The Stability of the Giant Clam Holobiont over Time and during Bleaching Stress

Pappas, Melissa

12 1900

The stability of marine photosymbiotic holobionts has major implications for the future of coral reef communities. This study aims to describe the stability of the Red Sea giant clam holobiont over the duration of one year and during induced bleaching stress under laboratory thermal manipulations. Tridacnid clams of the species Tridacna maxima were sampled at three reef locations near the central Saudi coast of the Red Sea. Associated Symbiodinium of Red Sea giant clams have previously been described to be part of only Clade A, which suggests a strong specificity in the clam-algal partnership, but specific types and potential shifting of types within this clade have not been examined for giant clams. The results from this study confirm that tridacnid symbiont types shift over time and the change between three A1 types suggests a biological and functional significance of two undescribed A1 Symbiodinium types. Experimental bleaching shows that Red Sea giant clams, although exposed to rather hot temperatures naturally, will bleach at 34°C after two weeks, and severely bleached clams likely will not recover. During bleaching, Symbiodinium types shift as well, and shift more drastically than seasonal shifts during the year. This shifting may be an evolved characteristic of the giant clam to aid in surviving major changes in the environment. However, more research is needed to determine if these holobionts are capable of keeping up with the global forecast of warming in reef environments.

Symbiosis

Giant clam

Bleaching

Symbiodinium

Thermal tolerance

Clade A

Implications of irradiance for the Red Sea Tridacna giant clam holobiont

Rossbach, Susann

01 1900

Giant clams (Tridacninae subfamily) are prominent members of Indo-Pacific corals reefs, including the Red Sea, where they play multiple roles and are of distinct ecological significance for these communities. Tridacninae stand out among other bivalves as one of the few molluscan groups that live in a symbiosis with dinoflagellate Symbiodiniaceae. This relationship is comparable to the symbiosis of corals and their associated algae, where the symbionts provide a substantial amount of the respiratory carbon demand of the host through their photosynthetic activity. Their photosymbiosis restricts the distribution of the Tridacninae holobiont (i.e. giant clam host, symbiotic algae and associated bacteria) to the sunlit, shallow waters of the euphotic zone, where organisms receive sufficient incident light to maintain their high rates of primary production and calcification. However, giant clams in these shallow reefs are simultaneously exposed to potentially high and damaging levels of solar (UV) radiation. This thesis includes research on the Red Sea Tridacna spp. holobiont from an ecosystem to microscale level. It assess the abundance and distribution of Red Sea giant clams, including their associated symbiotic microalgae and bacterial microbiome. Further, it describes the strong light-dependency of calcification and primary production of Red Sea Tridacna maxima clams and reports on the effective photo-protective mechanisms that have been evolved by these clams to thrive in shallow reefs, despite levels of high solar irradiance. Tridacninae developed effective behavioral mechanisms for photo-protection, by which the clam is able to flexibly adjust its shell gaping behavior to incident light levels within a narrow time frame. On a microscale, Tridacninae use advanced photonic structures (iridocytes) within their tissues to mitigate the potential negative effects of high solar UV radiation, and to promote the photosynthesis of their symbiotic algae. Understanding the role of the Tridacna spp. holobiont for Red Sea coral reefs, its contributions to overall productivity, and its abundances in the region may serve as a baseline for further studies on this charismatic invertebrate. It may also contribute to the conservation efforts from local to regional scales, and eventually aid the protection of Tridacninae in the Red Sea and elsewhere.

Giant clam

Tridacna

Light

Red Sea

Ecology

Calcification

Underwater Animal Monitoring Magnetic Sensor System

Kaidarova, Altynay

10 1900

Obtaining new insights into the behavior of free-living marine organisms is fundamental for conservation efforts and anticipating the impact of climate change on marine ecosystems. Despite the recent advances in biotelemetry, collecting physiological and behavioral parameters of underwater free-living animals remains technically challenging. In this thesis, we develop the first magnetic underwater animal monitoring system that utilizes Tunnel magnetoresistance (TMR) sensors, the most sensitive solid-state sensors today, coupled with flexible magnetic composites. The TMR sensors are composed of CoFeB free layers and MgO tunnel barriers, patterned using standard optical lithography and ion milling procedures. The short and long-term stability of the TMR sensors has been studied using statistical and Allan deviation analysis. Instrumentation noise has been reduced using optimized electrical interconnection schemes. We also develop flexible NdFeB-PDMS composite magnets optimized for applications in corrosive marine environments, and which can be attached to marine animals. The magnetic and mechanical properties are studied for different NdFeB powder concentrations and the performance of the magnetic composites for different exposure times to sea water is systematically investigated. Without protective layer, the composite magnets loose more than 50% of their magnetization after 51 days in seawater. The durability of the composite magnets can be considerably improved by using polymer coatings which are protecting the composite magnet, whereby Parylene C is found to be the most effective solution, providing simultaneously corrosion resistance, flexibility, and enhanced biocompatibility. A Parylene C film of 2μm thickness provides the sufficient protection of the magnetic composite in corrosive aqueous environments for more than 70 days. For the high level performance of the system, the theoretically optimal position of the composite magnets with respect to the sensing direction of the sensor has been estimated using finite element modeling software. The magnetic sensing system has been practically implemented for monitoring the belly size of a model fish and for monitoring the behavior of the largest living bivalve, giant clam (Tridacna maxima) in an aquarium. In both of these experiments, the sensing system showed a high performance, indicating its potential for novel marine monitoring applications.

