A. N. Stroganov

Analysis of Microsatellite Loci Variations in Herring (Clupea pallasii marisalbi) from the White Sea

The genetic diversity among spawning groups of herring from different parts of the White Sea was assessed using ten microsatellite loci. All loci were polymorphic with the expected heterozygosity estimates varying in the range of 12.7–94.1% (mean was 59.5%). The degree of genetic differentiation displayed by White Sea herring was statistically significant (θ = 2.03%). The level of pairwise genetic differentiation FST was 0–0.085, and it was statistically significant in most of the comparison pairs between the herring samples. A hierarchical analysis of molecular variance (AMOVA) revealed the statistically significant differentiation of White Sea herring. 96.59% genetic variation was found within the samples and 3.41% variation was found among the populations. The main component of interpopulation diversity (1.85%) falls at the differences between two ecological forms of herring, spring- and summer-spawning. Within the spring-spawning form, the presence of local stocks in Kandalaksha Bay, Onega Bay, and Dvina Bay was demonstrated.

Genetic variations in Clupea pallasii herring from Sea of Okhotsk based on microsatellite markers

The genetic variations among spawning groups of herrings from different spawning grounds of the northwestern part of the Sea of Okhotsk was assessed using ten microsatellite loci. All loci were polymorphic with the expected heterozygosity estimates varying at different loci in the range of 0.7–95.0% (with a mean of 68.5%). The degree of genetic differentiation displayed by the herrings from the Sea of Okhotsk was not statistically significant (θ = 0.74%). The level of pairwise genetic differentiation FST varied in the range of 0.002–0.014, nor was it statistically significant in all comparison pairs between the herring samples.

Population structure and variability of Pacific herring (Clupea pallasii) in the White Sea, Barents and Kara Seas revealed by microsatellite DNA analyses

Pacific herring, Clupea pallasii, have recently colonised the northeast Atlantic and Arctic Oceans in the early Holocene. In a relatively short evolutionary time, the herring formed a community with a complex population structure. Previous genetic studies based on morphological, allozyme and mitochondrial DNA data have supported the existence of two herring subspecies from the White Sea and eastern Barents and Kara Seas (C. p. marisalbi and C. p. suworowi, respectively). However, the population structure of the White Sea herring has long been debated and remains controversial. The analyses of morphological and allozyme data have previously identified local spawning groups of herring in the White Sea, whereas mtDNA markers have not revealed any differentiation. We conducted one of the first studies of microsatellite variation for the purpose of investigating the genetic structure and relationship of Pacific herring among ten localities in the White Sea, the Barents Sea and the Kara Sea. Using classical genetic variance-based methods (hierarchical AMOVA, overall and pairwise FST comparisons), as well as the Bayesian clustering, we infer considerable genetic diversity and population structure in herring at ten microsatellite loci. Genetic differentiation was the most pronounced between the White Sea (C. p. marisalbi) versus the Barents and Kara seas (Chesha–Pechora herring, C. p. suworowi). While microsatellite variation in all C. pallasii was considerable, genetic diversity was significantly lower in C. p. suworowi, than in C. p. marisalbi. Also, tests of genetic differentiation were indicating significant differentiation within the White Sea herring between sympatric summer- and spring-spawning groups, in comparison with genetic homogeneity of the Chesha–Pechora herring.

Comparative Analysis of Genetic Variability of White Sea Cod (Gadus morhua marisalbi) at Allozyme and Microsatellite Markers

Variability of cod spawning and feeding schools from Kandalaksha Bay of the White Sea, was examined at six allozyme and eight microsatellite loci. The degree of genetic differentiation at allozyme loci constituted θ = 0.36% [95% bootstrap interval 0.0458; 0.6743]. The differentiation estimates obtained using microsatellite markers were higher, θ = 1.33% [0.057; 3.11]. It was demonstrated that the level of genetic diversity in the White Sea cod was lower than that established for the Atlantic cod from Barents Sea using the same set of allozyme and microsatellite markers. The genetic data obtained support the opinion that the White Sea cod is a reproductively independent group formed as a result of the Holocene dispersal of Atlantic cod.

