分枝杆菌噬菌体在结核病诊断、耐药筛选中的应用研究

随着耐药结核分枝杆菌的传播,结核病的防治面临巨大挑战,结核分枝杆菌的快速诊断和耐药性筛选和新型治疗药物的研发是结核病防治的关键。噬菌体生物扩增法是一种经济、快速、易操作且不需要特殊仪器的表型实验技术,最近几年发展很快。本文综述了分枝杆菌噬菌体在结核病的诊断、耐药筛选中应用的最新进展。     

结核分枝杆菌免疫优势抗原研究进展

结核病是当今影响人类健康、流行性最广、病死率最高的感染性疾病之一。结核病的诊断和疫苗的构建成为当前的研究热点,筛选出结核分枝杆菌免疫优势抗原是快速准确的诊断结核病及研制安全有效的疫苗的关键。拟对近年来国内外学者发现的结核分枝杆菌免疫优势抗原的分子生物学特性研究进展进行综述。     

结核病诊断技术新进展

结核病疫情亟需快速、有效的诊断方法,但长久以来其诊断一直依靠传统的结核分枝杆菌抗酸染色涂片和培养技术,并不能满足快速诊断的需要。为解决这个全球性的问题,近年来出现了多种结核病新的诊断技术和方法,如新的影像学检查及计算机辅助技术、显微镜学诊断技术、结核分枝杆菌快速培养技术、免疫学诊断技术,以及结核分枝杆菌特异性核酸扩增技术。本文主要介绍几种最有代表性的技术和方法,其中部分技术已获得世界卫生组织(World Health Organization,WHO)的推荐,部分正在进行大规模临床研究或验证,反映了近年来结核病诊断发展的新方向。     

结核病实验诊断技术

结核病诊断一直是控制结核病疫情的关键,快速准确、敏感特异、简便低廉的诊断方法是目前迫切需要的.从结核分枝杆菌快速诊断噬菌体法、AMPLICOR(R) MTB试验、Gen-Probe分子生物学诊断方法到T-SPOT.TB和QuantiFeron-Gold Test免疫学检测方法,结核病实验诊断方法在不断改进和完善.近年来...     

结核分枝杆菌蛋白抗原的研究进展

结核病当今世界人类致死的主要疾病之一,早期诊断发现病人、选择敏感的抗结核药物进行有效治疗是控制结核病的关键。而临床上对结核病患者检出率低,漏诊率和误诊率高,结果导致结核耐药的情况越来越严重。简便、快速、准确的免疫学检测方法在诊断结核病中起到了重要的作用。本文对用于免疫学检测的蛋白抗原作一综述。     

T SPOT TB技术用于结核的辅助诊断

近年来,我国结核病的发病率有上升趋势,临床上经常会遇到一些症状不典型的结核病和肺外结核病,而目前可用于诊断结核病的方法有限,同时又缺乏快速敏感的实验室技术,为结核病的早期诊断与治疗带来困难.酶联免疫斑点法(enzyme-linked immunospot assay,ELISPOT)技术是一种新型的免疫酶技术,从单细胞水平检测分泌抗体细胞或分泌细胞因子细胞[1].由ELISPOT发展而来的T SPOT TB(结核感染T细胞斑点试验)技术用于检测结核感染后特异性T细胞分泌的γ干扰素(IFN-γ),并据此结果判断是否感染结核.     

