ABSTRACT
As the main carrier of oxygen delivery in the blood circulation system, hemoglobin (Hb) plays a key role in the adaptation of animals to high altitude hypoxia.In this paper, we combined analysis of genome, transcriptome, molecular evolution, homology modeling and molecular dynamics simulation, and explored the molecular mechanisms of increased blood oxygen affinity of Pseudopodoces humilis.Our results showed that the prenatal expressed p gene was highly expressed in the adult Pseudopodoces humilis (RPKM = 32.22) compared to Parus major (RPKM = 0), and this may result in the presence of two additional p-type Hbs with high oxygen affinity in the blood of P.humilis, i.e.(al>p)2 and (aAp)2.The PA25G-A and pA55L-I mutations may increase the van der Waals force between the B and D helices, which might eventually make the entire Pv subunit more compact and finally reduce the number of hydrogen bonds between a dimers, hence the transition from T state to R state is prone to occur.The two mutations of (3a43A-S and pA44S-N could change the conformation and polarity of the heme pocket opening, thus making the solution easier to flow into/out of the heme pocket and therefore facilitating the gas exchange.The pA90E-K mutation in P.humilis has undergone strong positive selection, which could increase the basicity of pA-type Hb, thereby offsetting the decrease in Hb-02 affinity caused by the Bohr effect.In addition, we also found that aA44P-S and pA43A-S mutations may increase the hydrophilicity of otA and pv type Hbs, which is beneficial to the accumulation of Hb to a higher concentration in red blood cells.Collectively, the prenatal Hb genes highly expressed in the adult together with the genetic based changes in intrinsic 0, affinity and physicochemical property of aA and pA Hb could be the main causes for the increase in blood oxygen affinity of P.humilus.
ABSTRACT
Adaptation to high-altitude hypoxia is essential for domestic animals, such as yak, Tibetan chicken, and Tibetan sheep, living on high plateaus, as it ensures efficient oxygen absorption and utilization. Red blood cells are the primary medium for transporting oxygen in the blood. However, little is known about the genetic mechanism of erythrocyte traits. Genome-wide association studies (GWASs) based on single markers or haplotypes have identified potential mechanisms for genetic variation and quantitative traits. To identify loci associated with erythrocyte traits, we performed a GWAS based on the method of the single marker and haplotype in 498 Alpine Merino sheep for six erythrocyte traits: red blood cell count (RBC), hemoglobin (HGB), hematocrit (HCT), mean corpuscular hemoglobin (MCH), mean corpuscular hemoglobin concentration (MCHC), and RBC volume distribution width coefficient of variation (RWD_CV). Forty-two significant single-nucleotide polymorphisms (SNPs) associated with the six erythrocyte traits were detected by means of a single-marker GWAS, and 34 significant haplotypes associated with five erythrocyte traits were detected by means of haplotype analysis. We identified six genes (DHCR24, SPATA9, FLI1, PLCB1, EFNB2, and SH2B3) as potential genes of interest via gene function annotations, location, and expression variation. In particular, FLI1 and PLCB1 were associated with hematopoiesis and erythropoiesis, respectively. These results provide a theoretical basis for analyzing erythrocyte traits and high-altitude hypoxia adaptation in Alpine Merino sheep and will be a useful reference for future studies of plateau-dwelling livestock.
