halobacter research
卤菌研究
halobacter strains
卤菌株
halobacter species
卤菌种
halobacterial growth
卤菌生长
halobacter colonies
卤菌菌落
halobacter metabolism
卤菌代谢
halobacter membrane
卤菌膜
halobacter protein
卤菌蛋白
halobacter culture
卤菌培养
halobacter genome
卤菌基因组
halobacter species thrive in high-salt environments such as salt lakes and salt flats.
嗜盐菌物种在盐湖和盐滩等高盐环境中茁壮成长。
researchers study halobacter metabolism to understand how extremophiles survive in harsh conditions.
研究人员研究嗜盐菌的代谢过程,以了解极端微生物如何在恶劣条件下生存。
halobacter cells contain unique purple pigments called bacteriorhodopsin that convert light into energy.
嗜盐菌细胞含有一种独特的紫色色素——细菌视紫红质,可以将光转化为能量。
the halobacter population doubles approximately every five hours under optimal laboratory conditions.
在最佳实验室条件下,嗜盐菌种群大约每五小时翻一番。
scientists culture halobacter in media containing at least twenty percent sodium chloride.
科学家在含有至少百分之二十氯化钠的培养基中培养嗜盐菌。
halobacter adaptation to extreme salinity requires specialized potassium transport proteins.
嗜盐菌适应极端高盐环境需要特殊的钾转运蛋白。
the halobacter membrane maintains structural integrity through unique ether-linked lipids.
嗜盐菌膜通过独特的醚键脂质维持结构完整性。
halobacter survival depends on active ion pumps that prevent cellular dehydration.
嗜盐菌的存活依赖于活跃的离子泵,防止细胞脱水。
researchers extracted halobacter dna to sequence the genome of this ancient organism.
研究人员提取了嗜盐菌的dna,以测序这种古老生物的基因组。
halobacter enzymes remain stable and functional at salt concentrations that would destroy most proteins.
嗜盐菌酶在盐浓度下保持稳定并发挥功能,而这种盐浓度会破坏大多数蛋白质。
recent halobacter research has provided clues about the early evolution of life on our planet.
最近的嗜盐菌研究为地球早期生命的进化提供了线索。
the halobacter colony develops a characteristic reddish-orange color due to carotenoid pigments.
嗜盐菌菌落由于类胡萝卜素色素而呈现出特有的红橙色。
halobacter photosynthesis operates through a different mechanism compared to photosynthetic plants.
嗜盐菌的光合作用机制与光合植物不同。
halobacter research
卤菌研究
halobacter strains
卤菌株
halobacter species
卤菌种
halobacterial growth
卤菌生长
halobacter colonies
卤菌菌落
halobacter metabolism
卤菌代谢
halobacter membrane
卤菌膜
halobacter protein
卤菌蛋白
halobacter culture
卤菌培养
halobacter genome
卤菌基因组
halobacter species thrive in high-salt environments such as salt lakes and salt flats.
嗜盐菌物种在盐湖和盐滩等高盐环境中茁壮成长。
researchers study halobacter metabolism to understand how extremophiles survive in harsh conditions.
研究人员研究嗜盐菌的代谢过程,以了解极端微生物如何在恶劣条件下生存。
halobacter cells contain unique purple pigments called bacteriorhodopsin that convert light into energy.
嗜盐菌细胞含有一种独特的紫色色素——细菌视紫红质,可以将光转化为能量。
the halobacter population doubles approximately every five hours under optimal laboratory conditions.
在最佳实验室条件下,嗜盐菌种群大约每五小时翻一番。
scientists culture halobacter in media containing at least twenty percent sodium chloride.
科学家在含有至少百分之二十氯化钠的培养基中培养嗜盐菌。
halobacter adaptation to extreme salinity requires specialized potassium transport proteins.
嗜盐菌适应极端高盐环境需要特殊的钾转运蛋白。
the halobacter membrane maintains structural integrity through unique ether-linked lipids.
嗜盐菌膜通过独特的醚键脂质维持结构完整性。
halobacter survival depends on active ion pumps that prevent cellular dehydration.
嗜盐菌的存活依赖于活跃的离子泵,防止细胞脱水。
researchers extracted halobacter dna to sequence the genome of this ancient organism.
研究人员提取了嗜盐菌的dna,以测序这种古老生物的基因组。
halobacter enzymes remain stable and functional at salt concentrations that would destroy most proteins.
嗜盐菌酶在盐浓度下保持稳定并发挥功能,而这种盐浓度会破坏大多数蛋白质。
recent halobacter research has provided clues about the early evolution of life on our planet.
最近的嗜盐菌研究为地球早期生命的进化提供了线索。
the halobacter colony develops a characteristic reddish-orange color due to carotenoid pigments.
嗜盐菌菌落由于类胡萝卜素色素而呈现出特有的红橙色。
halobacter photosynthesis operates through a different mechanism compared to photosynthetic plants.
嗜盐菌的光合作用机制与光合植物不同。
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