Large-scale chromosomal changes and associated fitness consequences in pathogenic fungi

被引:23
作者
Forche A. [1 ]
机构
[1] Department of Biology, Bowdoin College, 6500 College Station, Brunswick
来源
Current Fungal Infection Reports | 2014年 / 8卷 / 2期
关键词
Adaptation; Aneuploidy; Candida; Cryptococcus; Fitness; Fluconazole resistance; Fungal pathogens; Genome plasticity; Loss of heterozygosity;
D O I
10.1007/s12281-014-0181-2
中图分类号
学科分类号
摘要
Pathogenic fungi encounter many different host environments to which they must adapt rapidly to ensure growth and survival. They also must be able to cope with alterations in established niches during long-term persistence in the host. Many eukaryotic pathogens have evolved a highly plastic genome, and large-scale chromosomal changes including aneuploidy, and loss of heterozygosity (LOH) can arise under various in vitro and in vivo stresses. Both aneuploidy and LOH can arise quickly during a single cell cycle, and it is hypothesized that they provide a rapid, albeit imprecise, solution to adaptation to stress until better and more refined solutions can be acquired by the organism. While LOH, with the extreme case of haploidization in Candida albicans, can purge the genome from recessive lethal alleles and/or generate recombinant progeny with increased fitness, aneuploidy, in the absence or rarity of meiosis, can serve as a non-Mendelian mechanism for generating genomic variation. © Springer Science+Business Media 2014.
引用
收藏
页码:163 / 170
页数:7
相关论文
共 98 条
[1]  
Hube B., Extracellular proteinases of human pathogenic fungi, Contrib Microbiol, 5, pp. 126-137, (2000)
[2]  
Casadevall A., Amoeba provide insight into the origin of virulence in pathogenic fungi, Adv Exp Med Biol, 710, pp. 1-10, (2012)
[3]  
Waechtler B., Wilson D., Haedicke K., Dalle F., Hube B., From attachment to damage: Defined genes of Candida albicans mediate adhesion, invasion and damage during interaction with oral epithelial cells, PLoS One, 6, (2011)
[4]  
Brown A.J.P., Budge S., Kaloriti D., Tillmann A., Jacobsen M.D., Yin Z., Et al., Stress adaptation in a pathogenic fungus, J Exp Biol, 217, pp. 144-155, (2014)
[5]  
Noble S.M., Candida albicans specializations for iron homeostasis: From commensalism to virulence, Curr Opin Microbiol, 16, pp. 708-715, (2013)
[6]  
Hube B., Monod M., Schofield D.A., Brown A.J.P., Gow N.A.R., Expression of seven members of the gene family encoding secretory aspartyl proteinases in Candida albicans, Molecular Microbiology, 14, 1, pp. 87-99, (1994)
[7]  
Fradin C., Kretschmar M., Nichterlein T., Gaillardin C., D'Enfert C., Hube B., Stage-specific gene expression of Candida albicans in human blood, Molecular Microbiology, 47, 6, pp. 1523-1543, (2003)
[8]  
Setiadi E.R., Doedt T., Cottier F., Noffz C., Ernst J.F., Transcriptional Response of Candida albicans to Hypoxia: Linkage of Oxygen Sensing and Efg1p-regulatory Networks, Journal of Molecular Biology, 361, 3, pp. 399-411, (2006)
[9]  
Lorenz M.C., Bender J.A., Fink G.R., Transcriptional response of Candida albicans upon internalization by macrophages, Eukaryotic Cell, 3, 5, pp. 1076-1087, (2004)
[10]  
Upadhya R., Campbell L.T., Donlin M.J., Aurora R., Lodge J.K., Global transcriptome profile of Cryptococcus neoformans during exposure to hydrogen peroxide induced oxidative stress, PLoS One, 8, (2013)
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