Coordinatore | UNIVERSITAT DE BARCELONA
Organization address
address: GRAN VIA DE LES CORTS CATALANES 585 contact info |
Nazionalità Coordinatore | Spain [ES] |
Totale costo | 87˙500 € |
EC contributo | 87˙500 € |
Programma | FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013) |
Code Call | FP7-PEOPLE-2010-RG |
Funding Scheme | MC-IRG |
Anno di inizio | 2011 |
Periodo (anno-mese-giorno) | 2011-04-01 - 2014-09-30 |
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UNIVERSITAT DE BARCELONA
Organization address
address: GRAN VIA DE LES CORTS CATALANES 585 contact info |
ES (BARCELONA) | coordinator | 87˙500.00 |
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'The study of invertebrate-microbial associations is emerging as a prominent field in marine biology and biotechnology, with vast implications that range from a fundamental knowledge of host ecology and symbiont biodiversity to the advanced understanding of natural products discovery and sustainable production. While considerable incentives exist to unravel the complex metabolic interactions between host invertebrates and symbiotic microbes, basic questions regarding the biodiversity and stability of these relationships remain unanswered. Here, I propose to advance our knowledge on the genetic diversity, spatio-temporal variability and functional significance of microbial symbionts in ascidians. First, I propose to characterize the diversity and host-specificity of ascidian-microbial symbioses by massively parallel 16S rRNA gene tag pyrosequencing and comparison of microbial community partitioning in ascidians at the inter- and intra-species levels. Secondly, I will describe the dynamics and fidelity of invertebrate-microbial relationships by documenting spatial and temporal fluctuations of bacterial and archaeal communities in ascidians, utilizing the sensitive DNA fingerprinting technique T-RFLP in conjunction with 16S rRNA gene libraries from pyrosequencing. Finally, I will provide the first assessment of the contribution of autotrophic and heterotrophic symbionts to host metabolism over time by quantifying the stress levels and reproductive success of the host. The multi-scale and interdisciplinary research approach suggested here will provide for the first holistic account of host-symbiont interactions between ascidians and microbes.'
Marine biologists and biotechnologists are turning their attention to the study of invertebrate-microbial associations. This area of research has enormous implications, ranging from host ecology and symbiont biodiversity to the discovery of natural products and their sustainable production.
Although the rewards for revealing the complex interactions between host invertebrates and symbiotic microbes are significant, many questions remain. Their answers may be found, however, through the efforts of the EU-funded project 'Bacterial symbiosis in ascidians' (SYMASC).
The initiative investigated the genetic diversity, spatio-temporal variability and functional significance of symbiotic microorganisms living in ascidians (commonly known as sea squirts). The microbiota living in ascidians were found to be clearly different from free-living seawater microbial communities. It was also revealed that some of the microorganisms associated with sea squirts were shared with other invertebrate hosts, while others were unique to ascidians.
Ascidian-microbial associations appear to be stable over time, with bacteria generally present in both larvae and adults, suggesting that at least some bacterial symbionts may be indispensable for the establishment and long-term survival of ascidians. In addition, the symbiotic relationship between sea squirts and microorgansims exists independently of factors like the host's life cycle, stress levels and the temperature of the surrounding seawater.
Studies of ascidian microbiota also showed that these associations are maintained by the microenvironment within the host organism, providing optimal conditions for different metabolic pathways. These conditions include ample chemical substrate in the form of ammonia-rich waste from the host suitable for microbial nitrification, and sufficient exposure to light so cyanobacterial symbionts can perform photosynthesis. In this way, sea squirts provide unique and fertile conditions for a diverse group of microorganisms.
The invasive ascidian Styela plicata was further studied as a model species. It was discovered that the bacterial communities it hosts might help it survive and acclimatise to new habitats by establishing relationships with beneficial local bacteria.
SYMASC represented an interdisciplinary study of host-symbiont interactions between ascidians and microbes, resulting in significant advances in the study of invertebrate-microbial symbioses and a greater understanding of how symbiotic microorganisms respond to changing environmental conditions and interact with their hosts. New insights into the short-term vulnerability and long-term resilience of these important seabed-dwelling organisms were also obtained.
Results from SYMASC will help set a baseline for future studies and the design of management plans that will ensure the long-term preservation of marine biodiversity.