Nicolaas C. Gey van Pittius scite author profile

Recent evidence shows that mycobacteria have developed novel and specialized secretion systems for the transport of extracellular proteins across their hydrophobic, and highly impermeable, cell wall. Strikingly, mycobacterial genomes encode up to five of these transport systems. Two of these systems, ESX-1 and ESX-5, are involved in virulence - they both affect the cell-to-cell migration of pathogenic mycobacteria. Here, we discuss this novel secretion pathway and consider variants that are present in various Gram-positive bacteria. Given the unique composition of this secretion system, and its general importance, we propose that, in line with the accepted nomenclature, it should be called type VII secretion.

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PPE and PE_PGRS proteins of Mycobacterium marinum are transported via the type VII secretion system ESX‐5

Abdallah

Verboom

Weerdenburg

et al. 2009

Molecular Microbiology

238

314

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SummaryESX-5 is one of the five type VII secretion systems found in mycobacteria. These secretion systems are also known as ESAT-6-like secretion systems. Here, we have determined the secretome of ESX-5 by a proteomic approach in two different strains of Mycobacterium marinum. Comparison of the secretion profile of wild-type strains and their ESX-5 mutants showed that a number of PE_PGRS and PPE-MPTR proteins are dependent on ESX-5 for transport. The PE and PPE protein families are unique to mycobacteria, are highly expanded in several pathogenic species, such as Mycobacterium tuberculosis and M. marinum, and certain family members are cell surface antigens associated with virulence. Using a monoclonal antibody directed against the PGRS domain we showed that nearly all PE_PGRS proteins that are recognized by this antibody are missing in the supernatant of ESX-5 mutants. In addition to PE_PGRS and PPE proteins, the ESX-5 secretion system is responsible for the secretion of a ESAT-6-like proteins. Together, these data show that ESX-5 is probably a major secretion pathway for mycobacteria and that this system is responsible for the secretion of recently evolved PE_PGRS and PPE proteins.

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Untitled

et al. 2006

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Background: The PE and PPE multigene families of Mycobacterium tuberculosis comprise about 10% of the coding potential of the genome. The function of the proteins encoded by these large gene families remains unknown, although they have been proposed to be involved in antigenic variation and disease pathogenesis. Interestingly, some members of the PE and PPE families are associated with the ESAT-6 (esx) gene cluster regions, which are regions of immunopathogenic importance, and encode a system dedicated to the secretion of members of the potent T-cell antigen ESAT-6 family. This study investigates the duplication characteristics of the PE and PPE gene families and their association with the ESAT-6 gene clusters, using a combination of phylogenetic analyses, DNA hybridization, and comparative genomics, in order to gain insight into their evolutionary history and distribution in the genus Mycobacterium.

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Systematic Genetic Nomenclature for Type VII Secretion Systems

et al. 2009

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A Balancing Act: Efflux/Influx in Mycobacterial Drug Resistance

Louw

Warren

Pittius

et al. 2009

Antimicrob Agents Chemother

218

200

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Effect of household and community interventions on the burden of tuberculosis in southern Africa: the ZAMSTAR community-randomised trial

et al. 2013

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NovelMycobacterium tuberculosisComplex Pathogen,M. mungi

Alexander

Laver²,

Michel³

et al. 2010

Emerg. Infect. Dis.

207

187

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Reinfection and Mixed Infection Cause Changing Mycobacterium tuberculosis Drug-Resistance Patterns

Rie

Victor

Richardson

et al. 2005

Am J Respir Crit Care Med

157

158

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Rationale:Multiple infections with different strains of Mycobacterium tuberculosis may occur in settings where the infection pressure is high. The relevance of mixed infections for the patient, clinician, and control program remains unclear. Objectives: This study aimed to describe reinfection and mixed infection as underlying mechanisms of changing drug-susceptibility patterns in serial sputum cultures. Methods: Serial M. tuberculosis sputum cultures from patients diagnosed with multi-drug-resistant (MDR) tuberculosis were evaluated by phenotypic drug-susceptibility testing and mutation detection methods. Genotypic analysis was done by IS6110 DNA fingerprinting and a novel strain-specific polymerase chain reaction amplification method. Measurements and Main Results: DNA fingerprinting analysis of serial sputum cultures from 48 patients with MDR tuberculosis attributed 10 cases to reinfection and 1 case to mixed infection. In contrast, strain-specific polymerase chain reaction amplification analysis in 9 of the 11 cases demonstrated mixed infection in 5 cases, reinfection in 3 cases, and laboratory contamination in 1 case. Analysis of clinical data suggests that firstline therapy can select for a resistant subpopulation, whereas poor adherence or second-line therapy resulted in the reemergence of the drug-susceptible subpopulations. Conclusions: We have shown that, in some patients with MDR tuberculosis, mixed infection may be responsible for observations attributed to reinfection by DNA fingerprinting. We conclude that treatment and adherence determines which strain is dominant. We hypothesize that treatment with second-line drugs may lead to reemergence of the drug-susceptible strain in patients with mixed infection. Keywords: drug resistance; mixed infections; Mycobacterium tuberculosis; reinfectionTraditionally, infection by Mycobacterium tuberculosis was assumed to be caused by a single strain, and recurrences were believed to be due to reactivation of the strain that caused the (Received in original form March 22, 2005; accepted in final form May 19, 2005) Supported by GlaxoSmithKline Action TB Program for funding the collection of clinical and demographic data, sputum culturing, and DNA fingerprinting; the Harry Crossley Foundation and the National Research Foundation (project 2054201 and the DST/NRF Centre of Excellence for Biomedical TB Research) for funding the development of the polymerase chain reaction-based strain-typing method; and the National Institutes of Health (R21 A155800-01) and the Wellcome Trust (DDS PC3145) for funding the identification of genotypic mechanisms conferring drug resistance.Correspondence and requests for reprints should be addressed to Robin M. Warren, Ph.D.,

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