耐多药结核分枝杆菌的研究进展

耐多药结核分枝杆菌(Mycobacterium tuberculosis,Mtb)的产生和播散,尤其是泛耐药菌株的出现,已成为新世纪结核病控制的三大难题之一。Mtb耐药机制的研究有助于快速分子诊断工具的发展,且能指导抗结核新药的开发。了解耐多药结核分枝杆菌的耐药机制、分子特征及治疗的研究进展,将为耐多药Mtb的防治提供依据。     

肺外结核病微生物学诊断方法的研究和应用进展

肺外结核病指由结核分枝杆菌（Mycobacterium tuberculosis, MTB）感染所引起的发生在肺部以外器官和部位的结核病。近年来肺外结核的发病率逐渐升高,未能得到早期有效治疗的肺外结核病患者可能并发畸形、截瘫甚至死亡等严重后果。微生物学检测方法对从病原学角度诊断肺外结核病至关重要。基于此,总结了近年来肺外结核病细菌学检查方法、结核分枝杆菌的抗原检测与分子生物学检测等微生物学诊断方法的概况及应用进展,并对这些检测方法的优缺点及适用范围进行了分析、比较,以期为今后肺外结核病病原学诊断的研究提供相关信息。     

结核分枝杆菌潜伏感染诊断方法的新进展

每年有超过8百万人感染结核,其中绝大部分没有发展为活动性结核病,而是表现为潜伏性结核感染。大多数活动性结核病是潜伏感染的结核杆菌重新被激活所致,因此结核潜伏感染者成为结核患者的重要来源。及早诊断和治疗结核潜伏感染者是控制结核传播的最有效手段之一。我们较要综述了目前国内外结核潜伏感染的诊断方法及其新进展。     

基于全基因转录组的结核诊断标识研究

早期诊断是结核患者得到及时治疗的关键,目前结核病诊断手段不足,迫切需要更加快速、简便的诊断方法.本研究分析9例治疗前结核患者、6例结核潜伏感染者、6例健康对照的全基因转录组表达谱,并对结核患者治疗前后表达谱进行随访.结果发现,与健康对照和结核潜伏感染者比较,结核患者有77个高表达、50个低表达的差异表达基因,其中有12个差异表达基因表达量经抗结核治疗后下调;差异表达基因GO分析筛选出9个与炎症反应、免疫应答、趋药性相关的生物学功能通路,KEGG pathway分析发现,1个细胞因子和细胞因子受体相关的信号转导通路,各通路均有趋化因子或者细胞因子参与.应用RT-qPCR方法进行临床扩大样本验证,发现大部分基因RT-qPCR验证结果与基因芯片结果趋势一致,其中HBB等8个基因一致性最好;绘制ROC曲线评价HBB和TNFRSF10C两个基因诊断结核病的效能,AUC均在0.9以上,敏感性和特异性均在95%以上;本研究发现的差异表达基因为结核病研究提供了新的生物学标识,为结核病诊断方法的建立、疗效的监测、发病机制的揭示提供了新依据.     

Genetics-directed drug discovery for combating Mycobacterium tuberculosis infection

Mycobacterium tuberculosis (Mtb), the pathogen of tuberculosis (TB), is one of the most infectious bacteria in the world. The traditional strategy to combat TB involves targeting the pathogen directly; however, the rapid evolution of drug resistance lessens the efficiency of this anti-TB method. Therefore, in recent years, some researchers have turned to an alternative anti-TB strategy, which hinders Mtb infection through targeting host genes. In this work, using a theoretical genetic analysis, we identified 170 Mtb infection-associated genes from human genetic variations related to Mtb infection. Then, the agents targeting these genes were identified to have high potential as anti-TB drugs. In particular, the agents that can target multiple Mtb infection-associated genes are more druggable than the single-target counterparts. These potential anti-TB agents were further screened by gene expression data derived from connectivity map. As a result, some agents were revealed to have high interest for experimental evaluation. This study not only has important implications for anti-TB drug discovery, but also provides inspirations for streamlining the pipeline of modern drug discovery.     

