Journal of Environmental Science International (한국환경과학회지)

The Korean Environmental Sciences Society (한국환경과학회)
권호 표지
DOI QR코드

DOI QR Code

The Geographical Distribution and Genetic Distance of Yellowfin Goby (Acanthogobius flavimanus) off the Coast of Korea

한국 연안에 서식하는 문절망둑의 지리적 분포와 유전적 거리

  • Hyunsang Shin (Department of Marine Biological Resource and Aquaculture, Kunsan National University) ;
  • Youn Choi (Department of Marine Biological Resource and Aquaculture, Kunsan National University) ;
  • Kiyoung Lee (Department of Marine Biological Resource and Aquaculture, Kunsan National University)
  • 신현상 (국립군산대학교 해양생물자원학과) ;
  • 최윤 (국립군산대학교 해양생물자원학과) ;
  • 이기영 (국립군산대학교 해양생물자원학과)
  • Received : 2024.03.15
  • Accepted : 2024.04.16
  • Published : 2024.04.30
Download PDF
⟨ Previous Next ⟩

Abstract

A total of 64 individuals of Acanthogobius flavimanus, which inhabit the coast of Korea, were collected from 8 regions from July to August 2023. A haplotype network and a phylogenetic tree were created. The genomic DNA of the target fish species was compared and analyzed with the genomic DNA of four regions in Japan downloaded from the National Center for Biotechnology Information (NCBI). In the haplotype network of Acanthogoboius flavimanus, Eocheong-do (EC) and Goseong (MAJ) exhibited low genetic similarity with other regions in Korea and Japan. The Phylogenetic tree showed that the population of MAJ exhibited differences in genetic structure compared to populations in other regions of Korea and Japan, indicating a distant relationship. Most marine organisms are known to migrate and spread via ocean currents, which is the most crucial factor promoting gene flow through larvae between populations. The haplotype of Acanthogobius flavimanus in MAJ differs from the haplotypes in Korea and Japan. The population in MAJ is believed to have limited genetic exchange due to the North Korea Cold Currents. We identified haplotype patterns based on the geographical distribution of Acanthogobius flavimanus off the coast of Korea and inferred that ocean currents have some influence on genetic distances.

