{"title":"鉴定非复制结核分枝杆菌的分子和微生物学方法。","authors":"Jansy Passiflora Sarathy","doi":"10.1371/journal.ppat.1012595","DOIUrl":null,"url":null,"abstract":"<p><p>Chronic tuberculosis (TB) disease, which requires months-long chemotherapy with multiple antibiotics, is defined by diverse pathological manifestations and bacterial phenotypes. Targeting drug-tolerant bacteria in the host is critical to achieving a faster and durable cure for TB. In order to facilitate this field of research, we need to consider the physiology of persistent MTB during infection, which is often associated with the nonreplicating (NR) state. However, the traditional approach to quantifying bacterial burden through colony enumeration alone only informs on the abundance of live bacilli at the time of sampling, and provides an incomplete picture of the replicative state of the pathogen and the extent to which bacterial replication is balanced by ongoing cell death. Modern approaches to profiling bacterial replication status provide a better understanding of inter- and intra-population dynamics under different culture conditions and in distinct host microenvironments. While some methods use molecular markers of DNA replication and cell division, other approaches take advantage of advances in the field of microfluidics and live-cell microscopy. Considerable effort has been made over the past few decades to develop preclinical in vivo models of TB infection and some are recognized for more closely recapitulating clinical disease pathology than others. Unique lesion compartments presenting different environmental conditions produce significant heterogeneity between Mycobacterium tuberculosis populations within the host. While cellular lesion compartments appear to be more permissive of ongoing bacterial replication, caseous foci are associated with the maintenance of M. tuberculosis in a state of static equilibrium. The accurate identification of nonreplicators and where they hide within the host have significant implications for the way novel chemotherapeutic agents and regimens are designed for persistent infections.</p>","PeriodicalId":48999,"journal":{"name":"PLoS Pathogens","volume":"20 10","pages":"e1012595"},"PeriodicalIF":5.5000,"publicationDate":"2024-10-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11463790/pdf/","citationCount":"0","resultStr":"{\"title\":\"Molecular and microbiological methods for the identification of nonreplicating Mycobacterium tuberculosis.\",\"authors\":\"Jansy Passiflora Sarathy\",\"doi\":\"10.1371/journal.ppat.1012595\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Chronic tuberculosis (TB) disease, which requires months-long chemotherapy with multiple antibiotics, is defined by diverse pathological manifestations and bacterial phenotypes. Targeting drug-tolerant bacteria in the host is critical to achieving a faster and durable cure for TB. In order to facilitate this field of research, we need to consider the physiology of persistent MTB during infection, which is often associated with the nonreplicating (NR) state. However, the traditional approach to quantifying bacterial burden through colony enumeration alone only informs on the abundance of live bacilli at the time of sampling, and provides an incomplete picture of the replicative state of the pathogen and the extent to which bacterial replication is balanced by ongoing cell death. Modern approaches to profiling bacterial replication status provide a better understanding of inter- and intra-population dynamics under different culture conditions and in distinct host microenvironments. While some methods use molecular markers of DNA replication and cell division, other approaches take advantage of advances in the field of microfluidics and live-cell microscopy. Considerable effort has been made over the past few decades to develop preclinical in vivo models of TB infection and some are recognized for more closely recapitulating clinical disease pathology than others. Unique lesion compartments presenting different environmental conditions produce significant heterogeneity between Mycobacterium tuberculosis populations within the host. While cellular lesion compartments appear to be more permissive of ongoing bacterial replication, caseous foci are associated with the maintenance of M. tuberculosis in a state of static equilibrium. 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引用次数: 0
摘要
慢性结核病(TB)需要使用多种抗生素进行长达数月的化疗,其病理表现和细菌表型多种多样。以宿主体内的耐药细菌为靶标,对于更快、更持久地治愈结核病至关重要。为了促进这一领域的研究,我们需要考虑感染期间持续存在的 MTB 的生理学,这通常与非复制(NR)状态有关。然而,仅通过菌落计数来量化细菌负担的传统方法只能提供采样时活杆菌的数量,无法全面反映病原体的复制状态以及细菌复制与持续细胞死亡之间的平衡程度。现代的细菌复制状态分析方法能更好地了解细菌在不同培养条件和不同宿主微环境下的种群间和种群内动态。有些方法使用 DNA 复制和细胞分裂的分子标记,而另一些方法则利用了微流控技术和活细胞显微镜领域的进步。过去几十年来,人们在开发结核病感染的临床前体内模型方面付出了巨大努力,其中一些模型比其他模型更接近临床疾病病理。独特的病变区呈现出不同的环境条件,在宿主体内的结核分枝杆菌种群之间产生显著的异质性。细胞病变区似乎更有利于细菌的持续复制,而病灶则与结核分枝杆菌维持静态平衡状态有关。准确识别非复制者及其在宿主体内的藏身之处,对设计新型化疗药物和治疗方案以治疗顽固性感染具有重要意义。
Molecular and microbiological methods for the identification of nonreplicating Mycobacterium tuberculosis.
Chronic tuberculosis (TB) disease, which requires months-long chemotherapy with multiple antibiotics, is defined by diverse pathological manifestations and bacterial phenotypes. Targeting drug-tolerant bacteria in the host is critical to achieving a faster and durable cure for TB. In order to facilitate this field of research, we need to consider the physiology of persistent MTB during infection, which is often associated with the nonreplicating (NR) state. However, the traditional approach to quantifying bacterial burden through colony enumeration alone only informs on the abundance of live bacilli at the time of sampling, and provides an incomplete picture of the replicative state of the pathogen and the extent to which bacterial replication is balanced by ongoing cell death. Modern approaches to profiling bacterial replication status provide a better understanding of inter- and intra-population dynamics under different culture conditions and in distinct host microenvironments. While some methods use molecular markers of DNA replication and cell division, other approaches take advantage of advances in the field of microfluidics and live-cell microscopy. Considerable effort has been made over the past few decades to develop preclinical in vivo models of TB infection and some are recognized for more closely recapitulating clinical disease pathology than others. Unique lesion compartments presenting different environmental conditions produce significant heterogeneity between Mycobacterium tuberculosis populations within the host. While cellular lesion compartments appear to be more permissive of ongoing bacterial replication, caseous foci are associated with the maintenance of M. tuberculosis in a state of static equilibrium. The accurate identification of nonreplicators and where they hide within the host have significant implications for the way novel chemotherapeutic agents and regimens are designed for persistent infections.
期刊介绍:
Bacteria, fungi, parasites, prions and viruses cause a plethora of diseases that have important medical, agricultural, and economic consequences. Moreover, the study of microbes continues to provide novel insights into such fundamental processes as the molecular basis of cellular and organismal function.