Abstract
Molecular studies based on the high resolution genetic markers help us to grasp the factor shaping the genetic structure of marine organisms. Ecological factors linking to life history traits have often explained the process of genetic structuring in open and connectable oceanic environments. Besides, population genetic divergence can be affected by fragmented habitat, oceanic current, and past geographical events. In the present study, we demonstrated the genetic differentiation of marine gastropod Monodonta sp. within a narrow range of peripheral oceanic islands, the Ogasawara Islands. Genetic analyses were performed not only with a mitochondrial DNA marker but also with a high-throughput SNPs dataset obtained by ddRAD-seq. The results of the mtDNA analyses did not show genetic divergence among populations, while the SNPs dataset detected population genetic differentiation. Population demographic analyses and gene flow estimation suggested that the genetic structure was formed by sea level fluctuation associated with the past climatic change and regulated by temporal oceanographic conditions. These findings provide important insights into population genetic patterns in open and connectable environments.
Highlights
Molecular studies based on the high resolution genetic markers help us to grasp the factor shaping the genetic structure of marine organisms
The analysis of molecular variance (AMOVA) analysis did not show the existence of population genetic differentiation in Monodonta sp. (ΦST = 0.02, P = 0.23; Table 2)
The present study tested the level of population genetic differentiation of an intertidal gastropod species distributed within a narrow range of peripheral oceanic islands using two types of genetic markers
Summary
Molecular studies based on the high resolution genetic markers help us to grasp the factor shaping the genetic structure of marine organisms. Population demographic analyses and gene flow estimation suggested that the genetic structure was formed by sea level fluctuation associated with the past climatic change and regulated by temporal oceanographic conditions. These findings provide important insights into population genetic patterns in open and connectable environments. For marine benthic organisms with low mobility in the adult phase, life history traits such as development types and the length of the planktonic larval phase are related to the level of dispersal ability and connectivity among populations It often explains the process of genetic structuring in marine situations[5–8]. Oceanic islands provide a simple model for studying the process of genetic differentiation following divergence from ancestral species
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