Keywords

References

  1. Alvi, M. A., Khalid, A., Ali, R. M. A., Saqib, M., Qamar, W., Li, L., Ahmad, B., Fu, B., Yan, H., Jia, W., 2023, Genetic variation and population structure of fasciola hepatica: An in silico analysis, Parasitol.Res., 122, 2155-2173.  https://doi.org/10.1007/s00436-023-07917-0
  2. Bohonak, A. J., 1999, Dispersal, gene flow, and population structure, Q. Rev. Biol., 74, 21-45.  https://doi.org/10.1086/392950
  3. Burton, R. S., 1983, Protein polymorphisms and genetic differentiation of marine invertebrate populations, 4, 193-206. 
  4. Choi, Y., 2011, The goby, Jisungsa, Seoul, Korea, 69-101. 
  5. Choi, Y., Kim, I., Ryu, B., Park, J., 1996, Ecology of Synechogobius hasta (pisces: Gobiidae) in the kum river estuary, Korea, 29, 115-123. 
  6. Choi, Y., Kim, J., Park, J., 2021, Marine fishes of Korea, 5th, Kyohak-sa, Seoul, Korea, 460-485. 
  7. Fan, H. Y., Ji, Y. P., Zhang, S. H., Yuan, C. T., Gao, T. X., 2005, Research of fishery biology of the neritic fish Synechogobius ommaturus in the area of the huanghe delta, 35, 733-736. 
  8. Heo, N., Lomolino, M. V., Watkins Jr, J. E., Yun, S., Weber-Townsend, J., Fernando, D. D., 2022, Evolutionary history of the asplenium scolopendrium complex (aspleniaceae), a relictual fern with a northern pan-temperate disjunct distribution, Biol. J. Linn. Soc., 137, 183-199.  https://doi.org/10.1093/biolinnean/blac080
  9. Hirase, S., Chambers, S., Hassell, K., Carew, M., Pettigrove, V., Soyano, K., Nagae, M., Iwasaki, W., 2017, Phylogeography of the yellowfin goby Acanthogobius flavimanus in native and non-native distributions, Mar.Biol., 164, 1-12.  https://doi.org/10.1007/s00227-017-3137-6
  10. Hwang, J., Wong, C. K., 2005, The china coastal current as a driving force for transporting calanus sinicus (Copepoda: Calanoida) from its population centers to waters off taiwan and hong kong during the winter northeast monsoon period, J. Plankton Res., 27, 205-210.  https://doi.org/10.1093/plankt/fbh162
  11. Iwata, A., Jeon, S. R., 1987, First record of four gobiid fishes from Korea, 20, 1-12. 
  12. Kim, I. S., 1987, A Taxonomic revision of the subfamily gobiidae (pisces, gobiinae) from Korea, 20, 529-542. 
  13. Kuno, Y., Takita, T., 1997, The growth, maturation and feeding habits of the gobiid fish Acanthogobius hasta distributed in ariake sound, Kyushu, Japan. 63, 242-248.  https://doi.org/10.2331/fishsci.63.242
  14. Lee, Y., 1992, A Taxonomic study of the genera Acanthogobius and Synechogobius (Pisces: Gobiidae) from Korea, 4, 1-25. 
  15. Lee, Y., 2013, Changes in the list of species in Korean gobiid fishes, 24, 199-213.
  16. Moore, A., Giorgetti, A., Maclean, C., Grace, P., Wadhwa, S., Cooke, J., Prepared for the australian government department of the environment, water, heritage and the arts, commonwealth of Australia, 2008, Review of the impacts of gambusia, redfin perch, tench, roach, Yellowfin goby and Streaked goby in Australia, Australia. 
  17. Morgan, S. G., 1990, Impact of planktivorous fishes on dispersal, hatching, and morphology of estuarine crab larvae, 71, 1639-1652. 
  18. Moyle, P. B., Cech, J. J., 2004, Fishes, 5th, Pearson Prentice Hall, Upper Saddle River, NJ. 
  19. Nakabo, T., 2013, Fishes of Jjapan with pictorial keys to the species, Japan, 16-121. 
  20. National Institute of Biological Resources (NIBR), National institute of biological resources, 2024, National list of Korea, Incheon, Korea. 
  21. Neilson, M. E., Wilson Jr, R. R., 2005, mtDNA singletons as evidence of a post-invasion genetic bottleneck in Yellowfin goby Acanthogobius flavimanus from San Francisco bay, California, Mar. Ecol. Prog. Ser., 296, 197-208.  https://doi.org/10.3354/meps296197
  22. Nelson, J. S., Grande, T. C., Wilson, M. V., 2016, Fishes of the world, 5th, John Wiley & Sons, Hoboken New Jersey, 326-333. 
  23. Raco, M., Jung, T., Horta Jung, M., Chi, N. M., Botella, L., Suzuki, N., 2023, Sequence and phylogenetic analysis of a novel alphaendornavirus, the first virus described from the oomycete plant pathogen phytophthora heveae, Arch. Virol., 168, 1-7.  https://doi.org/10.1007/s00705-023-05786-7
  24. Shin, H., Byun, D., Park, K., Lee, S., Kang, B., Lee, S., Choi, B., Lee, E., Korea hydrographic and oceanography agency, 2016, Research on creating a standard template for educational schematic current map, Seoul, Korea. 
  25. Song, N., Zhang, X. M., Sun, X. F., Yanagimoto, T., Gao, T. X., 2010, Population genetic structure and larval dispersal potential of Spottedtail goby Synechogobius ommaturus in the north-west pacific, J. Fish Biol., 77, 388-402.  https://doi.org/10.1111/j.1095-8649.2010.02694.x
  26. Song, N., Zhang, X., Gao, T., 2010, Genetic diversity and population structure of Spottedtail goby (Synechogobius ommaturus) based on AFLP analysis, Biochem. Syst. Ecol., 38, 1089-1095.  https://doi.org/10.1016/j.bse.2010.10.007
  27. Sun, Z., Li, Y., Song, C., Chen, J., Song, N., 2020, Comparative studies on morphology and genetics between Acanthogobius ommaturus and Acanthogobius flavimanus, JFC, 44, 1237-1248. 
  28. Suzuki, N., Sakurai, N., Sugihara, T., 1989, Development of eggs, larvae and juveniles of the Oriental goby Acanthogobius flavimanus reared in the laboratory, 36, 277-289. 
  29. Thuy, T. T., My, N. H., Hau, T. D., 2022, First faunal record of larval and juvenile gobies (Actinopterygii: Gobiiformes) in the ka long estuary, northern vietnam, 44, 61-72.  https://doi.org/10.15625/2615-9023/16120
  30. Zhang, D., Kan, X., Huss, S. E., Jiang, L., Chen, L., Hu, Y., 2018, Using phylogenetic analysis to investigate eukaryotic gene origin, 138, e56684. 
  31. Zhang, D., Gao, F., Jakovlic, I., Zou, H., Zhang, J., Li, W. X., Wang, G. T., 2020, PhyloSuite: An integrated and scalable desktop platform for streamlined molecular sequence data management and evolutionary phylogenetics studies, 20(1), 348-355.