Oxygen is essential for most life forms.Insufficient oxygen supply can disrupt homeostasis and compromise survival,and hypoxia-induced cardiovascular failure is fatal in many animals,including humans.However,certain s...Oxygen is essential for most life forms.Insufficient oxygen supply can disrupt homeostasis and compromise survival,and hypoxia-induced cardiovascular failure is fatal in many animals,including humans.However,certain species have adapted and evolved to cope with hypoxic environments and are therefore good models for studying the regulatory mechanisms underlying responses to hypoxia.Here,we explored the physiological and molecular responses of the cardiovascular system in two closely related hypoxiaadapted species with different life histories,namely,Qinghai voles(Neodon fuscus)and Brandt’s voles(Lasiopodomys brandtii),under hypoxic(10%O_(2) for 48 h)and normoxic(20.9%O_(2) for 48 h)exposure.Kunming mice(Mus musculus)were used for comparison.Qinghai voles live in plateau areas under hypoxic conditions,whereas Brandt’s voles only experience periodic hypoxia.Histological and hematological analyses indicated a strong tolerance to hypoxia in both species,but significant cardiac tissue damage and increased blood circulation resistance in mice exposed to hypoxia.Comparative transcriptome analysis revealed enhanced oxygen transport efficiency as a coping mechanism against hypoxia in both N.fuscus and L.brandtii,but with some differences.Specifically,N.fuscus showed upregulated expression of genes related to accelerated cardiac contraction and angiogenesis,whereas L.brandtii showed significant up-regulation of erythropoiesis-related genes.Synchronized upregulation of hemoglobin synthesis-related genes was observed in both species.In addition,differences in cardiometabolic strategies against hypoxia were observed in the rodents.Notably,M.musculus relied on adenosine triphosphate(ATP)generation via fatty acid oxidation,whereas N.fuscus shifted energy production to glucose oxidation under hypoxic conditions and L.brandtii employed a conservative strategy involving down-regulation of fatty acid and glucose oxidation and a bradycardia phenotype.In conclusion,the cardiovascular systems of N.fuscus and L.brandtii have evolved different adaptation strategies to enhance oxygen transport capacity and conserve energy under hypoxia.Our findings suggest that the coping mechanisms underlying hypoxia tolerance in these closely related species are context dependent.展开更多
Background:Gut microbiota exert an immense effect on host health and host environmental adaptation.Furthermore,the composition and structure of gut microbiota are determined by the environment and host genetic factors...Background:Gut microbiota exert an immense effect on host health and host environmental adaptation.Furthermore,the composition and structure of gut microbiota are determined by the environment and host genetic factors.However,the relative contribution of the environment and host genetic factors toward shaping the structure of gut microbiota has been poorly understood.Methods:In this study,we characterized the fecal microbial communities of the closely related voles Neodon fuscus,Lasiopodomys brandtii,and L.mandarinus after caged feeding in the laboratory for 6 months,through high-throughput sequencing and bioinformatics analysis.Results:The results of pairwise comparisons of N.fuscus vs.L.brandtii and L.mandarinus vs.L.brandtii revealed significant differences in bacterial diversity and composition after domestication.While 991 same operational taxonomic units(OTUs)were shared in three voles,there were 362,291,and 303 species-specific OTUs in N.fuscus,L.brandtii,and L.mandarinus,respectively.The relative abundances of Proteobacteria and Prevotella,which are reported to be enriched in high-altitude populations,were significantly higher in high-altitude N.fuscus than in low-altitude L.brandtii after domestication.Firmicutes,which produce various digestive enzymes for energy metabolism,and Spirochaetes,which can degrade cellulose,were found in higher abundance in subterranean L.mandarinus than that in L.brandtii which dwells on the earth surface.Conclusion:Our findings showed that some components of gut microbiota still maintained dominance even when different host species are reared under the same environmental conditions,suggesting that these bacteria are substantially influenced by host factors.展开更多
Background:Echinococcus multilocularis causes alveolar echinococcosis(AE)and is widely prevalent in Qinghai Province,China,where a number of different species have been identified as hosts.However,limited information ...Background:Echinococcus multilocularis causes alveolar echinococcosis(AE)and is widely prevalent in Qinghai Province,China,where a number of different species have been identified as hosts.However,limited information is available on the Qinghai vole(Lasiopodomys fuscus),which is hyper endemic to Qinghai Province and may represent a potential intermediate host of E.multilocularis.Thus,L.fuscus could contribute to the endemicity of AE in the area.Methods:Fifty Qinghai voles were captured from Jigzhi County in Qinghai Province for the clinical identification of E.multilocularis infection via anatomical examination.Hydatid fluid was collected from vesicles of the livers in suspected voles and subjected to a microscopic examination and PCR assay based on the barcoding gene of cox 1.PCR-amplified segments were sequenced for a phylogenetic analysis.E.multilocularis-infected Qinghai voles were morphologically identified and subjected to a phylogenetic analysis to confirm their identities.Results:Seventeen of the 50 Qinghai voles had E.multilocularis-infection-like vesicles in their livers.Eleven out of the 17 Qinghai voles presented E.multilocularis infection,which was detected by PCR and sequencing.The phylogenetic analysis showed that all 11 positive samples belonged to the E.multilocularis Asian genotype.A morphological identification and phylogenetic analysis of the E.multilocularis-infected Qinghai voles confirmed that all captured animals were L.fuscus.Conclusions:L.fuscus can be infected with E.multilocularis and plays a potential role in the life cycle and epidemiology of E.multilocularis in the Qinghai-Tibetan Plateau of China.展开更多