Genus Gadus (Gadidae): Composition, distribution, and evolution of forms

Analysis of the morphobiological and genetic characteristics of the Gadus genus has been performed, the peculiarities of the genus evolution are discussed, and the resettlement has been reconstructed for the period of 5.5-5.4 million years until the present. The genus Gadus comprises two polytypic species, Atlantic cod G. morhua and Pacific cod, and both species form several subspecies combined into two phylogenetic groups. The taxonomical status of the Greenland cod G. macrocephalus ogac has been specified. The analyzed material evidences to the illegality of synonymy of the Greenland cod and the White Sea cod, since the latter species is genetically a product of the Holocene resettlement of the Atlantic cod and, thus, appears as its subspecies, but the Greenland cod is a product of the Holocene resettlement of the Pacific cod, appearing as its subspecies.

On differentiation of cod (Gadus morhua L.) groups in Baltic Sea

Using the AGP*, PGI-1*, PGI-2*, LDH*, IDH*, and PGM* allozyme markers, the differentiation of cod groups during the spawning period in Baltic Sea was evaluated. It was demonstrated that cod samples from the eastern and western parts of Baltic Sea (being statistically significantly different from the cod samples from the Norwegian Sea, Barents Sea, and the Skagerrak Strait) demonstrated a high degree of identity (I = 0.99–1.0), which could be associated with the observed from the beginning of the present millennium increased migration of cod from eastern Baltic regions to the waters of Bornholm basin, and the distribution of the part of migrants from Bornholm basin to Arkona basin.

Variability of DNA microsatellite loci in populations of Pacific cod Gadus macrocephalus Tilesius (Gadidae)

Despite almost a hundred years of studies on the Pacific cod’s biological and ecological peculiarities, many of them and especially population structure remain poorly understood. The variability of DNA microsatellite loci Gmo3, Gmo34, Gmo35, Pgmo32, and Gmo 19 was analyzed for the cod sampled in different areas of the North Pacific. The cod sampled nearby the Southern Kurils, differed significantly by Gmo3 and Pgmo32 compared to the populations inhabiting the Bering Sea, the Sea of Okhotsk and the coastal waters off Canada. Further, Pacific cod of the three latter populations demonstrated high similarity (I = 0.996) in spite of considerable geographic remoteness of these areas from one another.

Preliminary data on the variability of three microsatellite loci in Pacific Gadus macrocephalus and Atlantic G. morhua cod (Gadidae)

Variability of microsatellite DNA loci Gmo3, Gmo34, and Gmo35 is studied in samples of Pacific cod Gadus macrocephalus and Atlantic cod G. morhua. The results show high values of identity of the samples within the North Pacific basin (0.9766–0.9924) and within the Northeast Atlantic basin (0.9580). Based on the pairwise assessment of genetic differentiation, the FST values are significantly different in all variants between the samples of Pacific and Atlantic cod (FST = 0.5235–0.6719, p < 0.001). Within the basins, the significant differences in the frequencies of main alleles are revealed in the loci Gmo3 and Gmo34 for the samples from the Pacific and Atlantic oceans, respectively.

Data on variation of microsatellite loci in Kildin cod Gadus morhua kildinensis (Gadidae)

Variation of microsatellite loci Gmo8, Gmo-G12, Gmo-G18, Gmo19, PGmo32, Gmo34, and Gmo35 is investigated in Kildin cod Gadus morhua kildinensis. The investigated loci are characterized by a low level of variation: five loci are represented by two-allele systems and three loci are monomorphic. Mean value of heterozygosity calculated by all investigated loci is lower in Kildin cod than in Atlantic Gadus morhua—0.2854 vs. 0.5667.

Variability of Microsatellite Loci of Greenland Cod Gadus ogac Richardson 1836: Comparison with Other Species of Gadus Genus (Gadidae)

Comparative analysis of variability of seven microsatellite loci—Gmo3, Gmo-G12, Gmo-G18, Gmo19, Gmo34, Gmo35 and Pgmo32—was performed for the Greenland cod Gadus ogac, Pacific cod G. macrocephalus, Atlantic cod G. morhua, and White Sea cod G. morhua marisalbi. High genetic identity was observed between the Greenland cod and Pacific cod (I = 0.9520). Pair analysis of genetic differentiation was performed on the studied microsatellite loci according to θ (analogue of FST). The Greenland cod differed significantly from the Pacific, Atlantic, and the White Sea cod; however, the differentiation level varied. The lowest value was observed for the pair Greenland cod-Pacific cod (0.123), and the highest levels were registered for the pairs Greenland cod-Atlantic cod (0.605) and Greenland cod-White Sea cod (0.535).