Translocation as a strategy to rehabilitate the queen conch (Strombus gigas) population in the Florida Keys

Queen conch (Strombus gigas) stocks in the Florida Keys once supported commercial and recreational fisheries, but overharvesting has decimated this once abundant snail. Despite a ban on harvesting this species since 1985, the local conch population has not recovered. In addition, previous work has reported that conch located in nearshore Keys waters are incapable of spawning because of poor gonadal condition, although reproduction does occur offshore. Queen conch in other areas undergo ontogenetic migrations from shallow, nearshore sites to offshore habitats, but conch in the Florida Keys are prevented from doing so by Hawk Channel. The present study was initiated to determine the potential of translocating nonspawning nearshore conch to offshore sites in order to augment the spawning stock. We translocated adult conch from two nearshore sites to two offshore sites. Histological examinations at the initiation of this study confirmed that nearshore conch were incapable of reproduction, whereas offshore conch had normal gonads and thus were able to reproduce. The gonads of nearshore females were in worse condition than those of nearshore males. However, the gonadal condition of the translocated nearshore conch improved, and these animals began spawning after three months offshore. This finding suggests that some component of the nearshore environment (e.g., pollutants, temperature extremes, poor food or habitat quality) disrupts reproduction in conch, but that removal of nearshore animals to suitable offshore habitat can restore reproductive viability. These results indicate that translocations are preferable to releasing hatchery-reared juveniles because they are more cost-effective, result in a more rapid increase in reproductive output, and maintain the genetic integrity of the wild stock. Therefore, translocating nearshore conch to offshore spawning aggregations may be the key to expediting the recovery of queen conch stocks in the Florida Keys.

Production of triploid African catfish, Clarias gariepinus (Burchell), using chromosome manipulation techniques

An experiment was conducted to induce triploidy in African catfish, Clarias gariepinus, using heat shock and cold shock techniques. Cold shock at a temperature of 0± 1°C and 5±1°C for a duration of 15, 30, 45 and 60 min and heat shock at a temperature of 40±0.5°C and 41 ±OS C for a duration of 1, 2 and 3 min was given to induce triploidy 5 min after fertilization. Maximum percentage of triploids (91.4%) were obtained in the heat shock at a temperature of 40±0SC for a duration of 1 min whereas cold shock at 0± 1 C for a duration of 60 min yielded 90% of triploids. Chromosome analysis revealed that diploids have 54 chromosomes and triploids have 81 chromosomes. The erythrocyte measurements of the minor axis and major axis were 1.17 times larger in treated fish than in controls. The growth studies showed that the growth rate was not significantly affected in triploids.