Wenying Hong , Rudi Mai

Tropical Bioresources Research Center, Hainan Tropical Agricultural Resources Research Institute, Sanya, 572025, Hainan, China
Author    Correspondence author
International Journal of Marine Science, 2025, Vol. 15, No. 1   
Received: 17 Dec., 2024    Accepted: 20 Jan., 2025    Published: 29 Jan., 2025

This is an open access article published under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Oysters are widely distributed along coastal regions worldwide and serve as key ecological engineering species with significant value in maintaining coastal ecosystem functions and supporting fisheries. However, the biogeographic distribution patterns and genetic connectivity of oyster populations vary considerably across regions, influenced by a combination of paleoclimatic and geological history, oceanographic gradients, and human activities. This study provides a comprehensive overview of the systematics and distribution of major oyster groups globally, elucidates the biogeographic divisions and historical-ecological factors driving oyster population differentiation, and reviews recent advances in the application of molecular markers and population genomics in studying oyster genetic connectivity. Through case studies from representative regions—including Pacific oysters in the Northwest Pacific, eastern oysters in the North Atlantic of North America, and rock oysters in Europe and the Southern Hemisphere—we analyze the genetic structure and connectivity patterns of regional populations. The results reveal variations in genetic diversity and gene flow levels among oyster populations across different marine regions. Understanding genetic connectivity is crucial for biodiversity conservation and sustainable resource management, enabling the delineation of management units and guiding breeding, stock enhancement, and habitat restoration efforts. Under global climate change, oyster population distributions and connectivity patterns may undergo profound shifts, necessitating enhanced research on oysters’ genetic responses to environmental changes. This study advocates for incorporating genetic connectivity into habitat conservation and aquaculture management decisions to enhance oyster populations' adaptability to environmental changes and ensure the long-term maintenance of their ecological functions and economic value.

Oyster; Biogeography; Genetic connectivity; Population genetics; Conservation genetics