Magnetic

Underwater Monitoring

Giant Clam

Composite Magnets

TMR Sensor

NdFeB/PDMS

Les bénitiers de Nouvelle-Calédonie : nouvelles espèces et échelles spatiales de connectivité chez Tridacna maxima et Hippopus hippopus / Giant clams of New Caledonia : new species and spatial scales of connectivity among Tridacna maxima and Hippopus hippopus

Tiavouane, Josina

29 June 2016

Malgré leur rôle fonctionnel au sein des écosystèmes coralliens, les populations de bénitiers (Tridacninae) sont en déclin à travers le monde en raison de leur surexploitation. En Nouvelle-Calédonie, 1 à 9 tonnes sont prélevées par an. Dans ce contexte, cette thèse a pour principaux objectifs de fournir des indications quant aux connectivités démographiques et évolutives des populations de deux espèces de bénitiers en Nouvelle-Calédonie, Tridacna maxima et Hippopus hippopus afin d'estimer les échelles spatiales de dispersion larvaire, comprendre leur dynamique et proposer des mesures de conservation adaptées. La connectivité des populations a été estimée via l'analyse de marqueurs génétiques microsatellites spécifiquement développés pour ces deux espèces. L'échantillonnage a permis l'identification de deux nouvelles espèces en Nouvelle-Calédonie. A l'échelle d'un récif et de quelques kilomètres, les tests de parenté montrent des taux d'auto-recrutement variables, jusqu'à 8% pour T. maxima dans le lagon sud-ouest et 29% pour H. hippopus dans le lagon nord-est. Les échelles spatiales de dispersion larvaire varient selon les espèces, jusqu'à au moins 35km pour H. hippopus. A l'échelle du territoire, les populations de bénitiers sont peu structurées, indiquant une connectivité évolutive certaine. Néanmoins, des différences significatives ont été observées entre la Grande Terre et Chesterfield, les Iles Loyautés et les atolls d'Entrecasteaux pour H. hippopus et entre la côte ouest et les Îles Loyautés pour T. maxima. Ces résultats fournissent d'importants éléments de réponse relatifs aux échelles spatiales de dispersion des bénitiers en Nouvelle-Calédonie. / Despite their functional role in coral reef ecosystems, giant clams (Tridacninae) are in decline worldwide due to their overexploitation. In New Caledonia, 1 to 9 tons are harvested per year. In this context, the main objectives of this thesis are to provide information about the demographic and evolutionary population’s connectivity for two species of giant clams in New Caledonia, Tridacna maxima and Hippopus hippopus, in order to estimate the spatial scales of larval dispersal, understand their population dynamics and propose appropriate conservation measures. The connectivity of populations was estimated by analyzing microsatellite genetic markers specifically developed for these two species. Sampling allowed the identification of two new species in New Caledonia. At reef scale and up to a few kilometers, parentage analysis showed that giant clam populations have varying self-recruitment rates, up to 8% for T. maxima in southwest lagoon and 29% for H. hippopus in northeastern lagoon. The spatial scales of larval dispersal varied for the two species, up to at least 35km for H. hippopus. At the scale of the territory, giant clam populations showed a weak genetic structure, highlighting evolutionary connectivity among sampled sites. However, significant differences were observed between the Mainland and Chesterfield, Loyalty Islands and Entrecasteaux for H. hippopus and between the west coast and the Loyalty Islands for T. maxima. These results provide important answers related to the spatial scales of larval dispersal in giant clams in New Caledonia.

Connectivité démographique

Connectivité évolutive

Bénitiers

Aires marines protégées

Auto-Recrutement

Dispersion larvaire

Repeuplement

Récifs coralliens

Demographic and evolutive connectivity

Giant clam

Tridacniae

577.7