Regulation of solute transport in streptococci by external and internal pH values.
作者信息
Poolman B, Driessen A J, Konings W N
出版信息
Microbiol Rev. 1987 Dec;51(4):498-508. doi: 10.1128/mr.51.4.498-508.1987.
Abstract
摘要
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Regulation of solute transport in streptococci by external and internal pH values.
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5
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6
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