Huang Kuo-Yang, Chen Yi-Ywan Margaret, Fang Yi-Kai, Cheng Wei-Hung, Cheng Chih-Chieh, Chen Yu-Chuen, Wu Tiffany E, Ku Fu-Man, Chen Shih-Chieh, Lin Rose, Tang Petrus
Graduate Institute of Biomedical Sciences, College of Medicine, Chang Gung University, Kwei-Shan, Taoyuan 333, Taiwan; Molecular Regulation and Bioinformatics Laboratory, Department of Parasitology, College of Medicine, Chang Gung University, Kwei-Shan, Taoyuan 333, Taiwan.
Biochim Biophys Acta. 2014 Jan;1840(1):53-64. doi: 10.1016/j.bbagen.2013.08.008. Epub 2013 Aug 17.
To establish an infection in the vagina, Trichomonas vaginalis must adapt to various environmental cues for survival and further replication. Nutrient competition by lactobacilli, the major normal vaginal flora, is one of the mechanisms to limit the growth of other microorganisms. Additionally, lactobacilli produce H2O2 that can reduce the genital infections caused by other pathogens. Thus, the ability to overcome the metabolic stresses, such as glucose restriction (GR), as well as the oxidative stresses, is critical for T. vaginalis to establish an infection.
To gain insights into the molecular mechanisms of adaptation to GR, we utilized next-generation RNA sequencing (RNA-seq) to quantify the gene expression changes upon GR. Autophagy, a cytoprotective response to starvation, was monitored by using autophagy-specific staining, autophagy inhibition assay, and co-localization of autophagosomes with lysosomes.
We demonstrated that GR promotes the survival of T. vaginalis. Besides, GR-cultivated cells exhibit higher H2O2 resistance. Our RNA-seq data revealed that genes involved in general energy metabolism were downregulated, whereas genes encoding glutamate metabolism-related aminotransferases were strikingly upregulated under GR. Furthermore, autophagy was first identified and characterized in T. vaginalis under GR.
These data suggest that GR induces a metabolic reprogramming, enhancing antioxidant ability and autophagy for cellular homeostasis to maintain survival.
Our work not only led to significant advances in understanding the transcriptional changes in response to GR but also provided possible strategies elicited by GR for T. vaginalis to adapt to the vaginal microenvironment.
阴道毛滴虫要在阴道中建立感染,就必须适应各种环境线索以存活并进一步繁殖。作为主要的正常阴道菌群,乳酸杆菌的营养竞争是限制其他微生物生长的机制之一。此外,乳酸杆菌产生的过氧化氢可减少由其他病原体引起的生殖道感染。因此,克服诸如葡萄糖限制(GR)等代谢应激以及氧化应激的能力对于阴道毛滴虫建立感染至关重要。
为深入了解适应葡萄糖限制的分子机制,我们利用新一代RNA测序(RNA-seq)来量化葡萄糖限制后基因表达的变化。通过使用自噬特异性染色、自噬抑制试验以及自噬体与溶酶体的共定位来监测自噬,这是一种对饥饿的细胞保护反应。
我们证明葡萄糖限制促进了阴道毛滴虫的存活。此外,经葡萄糖限制培养的细胞表现出更高的过氧化氢抗性。我们的RNA-seq数据显示,参与一般能量代谢的基因被下调,而编码谷氨酸代谢相关转氨酶的基因在葡萄糖限制条件下显著上调。此外,首次在阴道毛滴虫中鉴定并表征了葡萄糖限制条件下的自噬。
这些数据表明,葡萄糖限制诱导了代谢重编程,增强了抗氧化能力和自噬以维持细胞内稳态从而保持存活。
我们的工作不仅在理解对葡萄糖限制的转录变化方面取得了重大进展,还为阴道毛滴虫适应阴道微环境提供了葡萄糖限制引发的可能策略。
