Abstract
Amur ide (Leuciscus waleckii), a Cyprinid species, is broadly distributed in Northeast Asia. Different from its freshwater counterparts, the population in Lake Dali Nor has a strong alkalinity tolerance and can adapt to extremely alkali–saline water with bicarbonate over 50 mmol/L. To uncover the genetic basis of its alkaline adaptation, three populations, including one alkali form from Lake Dali Nor (DL), one freshwater form from its adjacent sister Lake Ganggeng Nor (GG), and one freshwater form from its historical origin, namely, the Songhua River (SH), were analyzed using genome resequencing technology. A total of 679.82 Gb clean data and 38,091,163 high-quality single-nucleotide polymorphism (SNP) loci were detected in the three populations. Nucleotide diversity and population structure analysis revealed that the DL and GG populations have lower nucleotide diversities and different genetic structures than those of the SH population. Selective sweeping showed 21 genes involved in osmoregulatory regulation (DLG1, VIPR1, AKT1, and GNAI1), inflammation and immune responses (DLG1, BRINP1, CTSL, TRAF6, AKT1, STAT3, GNAI1, SEC22b, and PSME4b), and cardiorespiratory development (TRAF6, PSME4b, STAT3, AKT1, and COL9A1) to be associated with alkaline adaption of the DL population. Interestingly, selective pressure (CodeML, MEME, and FEL) methods identified two functional codon sites of VIPR1 to be under positive selection in the DL population. The subsequent 3D protein modeling confirmed that these selected sites will incur changes in protein structure and function in the DL population. In brief, this study provides molecular evidence of population divergence and alkaline adaptation, which will be very useful for revealing the genetic basis of alkaline adaptation in Amur ide.
Highlights
Amur ide (Leuciscus waleckii) belongs to Cyprinidae and is widely distributed throughout Northeast Asia
These findings suggest that Amur ide individuals dwelling in Lake Dali Nor have evolved unique genetic strategies that differ from their freshwater counterparts to cope with extremely alkaline environments
The Songhua River (SH) population had the largest number of single-nucleotide polymorphism (SNP), and the difference was significant compared to the Dali Nor (DL) (two-tailed t-test, PSNP(SH/DL) = 2.53e−05**) and Ganggeng Nor (GG) (PSNP(SH/GG) = 3.11e−05**) populations; while the two lake forms had no obvious differences in the number of SNPs (PSNP (DL/GG) = 0.74) (Fig. 2a)
Summary
Amur ide (Leuciscus waleckii) belongs to Cyprinidae and is widely distributed throughout Northeast Asia. By combining genome scans with landscape genomic methods, Xu, et al.[9] found several genomic regions associated with alkaline adaptation under selective sweeps when comparing Amur ide in Lake Dali Nor and its ancestral freshwater form in the Amur River, which are candidate genes involved in processes such as ion homeostasis, reactive oxygen species elimination, and urea excretion. These findings suggest that Amur ide individuals dwelling in Lake Dali Nor have evolved unique genetic strategies that differ from their freshwater counterparts to cope with extremely alkaline environments. This study aims to identify target genes or pathways related to alkaline adaptation and provides new insights into the genetic basis of alkaline adaptation of Amur ide
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