基金supported by the National Natural Science Foundation of China(U2004152)Zhongyuan Science and Technology Innovation Leading Talent Project(224200510001)China Postdoctoral Science Foundation(2020M672264)。
文摘Oxygen is essential for most life forms.Insufficient oxygen supply can disrupt homeostasis and compromise survival,and hypoxia-induced cardiovascular failure is fatal in many animals,including humans.However,certain species have adapted and evolved to cope with hypoxic environments and are therefore good models for studying the regulatory mechanisms underlying responses to hypoxia.Here,we explored the physiological and molecular responses of the cardiovascular system in two closely related hypoxiaadapted species with different life histories,namely,Qinghai voles(Neodon fuscus)and Brandt’s voles(Lasiopodomys brandtii),under hypoxic(10%O_(2) for 48 h)and normoxic(20.9%O_(2) for 48 h)exposure.Kunming mice(Mus musculus)were used for comparison.Qinghai voles live in plateau areas under hypoxic conditions,whereas Brandt’s voles only experience periodic hypoxia.Histological and hematological analyses indicated a strong tolerance to hypoxia in both species,but significant cardiac tissue damage and increased blood circulation resistance in mice exposed to hypoxia.Comparative transcriptome analysis revealed enhanced oxygen transport efficiency as a coping mechanism against hypoxia in both N.fuscus and L.brandtii,but with some differences.Specifically,N.fuscus showed upregulated expression of genes related to accelerated cardiac contraction and angiogenesis,whereas L.brandtii showed significant up-regulation of erythropoiesis-related genes.Synchronized upregulation of hemoglobin synthesis-related genes was observed in both species.In addition,differences in cardiometabolic strategies against hypoxia were observed in the rodents.Notably,M.musculus relied on adenosine triphosphate(ATP)generation via fatty acid oxidation,whereas N.fuscus shifted energy production to glucose oxidation under hypoxic conditions and L.brandtii employed a conservative strategy involving down-regulation of fatty acid and glucose oxidation and a bradycardia phenotype.In conclusion,the cardiovascular systems of N.fuscus and L.brandtii have evolved different adaptation strategies to enhance oxygen transport capacity and conserve energy under hypoxia.Our findings suggest that the coping mechanisms underlying hypoxia tolerance in these closely related species are context dependent.
基金National Natural Science Foundation of ChinaGrant/Award Number:U2004152+3 种基金China Postdoctoral Science FoundationGrant/Award Number:2020M672264Zhongyuan Science and Technology Innovation Leading Talent ProjectGrant/Award Number:224200510001。
文摘Background:Gut microbiota exert an immense effect on host health and host environmental adaptation.Furthermore,the composition and structure of gut microbiota are determined by the environment and host genetic factors.However,the relative contribution of the environment and host genetic factors toward shaping the structure of gut microbiota has been poorly understood.Methods:In this study,we characterized the fecal microbial communities of the closely related voles Neodon fuscus,Lasiopodomys brandtii,and L.mandarinus after caged feeding in the laboratory for 6 months,through high-throughput sequencing and bioinformatics analysis.Results:The results of pairwise comparisons of N.fuscus vs.L.brandtii and L.mandarinus vs.L.brandtii revealed significant differences in bacterial diversity and composition after domestication.While 991 same operational taxonomic units(OTUs)were shared in three voles,there were 362,291,and 303 species-specific OTUs in N.fuscus,L.brandtii,and L.mandarinus,respectively.The relative abundances of Proteobacteria and Prevotella,which are reported to be enriched in high-altitude populations,were significantly higher in high-altitude N.fuscus than in low-altitude L.brandtii after domestication.Firmicutes,which produce various digestive enzymes for energy metabolism,and Spirochaetes,which can degrade cellulose,were found in higher abundance in subterranean L.mandarinus than that in L.brandtii which dwells on the earth surface.Conclusion:Our findings showed that some components of gut microbiota still maintained dominance even when different host species are reared under the same environmental conditions,suggesting that these bacteria are substantially influenced by host factors.
基金Our research was supported by the“Basic Research Project of the Qinghai Science and Technology Department”(2016-ZJ-791)the“International Cooperation Project of the Qinghai Science and Technology Department”(2015-HZ-809).
文摘Background:Echinococcus multilocularis causes alveolar echinococcosis(AE)and is widely prevalent in Qinghai Province,China,where a number of different species have been identified as hosts.However,limited information is available on the Qinghai vole(Lasiopodomys fuscus),which is hyper endemic to Qinghai Province and may represent a potential intermediate host of E.multilocularis.Thus,L.fuscus could contribute to the endemicity of AE in the area.Methods:Fifty Qinghai voles were captured from Jigzhi County in Qinghai Province for the clinical identification of E.multilocularis infection via anatomical examination.Hydatid fluid was collected from vesicles of the livers in suspected voles and subjected to a microscopic examination and PCR assay based on the barcoding gene of cox 1.PCR-amplified segments were sequenced for a phylogenetic analysis.E.multilocularis-infected Qinghai voles were morphologically identified and subjected to a phylogenetic analysis to confirm their identities.Results:Seventeen of the 50 Qinghai voles had E.multilocularis-infection-like vesicles in their livers.Eleven out of the 17 Qinghai voles presented E.multilocularis infection,which was detected by PCR and sequencing.The phylogenetic analysis showed that all 11 positive samples belonged to the E.multilocularis Asian genotype.A morphological identification and phylogenetic analysis of the E.multilocularis-infected Qinghai voles confirmed that all captured animals were L.fuscus.Conclusions:L.fuscus can be infected with E.multilocularis and plays a potential role in the life cycle and epidemiology of E.multilocularis in the Qinghai-Tibetan Plateau of China.