Rifampicin exposure reveals within-host Mycobacterium tuberculosis diversity in patients with delayed culture conversion

Mycobacterium tuberculosis (Mtb) genetic micro-diversity in clinical isolates may underline mycobacterial adaptation to tuberculosis (TB) infection and provide insights to anti-TB treatment response and emergence of resistance. Herein we followed within-host evolution of Mtb clinical isolates in two cohorts of TB patients, either with delayed Mtb culture conversion (> 2 months), or with fast culture conversion (< 2 months). We captured the genetic diversity of Mtb isolates obtained in each patient, by focusing on minor variants detected as unfixed single nucleotide polymorphisms (SNPs). To unmask antibiotic tolerant sub-populations, we exposed these isolates to rifampicin (RIF) prior to whole genome sequencing (WGS) analysis. Thanks to WGS, we detected at least 1 unfixed SNP within the Mtb isolates for 9/15 patients with delayed culture conversion, and non-synonymous (ns) SNPs for 8/15 patients. Furthermore, RIF exposure revealed 9 additional unfixed nsSNP from 6/15 isolates unlinked to drug resistance. By contrast, in the fast culture conversion cohort, RIF exposure only revealed 2 unfixed nsSNP from 2/20 patients. To better understand the dynamics of Mtb micro-diversity, we investigated the variant composition of a persistent Mtb clinical isolate before and after controlled stress experiments mimicking the course of TB disease. A minor variant, featuring a particular mycocerosates profile, became enriched during both RIF exposure and macrophage infection. The variant was associated with drug tolerance and intracellular persistence, consistent with the pharmacological modeling predicting increased risk of treatment failure. A thorough study of such variants not necessarily linked to canonical drug-resistance, but which are prone to promote anti-TB drug tolerance, may be crucial to prevent the subsequent emergence of resistance. Taken together, the present findings support the further exploration of Mtb micro-diversity as a promising tool to detect patients at risk of poorly responding to anti-TB treatment, ultimately allowing improved and personalized TB management.     

Phosphodiesterase 4 inhibition reduces innate immunity and improves isoniazid clearance of Mycobacterium tuberculosis in the lungs of infected mice

Tuberculosis (TB) caused by Mycobacterium tuberculosis (Mtb) is one of the leading infectious disease causes of morbidity and mortality worldwide. Though current antibiotic regimens can cure the disease, treatment requires at least six months of drug therapy. One reason for the long duration of therapy is that the currently available TB drugs were selected for their ability to kill replicating organisms and are less effective against subpopulations of non-replicating persistent bacilli. Evidence from in vitro models of Mtb growth and mouse infection studies suggests that host immunity may provide some of the environmental cues that drive Mtb towards non-replicating persistence. We hypothesized that selective modulation of the host immune response to modify the environmental pressure on the bacilli may result in better bacterial clearance during TB treatment. For this proof of principal study, we compared bacillary clearance from the lungs of Mtb-infected mice treated with the anti-TB drug isoniazid (INH) in the presence and absence of an immunomodulatory phosphodiesterase 4 inhibitor (PDE4i), CC-3052. The effects of CC-3052 on host global gene expression, induction of cytokines, and T cell activation in the lungs of infected mice were evaluated. We show that CC-3052 modulates the innate immune response without causing generalized immune suppression. Immune modulation combined with INH treatment improved bacillary clearance and resulted in smaller granulomas and less lung pathology, compared to treatment with INH alone. This novel strategy of combining anti-TB drugs with an immune modulating molecule, if applied appropriately to patients, may shorten the duration of TB treatment and improve clinical outcome.     

非一线抗结核药物耐药机制及耐药性诊断研究进展

结核病(Tuberculosis, TB)至今仍是世界三大传染疾病之一。2014年,TB导致的死亡人数已经超过HIV。二线抗TB药物是临床治疗耐多药TB(Multidrug-resistant TB, MDR-TB)的主要药物,然而某些MDR-TB患者由于未及时诊断、治疗方案不合理、所处区域医疗条件差等原因,逐渐发展成为广泛耐药TB(Extensively drug-resistant TB, XDR-TB),使治疗更加困难,其死亡率甚至与肺癌接近。目前结核分枝杆菌(Mycobacterium tuberculosis)的耐药性机制研究已经转向非一线药物,如二线、三线和一些新研发的抗TB药物,揭示这些非一线药物的耐药机制对于耐药TB的治疗和新型抗TB药物的研发具有重要意义。本文对目前临床上使用的主要非一线药物的耐药机制研究进行了综述,并对目前常用的TB耐药性诊断方法的优缺点进行了归纳比较。     

