Burgess Joshua W, Kottom Theodore J, Villegas Leah R, Lamont Jeffrey D, Baden Elizabeth M, Ramirez-Alvarado Marina, Limper Andrew H
Thoracic Disease Research Unit, 8-24 Stabile Building, Mayo Clinic, 200 1st Street SW, Rochester, MN 55905, USA.
Am J Respir Cell Mol Biol. 2009 Dec;41(6):714-21. doi: 10.1165/rcmb.2008-0098OC. Epub 2009 Mar 13.
Pneumocystis organisms are opportunistic fungal pathogens that cause significant pneumonia in immune-compromised hosts. Recent evidence has suggested that Pneumocystis carinii exists as separate mating types, and expresses and regulates proteins that govern meiosis and progression of the life cycle. This study was undertaken to investigate the activity of three life cycle-regulatory proteins in Pneumocystis, including two proteins essential in mating signaling, and a putative meiotic regulator, to determine the conditions under which they are most active. This study used V5/HIS-tagged PCRan1p, PCSte20p, and PCCbk1, purified from Saccharomyces cerevisiae strain, INVSC, as well as an in vitro Escherichia coli protein expression system to determine the optimal expression conditions of each protein in the presence of varying pH, temperature, and metal ions. These studies demonstrate an atypical enzymatic activity in PCRan1p, whereby the kinase was most active in the environmental conditions between 10 and 25 degrees C, compared with a dramatic reduction in activity above 30 degrees C, temperatures typically found within mammalian hosts. Circular dichroism and fluorescence spectroscopy suggest that PCRan1p becomes partially unfolded at 25 degrees C, leading to its most active conformation, whereas continued unfolding as temperature increases results in strongly suppressed activity. These studies suggest that, in vivo, while under conditions within the mammalian lung (typically 37 degrees C), PCRan1p kinase activity is largely suppressed, allowing better conditions for the activation of meiosis, whereas in ex vivo environments, PCRan1p kinase activity increases to arrest progression of the life cycle until conditions become more favorable.
肺孢子菌是机会性真菌病原体,可在免疫功能低下的宿主中引起严重肺炎。最近的证据表明,卡氏肺孢子菌以不同的交配型存在,并表达和调节控制减数分裂和生命周期进程的蛋白质。本研究旨在调查肺孢子菌中三种生命周期调节蛋白的活性,包括两种交配信号传导中必需的蛋白和一种假定的减数分裂调节因子,以确定它们最活跃的条件。本研究使用从酿酒酵母菌株INVSC中纯化的V5/HIS标记的PCRan1p、PCSte20p和PCCbk1,以及体外大肠杆菌蛋白表达系统,来确定每种蛋白在不同pH、温度和金属离子存在下的最佳表达条件。这些研究证明了PCRan1p具有非典型的酶活性,与在哺乳动物宿主中通常发现的高于30摄氏度时活性急剧降低相比,该激酶在10至25摄氏度的环境条件下最活跃。圆二色性和荧光光谱表明,PCRan1p在25摄氏度时会部分展开,从而导致其最活跃的构象,而随着温度升高持续展开会导致活性强烈抑制。这些研究表明,在体内,在哺乳动物肺内的条件下(通常为37摄氏度),PCRan1p激酶活性在很大程度上受到抑制,从而为减数分裂的激活提供了更好的条件,而在体外环境中,PCRan1p激酶活性增加以阻止生命周期的进程,直到条件变得更有利。