The latest study was published online in Nature
An international research team, led by Institute of Oceanology of Chinese Academy of Sciences and BGI, has completed the sequencing, assembly and analysis of Pacific oyster (Crassostrea gigas) genome—the first mollusk genome to be sequenced—that will help to fill a void in our understanding of the species-rich but poorly explored mollusc family. The study, published online today in Nature, reveals the unique adaptations of oysters to highly stressful environment and the complexity mechanism of shell formation.
"The accomplishment is a major breakthrough in the international Conchological research, with great advancement in the fields of Conchology and Marine Biology." said, Professor Fusui Zhang, Academician of Chinese Academy of Sciences, and a well-known Chinese Scientist of Conchology, "The study will provide valuable resources for studying the biology and genetic improvement of molluscs and other marine species. "
Oysters are a soft-bodied invertebrate with a double-hinged shell, which make up an essential part of many aquatic ecosystems. They have a global distribution and for many years they have much higher annual production than any other freshwater or marine organisms. In addition to its economic and ecological importance, the unique biological characteristics of oyster make it an important model for studying marine adaptations, inducing a great deal of biological and genomics research. The completed sequencing of oyster genome will provide a new horizon into understanding its natural mechanisms such as the adaptations to environmental stresses and shell formation, better exploration of marine gene resource, , among others.
Unlike many mammals and social insects, oyster as well as many other marine invertebrates is known to be highly polymorphism, which is a challenge for de novo assembling based on current strategies. In this study, researchers sequenced and assembled the Pacific oyster genome using a combination of short reads and a "Divide and Conquer" fosmid-pooling strategy. This is a novel approach developed by BGI, which can be used to study the genomes with high level of heterozygosity and/or repetitive sequences. After data process, the assembled oyster genome size is about 559 Mb, with a total of ~28,000 genes.
Based on the genomic and transcriptomic analysis results, researchers uncovered an extensive set of genes that allow oysters to adapt and cope with environmental stresses, such as temperature variation and changes in salinity, air exposure and heavy metals. For example, the expansion of heat shock protein 70 (HSP 70) may help explain why Pacific oyster can tolerate high temperatures as HSP family is expanded and highly expressed when in high temperature. The expansion of inhibitors of apoptosis proteins (IAPs), along with other findings, suggested that a powerful anti-apoptosis system exists and may be critical for oyster's amazing endurance to air exposure and other stresses. One notable finding on development is that the oyster Hox gene cluster was broken, and there are unusual gene losses and expansions of the TALE and PRD classes. Hox genes are essential and play critical important role in body plan, the Hox clusters are found to be more conserved in many organisms.
Researchers found paralogs might have the function to change the gene expression for better coping with the stresses. This result suggested that expansion and selective retention of duplicated defense-related genes are probably important to oyster's adaptation. Moreover, many immune-related genes were highly expressed in the digestive gland of the oyster, which indicated its digestive system was an important first-line defense organ against pathogens for the filter-feeder. The shell provides a strong protection against predation and desiccation in sessile marine animals such as oysters. At present, two models have been proposed for molluscan shell formation, but neither of them is accurate enough. In this study, by sequencing the peptides in the shell, researchers identified 259 shell proteins, and further analysis revealed that shell formation was a far more complex process than previously thought. They found many diverse proteins may play important roles in matrix construction and modification. The typical ECM proteins such as Laminin and some collagens were highly expressed in shells, suggesting that shell matrix has similarities to the ECM of animal connective tissues and basal lamina. Hemocytes may mediate fibronectin (FN)-like fibril formation in the shell matrix as they do in ECM. Furthermore, the functional diversity of proteins showed that the cells and exosome may participate in the shell formation.
Xiaodong Fang, Primary Investigator of this project at BGI, said, "The assembly approach of Oyster genome opens a new way for researchers to better crack the genomes with high-heterozygosity and high-polymorphism. The Oyster genome sheds insights into the comprehensive understanding of mollusc genomes or even lophotrochozoa genomes at the whole genome-wide level, with focuses on the studies of diversity, evolutionary adaptive mechanisms, developmental biology as well as genomics-assisted breeding. "
- The Institute of Oceanology of Chinese Academy of Sciences (IOCAS): IOCAS was established on August, 1950, and it is a multidisciplinary research and development institute in marine science in China. IOCAS is one of the organizations for strategic test on national intellectual property authorized by the State Intellectual Property Office of China (SIPO). IOCAS is also a key center for graduate education and training in marine science in China. It offers Ph.D. degree in 9 research areas and M.S. degree in 11 research areas. It also provides post-doctoral research opportunities in marine science. IOCAS currently has 600 employees, among which are 400 research staff, including 200 senior scientists. Among the research scientists, 4 are academicians of the Chinese Academy of Science (CAS) and 2 are academicians of the Chinese Academy of Engineering (CAE), and 106 are Ph.D. supervisors. For more information about BGI, please visit
- BGI: BGI was founded in Beijing, China, in 1999 with the mission to become a premier scientific partner for the global research community. The goal of BGI is to make leading-edge genomic science highly accessible, which it achieves through its investment in infrastructure, leveraging the best available technology, economies of scale, and expert bioinformatics resources. BGI, and its affiliates, BGI Americas, headquartered in Cambridge, MA, and BGI Europe, headquartered in Copenhagen, Denmark, have established partnerships and collaborations with leading academic and government research institutions as well as global biotechnology and pharmaceutical companies, supporting a variety of disease, agricultural, environmental, and related applications. BGI has a proven track record of excellence, delivering results with high efficiency and accuracy for innovative, high-profile research: research that has generated over 200 publications in top-tier journals such as Nature and Science. BGI's many accomplishments include: sequencing one percent of the human genome for the International Human Genome Project, contributing 10 percent to the International Human HapMap Project, carrying out research to combat SARS and German deadly E. coli, playing a key role in the Sino-British Chicken Genome Project, and completing the sequence of the rice genome, the silkworm genome, the first Asian diploid genome, the potato genome, and, more recently, have sequenced the human Gut Metagenome, and a significant proportion of the genomes for the1000 Genomes Project.