Importance of differential identification of <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> strains for understanding differences in their prevalence,treatment efficacy,and vaccine development

Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb), remains a serious global health problem in the 21^st century because of its high mortality. Mtb is an extremely successful human-adapted pathogen that displays a multifactorial ability to control the host immune response and to evade killing by drugs, resulting in the breakdown of BCG vaccine-conferred anti-TB immunity and development of multidrug-resistant (MDR) and extensively drug-resistant (XDR) Mtb. Although genetic components of the genomes of the Mtb complex strains are highly conserved, showing over 99% similarity to other bacterial genera, recently accumulated evidence suggests that the genetic diversity of the Mtb complex strains has implications for treatment outcomes, development of MDR/XDR Mtb, BCG vaccine efficacy, transmissibility, and epidemiological outbreaks. Thus, new insights into the pathophysiological features of the Mtb complex strains are required for development of novel vaccines and for control of MDR/XDR Mtb infection, eventually leading to refinement of treatment regimens and the health care system. Many studies have focused on the differential identification of Mtb complex strains belonging to different lineages because of differences in their virulence and geographical dominance. In this review, we discuss the impact of differing genetic characteristics among Mtb complex strains on vaccine efficacy, treatment outcome, development of MDR/XDR Mtb strains, and epidemiological outbreaks by focusing on the best-adapted human Mtb lineages. We further explore the rationale for differential identification of Mtb strains for more effective control of TB in clinical and laboratory settings by scrutinizing current diagnostic methods.     

结核分枝杆菌抗原蛋白的研究及其应用新进展

结核病(tuberculosis, TB)是由结核分枝杆菌(Mycobacterium tuberculosis, MTB)感染引起的慢性传染病,是仅次于正在暴发的新型冠状病毒肺炎(COVID-19)的第二大单一感染致死病因。COVID-19的大流行对TB的诊断及治疗造成了破坏性的影响,全球实现终结TB目标的进展偏离了轨道。因此,早诊断、早治疗依然是防控TB蔓延的关键。TB精准诊断一直受MTB抗原特异性、检测技术特异性和灵敏度的影响,因此亟需挖掘高特异性新抗原、开发新检测技术。随着蛋白质基因组学(proteogenomics)和质谱技术的快速发展,从临床体液、组织样本中高效、精准靶向检测MTB特异性已知、甚至新抗原的表达,以及监测治疗过程中的抗原表达量的动态变化,是TB诊断及治疗的发展趋势。在MTB标准菌株H37Rv的4 008个注释基因中(NC＿000 962.3, NCBI),国内外报道的已注释抗原虽有140多个,但仅有极少的抗原应用于TB的筛查及辅助诊断,离世界卫生组织(World Health Organization, WHO)的诊断标准尚远。本文通过对MTB已报道抗原以及基...     

Molecular Epidemiology and Clinical Characteristics of Drug-Resistant Mycobacterium tuberculosis in a Tuberculosis Referral Hospital in China

Background

Despite the large number of drug-resistant tuberculosis (TB) cases in China, few studies have comprehensively analyzed the drug resistance-associated gene mutations and genotypes in relation to the clinical characteristics of M. tuberculosis (Mtb) isolates.

