Bacterial Community Structures Associated with Healthy and Diseased Corals from Southern Taiwan

Chiu, Su-fen

16 June 2010

The methods of denaturing gradient gel electrophoresis (DGGE) and DNA sequencing were used to analyze the ribotypes of microbial communities associated with corals. Both healthy and diseased coral of different species were collected at three locations off the southern coast of Taiwan. Ribotyping results suggested that the microbial communities were diverse. The microbial community profiles, even among the same species of corals from different geographical locations or different times, differ significantly. The coral-associated bacterial communities contain many bacteria common to the habitants of various invertebrates. One ribotype presented on the Black Disease coral tissue is closely related to the Clostridium sp. previously identified from White Plaque-diseased and BBD corals. This Clostridium sp. may be relatived to coral diseased, as this species was also found in many types of diseased coral. The other one ribotype presented on our healthy and diseases coral is closed to denitrifying bacterium Pseudovibrio sp. which had been previously discovered in Kenting National Park Nanwan Bay as a new marine, facultative anaerobic bacterium. However, some bacteria were unexpected. The presence of some unusual species, such as Staphylococcus, Legionella and soil bacteria, associated with corals that were likely the results of human activities. Human activities, such as active fishing and tourism industries in the region might have all contributed to the change in bacterial communities and the death of coral colonies around the region.

microbial diversity

Black Disease (BD)

Coral associated bacteria

Comparative Profiling of coral symbiont communities from the Caribbean, Indo-Pacific, and Arabian Seas

Arif, Chatchanit

12 1900

Coral reef ecosystems are in rapid decline due to global and local anthropogenic factors. Being among the most diverse ecosystems on Earth, a loss will decrease species diversity, and remove food source for people along the coast. The coral together with its symbionts (i.e. Symbiodinium, bacteria, and other microorganisms) is called the ‘coral holobiont’. The coral host offers its associated symbionts suitable habitats and nutrients, while Symbiodinium and coral-associated bacteria provide the host with photosynthates and vital nutrients. Association of corals with certain types of Symbiodinium and bacteria confer coral stress tolerance, and lack or loss of these symbionts coincides with diseased or bleached corals. However, a detailed understanding of the coral holobiont diversity and structure in regard to diseases and health states or across global scales is missing. This dissertation addressed coral-associated symbiont diversity, specifically of Symbiodinium and bacteria, in various coral species from different geographic locations and different health states. The main aims were (1) to expand the scope of existing technologies, (2) to establish a standardized framework to facilitate comparison of symbiont assemblages over coral species and sites, (3) to assess Symbiodinium diversity in the Arabian Seas, and (4) to elucidate whether coral health states have conserved bacterial footprints. In summary, a next generation sequencing pipeline for Symbiodinium diversity typing of the ITS2 marker is developed and applied to describe Symbiodinium diversity in corals around the Arabian Peninsula. The data show that corals in the Arabian Seas are dominated by a single Symbiodinium type, but harbor a rich variety of types in low abundant. Further, association with different Symbiodinium types is structured according to geographic locations. In addition, the application of 16S rRNA gene microarrays to investigate how differences in microbiome structure relate to differences in health and disease demonstrate that coral species share common microbial footprints in phenotypically similar diseases that are conserved between regional seas. Moreover, corals harbor bacteria that are species-specific and distinct from the diseased microbial footprints. The existence of conserved coral disease microbiomes allows for cataloging diseases based on bacterial assemblage over coral species boundaries and will greatly facilitate future comparative analyses.

Symbiodinium

Coral Disease

White Plague Disease (WPD)

Coral-associated Bacteria

Red Sea

Persian Gulf

Arabian Gulf