Demography, taxonomy, genetics model of the Yenisei sturgeon. 20 years later. Part 3. Mitotypic polymorphism

Based on the results of factor analysis of morphometric features and mito-objects, a semantic interpretation of the interaction of nuclear/Mendelian genetics/and cytoplasmic/ mito-object composition/genomes in the form of a table of interaction of carriers of haplotypes of Russian and baerii-iike sturgeons is considered. Regression relationships “weight – haplobject composition,” mitobject and gene waves for samples of various reservoirs of Siberia from the Ob to Kolyma are built. Execution of dependencies with determination of order 0.9 was noted. 

1. Bazelyuk N.I., Kozlova N.V., Mukhamedova R.F. (2013). Molecular genetic identification of the Russian sturgeon (sturgeon Acipenser gueldenstaedtii) from natural populations of the Volga-Caspian basin // Yestvennye nauki (Natural Sciences). 2 (43) Genetics. Pp. 82-86. (In Russ.)

2. Barminsheva A.E. (2017). Phylogeography and intraspecific genetic polymorphism of the Siberian island, invented by Baery Brandt in 1869 in nature and aquaculture, Moscow: diss. ... book 120 pages. (In Russ.)

3. Gaidenok N.D., Zadelenov V.A. (2024). Demography, taxonomy, genetics of the Yenisei sturgeon model – 20 years later, Part 1 // Fisheries. No. 3. From 57-64. https://doi.org/10.36038/0131-6184-2024-3-57-64. (In Rus., abstract in Eng.)

4. Gaidenok N.D., Kirichenko O.I., Perestilin A.I. (2025). Demography, taxonomy, genetics of the Yenisei sturgeon model – 20 years later. Part 2. Morphometric polymorphism of the Yenisei sturgeon // Fisheries. No. 2. Pp. 57-64. https://doi.org/10.36038/0131- 6184-2025-2-57-64. (In Rus., abstract in Eng.)

5. Ivanov V.P., Paltkov V.N., Shipulin S.V. (2023). Fish resources of the Caspian Sea. Moscow: VNIRO Publishing House. 560 p. (In Russ.)

6. Kolmogorov A.N., Petrovsky I.G., Piskunov N.S. (1937). Investigation of the diffusion equation coupled with the increase of matter and its application to a biological problem. Bulletin of the Moscow State University. Ser. A. Mathematics and Mechanics. 1:6. Pp. 1-26. (In Russ.)

7. Nikolsky G.B. (1956). Fishes of the Amur basin – Moscow: Nauka. 552 p. (In Russ.)

8. Pobedintseva M.A. (2022). Molecular genetic diversity of river and lake polyploid fishes of Northern Eurasia – Novosibirsk: diss. ... book 120 pages. (In Russ.)

9. Svirezhev Yu.M. (1987). Nonlinear waves, dissipative structures and catastrophes in ecology. – M: Science. Gl. ed. fiz-mat. lit. 368 p. (In Russ.)

10. Svirezhev Yu.M., Pasekov V.P. (1982). Fundamentals of mathematical genetics. Moscow: Nauka. 512 p. (In Russ.)

11. Semyonko S.V. (2022). Molecular dating of insects (acipenseridae) based on the analysis of aggregate data // Genetics. Volume 58. No. 6. Pp. 700-712. (In Russ.)

12. Birstein V.J., Dukakis P., Desalle R. (2000). Polyphilia of mtDNA lines in Russian sturgeon, Acipenser gueldenstaedtii: Criminalistic and evolutionary aspects. Environmental genetics. Vol.1. Pp. 81-88

13. Birshtein V., Ruban G.I., Ludwig A., Dukakis P., Desalle R. (2005). The mysterious Russian sturgeon of the Caspian Sea: How many mysterious forms does it have? // Taxonomy and biodiversity. Vol. 3, No. 2. Pp. 203-218.

14. Fischer R.A. (1937). The wave of the spread of beneficial genes: Annals of eugenics. vol. 7. Pp. 355-369

15. Ivanov V.P., Nikonorov Yu., Perevaryukha N. (2003). Siberian sturgeon in Volga river caviar? // IWMC. World Wide Fund for Nature, April. (booklet)

16. Jennekens I., Meyer J.-N., Debus L., Pitra K., Ludwig A. (2000). Evidence of the presence of mitochondrial DNA clones of the Siberian sturgeon Acipenser baerii in the Russian sturgeon Acipenser gueldenstaedtii, caught in the Volga River. // Environmental letters. Vol. 3(6). Pp. 503-508

17. Kostitsyn V.A. (1937). Biological mathematics. – Paris: A/Colin. Pp. 2204-2215

18. Yanjun Shen E.A. A phylogenetic view on the relationship and evolutionary history of Acipenseriformes // Genomics. vol. 112. No. 5. Pp. 3511-3517