Self-recruitment in a coral reef fish population in a marine reserve

Herrera Sarrias, Marcela

12 1900

Marine protected areas (MPAs) have proliferated in the past decades to protect biodiversity and sustain fisheries. However, most of the MPA networks have been designed without taking into account a critical factor: the larval dispersal patterns of populations within and outside the reserves. The scale and predictability of larval dispersal, however, remain unknown due to the difficulty of measuring dispersal when larvae are minute (~ cm) compared to the potential scale of dispersal (~ km). Nevertheless, genetic approaches can now be used to make estimates of larval dispersal. The following thesis describes self-recruitment and connectivity patterns of a coral reef fish species (Centropyge bicolor) in Kimbe Bay, Papua New Guinea. To do this, microsatellite markers were developed to evaluate fine-scale genetics and recruit assignment via genetic parentage analysis. In this method, offspring are assigned to potential parents, so that larval dispersal distances can then be inferred for each individual larvae. From a total of 255 adults and 426 juveniles collected only 2 parentoffspring pairs were assigned, representing less than 1% self-recruitment. Previous data from the same study system showed that both Chaetodon vagagundus and Amphiprion percula have consistent high self-recuitment rates (~ 60%), despite having contrasting life history traits. Since C. bicolor and C. vagabundus have similar characteristics (e.g. reproductive mode, pelagic larval duration), comparable results were expected. On the contrary, the results of this study showed that dispersal patterns cannot be generalized across species. Hence the importance of studying different species and seascapes to better understand the patterns of larval dispersal. This, in turn, will be essential to improve the design and implementation of MPAs as conservation and management tools.

Self-recruitment

Parentage analysis

Microsatellites

Connectivity

Kimbe Bay

Larval Dispersal

Self-Recruitment in the Bumphead Parrotfish Under Different Levels of Fishing Pressure in the Solomon Islands

Lozano-Cortés, Diego

12 1900

Knowledge in the spatial patterns of fish larval dispersal is crucial for the establishment of a sustainable management of fisheries and species conservation. Direct quantification of larval dispersal is a challenging task due to the difficulty associated with larval tracking in the vast ocean. However, genetic approaches can be used to estimate it. Here, I employed genetic markers (microsatellites) as a proxy to determine dispersal patterns and self-recruitment levels using parentage analysis in the bumphead parrotfish (Bolbometapon muricatum) in the Solomon Islands. Tissue samples of 3924 fish (1692 juveniles, 1121 males and 1111 females) were collected from a spear-fishery at the Kia District in Santa Isabel Island. The samples come from three distinct zones with different fishing pressure histories (lightly fished, recently fished, and heavily fished). The mean dispersal distance estimated for the bumphead parrotfish was 36.5 Km (range 4 – 78 Km) and the genetic diversity for the population studied was low in comparison with other reef fishes. The parentage analysis identified 68 parent–offspring relationships, which represents a self-recruitment level of almost 50 %. Most of the recruits were produced in the zone that recently started to be fished and most of these recruits dispersed to the heavily fished zone. Comparisons of genetic diversity and relatedness among adults and juveniles suggested the potential occurrence of sweepstakes reproductive success. These results suggest that management measures must be taken straightaway to assure the sustainability of the spear-fishery. These measures may imply the ban on juveniles fishing in the heavily fished zone and the larger adults in the recently fished zone. Overall, the population dynamics of the studied system seem to be strongly shaped by self-recruitment and sweepstakes reproduction events.

Larval Disperal

Self-recruitment

fishery

Parentage analysis

relatedness

bumphead parrotfish

Connectivity of the Longfin Grouper (Epinephelus Quoyanus) in a marine reserve in the Great Keppel Island Group

Al-Salamah, Manalle

12 1900

With a dramatic decrease of biodiversity as a result of the increase in exploitation of marine ecosystems, the establishment of marine protected areas (MPAs) serves as an important means of protecting those resources. Although there is support for the effectiveness of these MPAs and MPA networks, there is room for improvement in terms of MPA management and design. For example, a better understanding of the dispersal dynamics of targeted species across these MPAs will serve as a more accurate means of reserve as well as fisheries management. While there have been many methods used to determine the larval dispersal of a certain species, parentage analysis is becoming the most robust. In this thesis, I attempt to determine the patterns of self-recruitment and larval dispersal of the Longfin Grouper (Epinephelus quoyanus) in one focal marine reserve within the Great Keppel Island group through the method of parentage. For this, I developed 14 microsatellite markers and with those, genotyped 610 adults as well as 478 juveniles from the study site. These genotypes allowed me to assign offspring to their potential parents, which then allowed me to measure the self-recruitment, local retention as well as larval dispersal percentages of this species from and within the reserve. My results indicate that there is 32% local retention to the reserve while 68% of the assigned juveniles were dispersed to other areas (4% of which dispersed to another reserve). Previous studies conducted in the same area showed higher reserve self-recruitment rates for both Plectropomus maculatus (~30%) and Lutjanus carponotatus (64%) despite their similar life history traits. The results from this study add to the growing evidence that dispersal patterns cannot be generalized across marine systems or even between species within a single system.

Epinephelus Quoyanus

Larval Dispersal

Parentage Analysis

Keppel Island

Self-recruitment

What Happened to Nemo: Population Dynamics of the Orange Clownfish, Amphiprion percula Over an Eight-Year Time Gap on Kimbe Island, Papua New Guinea

Fitzgerald, Lucy

04 1900

Long-term studies are important for understanding the intricacies of population dynamics over time. Self-recruitment and social hierarchy are valuable tools to quantify the rates at which populations change. In mutualistic symbiosis, where two species benefit from the relationship, different selective pressures and life histories can have unintended consequences on the population dynamics of both species. Anemonefish live in a sized-based hierarchy where individuals queue to be part of the breeding pair (ranks 1 and 2). They have a mutualistic association with their host anemone; the identity of the anemone can impact their growth and fecundity. However, there is limited knowledge on the anemone lifespan and its site persistence over time. Here, we investigate rank changes and self-recruitment in Amphiprion percula and persistence in a common host anemone, Stichodactyla gigantea, on the remote island of Kimbe Island in Papua New Guinea. The populations of A. percula (n = 1,530) and their local host anemones, S. gigantea (n = 290) and Heteractis magnifica (n = 174), were sampled exhaustively in 2011 and 2019. Using DNA profiling, I determined the fate of individuals between years. We found that 21% of the A. percula population survived over the eight-year time gap compared to the 69% survival of the associated S. gigantea population in a six-year time gap. Half of the surviving A. percula individuals increased in rank and exhibited faster growth rates living on S. gigantea compared to H. magnifica. Self-recruitment was high in both years, 47% in 2011 and 39% in 2019, with one individual returning to its natal anemone. Our findings provide rare insights into one of the most charismatic symbiotic relationships in the marine environment such as the first documentation of longevity in a host anemone.

Population Dynmics

Social Hierarchy

Mutualism

Clownfish

Anemones

Self-recruitment