far greater than those of C. cauteroma (424 mm) and C. cyanodus (382 mm). In contrast to the situation with C. rubescens in Shark Bay, this species reached a substantially older maximum age (22 years), but slightly shorter length (629 mm), and grew at a slower rate in the Abrolhos Islands, possibly reflecting the influence of greater productivity in Shark Bay and/or greater densities of this species in the Abrolhos Islands.
Although a few C. rubescens and C. schoenleinii reach large sizes in Shark Bay, most of the individuals of these species were less than 400 mm, their minimum legal length (MLL) for capture. This raises the possibility that these two sought after species, i.e. the seventh and ninth most abundant species in the recreational fishery in Shark Bay, are subjected to substantial fishing pressure. Sampling for C. cyanodus was considered representative of the sites that this species occupies in Shark Bay and the sampling methods would have been likely to have captured the full size range of this tuskfish. Thus, the failure to catch any C. cyanodus greater than 400 mm indicates that, in Shark Bay, this species does not grow to the far greater lengths of about 600 mm reported for this species as a maximum by Allen (1999). Furthermore, the 400 mm MLL for this species in Western Australia precludes the retention by fishers of this species in this environment. Choerodon cauteroma was caught at lengths up to 424 mm, which is greater than the maximum of 360 mm reported for this species (Allen, 1999). Although there is no MLL for C. cauteroma, recreational fishers are restricted to a bag limit of four fish per person per day, as is the case with all other tuskfish species.
Since fishers target large fish preferentially and the largest size classes of each of the species of tuskfish are dominated by males, heavy fishing pressure has the potential to remove a large proportion of the males of the Choerodon species that are fished in Shark Bay, i.e. C. rubescens, C. schoenleinii and C. cauteroma, and also of C. rubescens in the Abrolhos Islands. Since the ratio of females to males in catches of C. rubescens taken by the commercial fishery in the Abrolhos Islands are ca 1:1 and yet the typical adult sex ratio is heavily biased towards females (ca 14:1), that fishery is removing a substantial proportion of the males from the population. Protogynous hermaphroditic species are apparently able to respond to such pressure on the males by initiating a change in sex by the larger females. However, there is evidence from studies of other protogynous species that heavy size-selective fishing can lead to a reduction in the size and age at which a species changes sex and ultimately to a collapse in the stock.
The results of visual surveys, when taken in conjunction with the locations of the catches of each of the five Choerodon species, demonstrated that C. rubescens lives on reefs in oceanic waters along the western boundary of Shark Bay, whereas C. schoenleinii, C. cyanodus, C. cauteroma and C. cephalotes are found predominantly in the two inner gulfs of this large embayment. Choerodon cephalotes lives almost exclusively in seagrass beds, while C. schoenleinii and C. cyanodus occupy predominantly inner gulf reefs and rocky shorelines and C. cauteroma occurs in all of those three habitats. Choerodon cauteroma was the only species that underwent an obvious size-related shift during its life cycle, moving from seagrass to hard substrates, such as inner gulf reefs and rocky shorelines, as it reached adulthood.
The biological and habitat data produced during this thesis will provide fisheries and environmental managers with the types of information that will enable them to develop management plans for conserving tuskfish species and their habitats in Shark Bay. The biological data for C. rubescens in the Abrolhos Islands will be able likewise to be used to develop plans for conserving the stock of this species in waters in which it is heavily fished.
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