Methodology/Principal Findings

We thus analyzed the phenotypic and genotypic drug resistance profiles of 115 Mtb clinical isolates recovered from a tuberculosis referral hospital in Beijing, China. We also performed genotyping by 28 loci MIRU-VNTR analysis. Socio-demographic and clinical data were retrieved from medical records and analyzed. In total, 78 types of mutations (including 42 previously reported and 36 newly identified ones) were identified in 115 Mtb clinical isolates. There was significant correlation between phenotypic and genotypic drug resistance rates for first-line anti-TB drugs (P<0.001). Genotyping revealed 101 MIRU-VNTR types, with 20 isolates (17.4%) being clustered and 95 isolates (82.6%) having unique genotypes. Higher proportion of re-treatment cases was observed among patients with clustered isolates than those with unique MIRU-VNTR genotypes (75.0% vs. 41.1%). Moreover, clinical epidemiological links were identified among patients infected by Mtb strains belonging to the same clusters, suggesting a potential of transmission among patients.

Conclusions/Significance

Our study provided information on novel potential drug resistance-associated mutations in Mtb. In addition, the genotyping data from our study suggested that enforcement of the implementation of genotyping in diagnostic routines would provide important information for better monitor and control of TB transmission.     

Bedaquiline: Fallible Hope Against Drug Resistant Tuberculosis

Tuberculosis (TB) is a deadly bacterial infectious disease caused by intra-cellular pathogen Mycobacterium tuberculosis (Mtb). There were an estimated 1.4 million TB deaths in 2015 and an additional 0.4 million deaths resulting from TB among individuals with HIV. Drug-discovery for its cure is very slow in comparison with the causative organism’s fast pace of mutations conferring drug resistance. Moreover, the field of drug-discovery of anti-TB drugs is constantly being challenged by the drug resistant strains of Mtb. Several molecules/inhibitors are being tested across the pharmaceutical industry and research centres for their suitability as drug candidate. It takes immense effort, high costs and a whole lot of screening to bring a single molecule to the clinics for patient cure. In last 60 years, hundreds of molecules have been patented for their probable use to develop drug for treatment of TB. However, only one drug has been successfully approved that is bedaquiline (1-(6-bromo-2 -methoxy-quinolin-3-yl)-4-dimethylamino-2-naphtalen-1-yl-1-phenyl-butan-2-ol). This is a brief review about bedaquiline (BDQ), the only drug in last 45 years approved for curing drug-resistant pulmonary TB, its development, action mechanism and development of resistance against it.     

Recent updates on drug resistance in Mycobacterium tuberculosis

Tuberculosis (TB) along with acquired immune deficiency syndrome and malaria rank among the top three fatal infectious diseases which pose threat to global public health, especially in middle and low income countries. TB caused by Mycobacterium tuberculosis (Mtb) is an airborne infectious disease and one-third of the world's population gets infected with TB leading to nearly 1·6 million deaths annually. TB drugs are administered in different combinations of four first-line drugs (rifampicin, isoniazid, pyrazinamide and ethambutol) which form the core of treatment regimens in the initial treatment phase of 6–9 months. Several reasons account for the failure of TB therapy such as (i) late diagnosis, (ii) lack of timely and proper administration of effective drugs, (iii) lower availability of less toxic, inexpensive and effective drugs, (iv) long treatment duration, (v) nonadherence to drug regimen and (vi) evolution of drug-resistant TB strains. Drug-resistant TB poses a significant challenge to TB therapy and control programs. In the background of worldwide emergence of 558 000 new TB cases with resistance to rifampicin in the year 2017 and of them, 82% becoming multidrug-resistant TB (MDR-TB), it is essential to continuously update the knowledge on the mechanisms and molecular basis for evolution of Mtb drug resistance. This narrative and traditional review summarizes the progress on the anti-tubercular agents, their mode of action and drug resistance mechanisms in Mtb. The aim of this review is to provide recent updates on drug resistance mechanisms, newly developed/repurposed anti-TB agents in pipeline and international recommendations to manage MDR-TB. It is based on recent literature and WHO guidelines and aims to facilitate better understanding of drug resistance for effective TB therapy and clinical management.