Panepinto John, Liu Lide, Ramos Jeanie, Zhu Xudong, Valyi-Nagy Tibor, Eksi Saliha, Fu Jianmin, Jaffe H Ari, Wickes Brian, Williamson Peter R
Section of Infectious Diseases, Department of Medicine, University of Illinois at Chicago College of Medicine, Chicago, Illinois 60612, USA.
J Clin Invest. 2005 Mar;115(3):632-41. doi: 10.1172/JCI23048.
The study of fungal regulatory networks is essential to the understanding of how these pathogens respond to host environmental signals with effective virulence-associated traits. In this study, a virulence-associated DEAD-box RNA helicase-encoding gene (VAD1) was isolated from a mutant defective in the virulence factor laccase. A Deltavad1 mutant exhibited a profound reduction in virulence in a mouse model that was restored after reconstitution with WT VAD1. Loss of VAD1 resulted in upregulation of NOT1, a gene encoding a global repressor of transcription. NOT1 was found to act as an intermediary transcriptional repressor of laccase. Vad1 was located within macromolecular complexes that formed cytoplasmic granular bodies in mature cells and during infection of mouse brain. In addition, VAD1 was shown by in situ hybridization to be expressed in the brain of an AIDS patient coinfected with C. neoformans. To understand the role of VAD1 in virulence, a functional genomics approach was used to identify 3 additional virulence determinants dependent on VAD1: PCK1, TUF1, and MPF3, involved in gluconeogenesis, mitochondrial protein synthesis, and cell wall integrity, respectively. These data show that fungal virulence-associated genes are coordinately regulated and that an analysis of such transcriptomes allows for the identification of important new genes involved in the normal growth and virulence of fungal pathogens.
对真菌调控网络的研究对于理解这些病原体如何通过有效的毒力相关性状来响应宿主环境信号至关重要。在本研究中,从毒力因子漆酶缺陷的突变体中分离出一个与毒力相关的编码DEAD盒RNA解旋酶的基因(VAD1)。Δvad1突变体在小鼠模型中的毒力显著降低,在用野生型VAD1重构后得以恢复。VAD1的缺失导致NOT1上调,NOT1是一个编码转录全局阻遏物的基因。发现NOT1作为漆酶的中间转录阻遏物发挥作用。Vad1位于在成熟细胞以及感染小鼠脑期间形成细胞质颗粒体的大分子复合物中。此外,原位杂交显示VAD1在合并感染新型隐球菌的艾滋病患者的脑中表达。为了了解VAD1在毒力中的作用,采用功能基因组学方法鉴定了另外3个依赖于VAD1的毒力决定因素:PCK1、TUF1和MPF3,它们分别参与糖异生、线粒体蛋白质合成和细胞壁完整性。这些数据表明真菌毒力相关基因是协同调控的,并且对这种转录组的分析能够鉴定参与真菌病原体正常生长和毒力的重要新基因。