白色念珠菌主动摄取甘油需要由STL1编码的通透酶。
A permease encoded by STL1 is required for active glycerol uptake by Candida albicans.
作者信息
Kayingo Gerald, Martins António, Andrie Rachael, Neves Luisa, Lucas Cândida, Wong Brian
机构信息
Department of Internal Medicine, Section of Infectious Diseases, Yale University and VA Connecticut Healthcare System, 950 Campbell Avenue (111-I), West Haven, CT 06516, USA.
Centro de Biologia Molecular e Ambiental (CBMA), Departamento de Biologia/Universidade do Minho, Campus de Gualtar, 4710-057, Braga, Portugal.
出版信息
Microbiology (Reading). 2009 May;155(Pt 5):1547-1557. doi: 10.1099/mic.0.023457-0. Epub 2009 Apr 21.
Candida albicans accumulates large amounts of the polyols glycerol and d-arabitol when the cells are exposed to physiological conditions relevant to stress and virulence in animals. Intracellular concentrations of glycerol are determined by rates of glycerol production and catabolism and of glycerol uptake and efflux through the plasma membrane. We and others have studied glycerol production in C. albicans, but glycerol uptake by C. albicans has not been studied. In the present study, we found that [(14)C]glycerol uptake by C. albicans SC5314 was (i) accumulative; (ii) dependent on proton-motive force; (iii) unaffected by carbon source; and (iv) unaffected by large molar excesses of d-arabitol or other polyols. The respective K(m) and V(max) values were 2.1 mM and 460 micromol h(-1) (g dry wt)(-1) in glucose medium and 2.6 mM and 268 micromol h(-1) (g dry wt)(-1) in glycerol medium. To identify the C. albicans glycerol uptake protein(s), we cloned the C. albicans homologues of the Saccharomyces cerevisiae genes GUP1 and STL1, both of which are known to be involved in glycerol transport. When multicopy plasmids encoding C. albicans STL1, C. albicans STL2 and C. albicans GUP1 were introduced into the corresponding S. cerevisiae null mutants, the transformants all acquired the ability to grow on minimal glycerol medium; however, only S. cerevisiae stl1 null mutants transformed with C. albicans STL1 actively took up extracellular [(14)C]glycerol. When both chromosomal alleles of C. albicans STL1 were deleted from C. albicans BWP17, the resulting stl1 null mutants grew poorly on minimal glycerol medium, and their ability to transport [(14)C]glycerol into the cell was markedly reduced. In contrast, deletion of both chromosomal alleles of C. albicans STL2 or of C. albicans GUP1 had no significant effects on [(14)C]glycerol uptake or the ability to grow on minimal glycerol medium. Northern blot analysis indicated that C. albicans STL1 was expressed in both glucose and glycerol media, conditions under which we detected wild-type active glycerol uptake. Furthermore, STL1 was highly expressed in salt-stressed cells; however, the stl1 null mutant was no more sensitive to salt stress than wild-type controls. We also detected high levels of STL2 expression in glycerol-grown cells, even though deletion of this gene did not influence glycerol uptake activity in glycerol-grown cells. We conclude from the results above that a plasma-membrane H(+) symporter encoded by C. albicans STL1 actively transports glycerol into C. albicans cells.
当白色念珠菌细胞暴露于与动物应激和毒力相关的生理条件下时,会积累大量的多元醇甘油和D -阿拉伯糖醇。细胞内甘油的浓度由甘油的产生、分解代谢速率以及通过质膜的甘油摄取和流出速率决定。我们和其他人已经研究了白色念珠菌中甘油的产生,但白色念珠菌对甘油的摄取尚未得到研究。在本研究中,我们发现白色念珠菌SC5314对[¹⁴C]甘油的摄取具有以下特点:(i)是积累性的;(ii)依赖于质子动力势;(iii)不受碳源影响;(iv)不受大量摩尔过量的D -阿拉伯糖醇或其他多元醇的影响。在葡萄糖培养基中,相应的Kₘ和Vₘₐₓ值分别为2.1 mM和460 μmol h⁻¹(g干重)⁻¹,在甘油培养基中分别为2.6 mM和268 μmol h⁻¹(g干重)⁻¹。为了鉴定白色念珠菌的甘油摄取蛋白,我们克隆了酿酒酵母基因GUP1和STL1的白色念珠菌同源物,已知这两个基因都参与甘油转运。当将编码白色念珠菌STL1、白色念珠菌STL2和白色念珠菌GUP1的多拷贝质粒导入相应的酿酒酵母缺失突变体时,转化体都获得了在基本甘油培养基上生长的能力;然而,只有用白色念珠菌STL1转化的酿酒酵母stl1缺失突变体能够主动摄取细胞外的[¹⁴C]甘油。当从白色念珠菌BWP17中删除白色念珠菌STL1的两个染色体等位基因时,产生的stl1缺失突变体在基本甘油培养基上生长不良,并且它们将[¹⁴C]甘油转运到细胞中的能力明显降低。相比之下,删除白色念珠菌STL2或白色念珠菌GUP1的两个染色体等位基因对[¹⁴C]甘油摄取或在基本甘油培养基上生长的能力没有显著影响。Northern印迹分析表明,白色念珠菌STL1在葡萄糖和甘油培养基中均有表达,在这些条件下我们检测到野生型的活性甘油摄取。此外,STL1在盐胁迫细胞中高度表达;然而,stl1缺失突变体对盐胁迫的敏感性并不比野生型对照更高。我们还在甘油生长的细胞中检测到高水平的STL2表达,尽管删除该基因并不影响甘油生长细胞中的甘油摄取活性。根据上述结果,我们得出结论,由白色念珠菌STL1编码的质膜H⁺同向转运体可将甘油主动转运到白色念珠菌细胞中。
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