Puthayalai Treerat scite author profile

Burkholderia pseudomallei is the causative agent of melioidosis, a fatal infectious disease endemic in tropical regions worldwide, and especially prevalent in southeast Asia and northern Australia. This intracellular pathogen can escape from phagosomes into the host cytoplasm, where it replicates and infects adjacent cells. We previously demonstrated that, in response to B. pseudomallei infection of macrophage cell line RAW 264.7, a subset of bacteria co-localized with the autophagy marker protein, microtubule-associated protein light chain 3 (LC3), implicating autophagy in host cell defence against infection. Recent reports have suggested that LC3 can be recruited to both phagosomes and autophagosomes, thereby raising questions regarding the identity of the LC3-positive compartments in which invading bacteria reside and the mechanism of the autophagic response to B. pseudomallei infection. Electron microscopy analysis of infected cells demonstrated that the invading bacteria were either free in the cytosol, or sequestered in single-membrane phagosomes rather than double-membrane autophagosomes, suggesting that LC3 is recruited to B. pseudomallei-containing phagosomes. Partial or complete loss of function of type III secretion system cluster 3 (TTSS3) in mutants lacking the BopA (effector) or BipD (translocator) proteins respectively, resulted in delayed or no escape from phagosomes. Consistent with these observations, bopA and bipD mutants both showed a higher level of co-localization with LC3 and the lysosomal marker LAMP1, and impaired survival in RAW264.7 cells, suggesting enhanced killing in phagolysosomes. We conclude that LC3 recruitment to phagosomes stimulates killing of B. pseudomallei trapped in phagosomes. Furthermore, BopA plays an important role in efficient escape of B. pseudomallei from phagosomes.

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S100A8/A9 regulates CD11b expression and neutrophil recruitment during chronic tuberculosis

Scott¹,

Swanson²,

Al-Hammadi³

et al. 2020

119

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Novel role for IL-22 in protection during chronic Mycobacterium tuberculosis HN878 infection

et al. 2017

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Approximately 2 billion people are infected with Mycobacterium tuberculosis (Mtb), resulting in 1.4 million deaths every year. Among Mtb-infected individuals, clinical isolates belonging to the W-Beijing lineage are increasingly prevalent, associated with drug resistance, and cause severe disease immunopathology in animal models. Therefore, it is exceedingly important to identify the immune mechanisms that mediate protection against rapidly emerging Mtb strains, such as W-Beijing lineage. IL-22 is a member of the IL-10 family of cytokines with both protective and pathological functions at mucosal surfaces. Thus far, collective data show that IL-22 deficient mice are not more susceptible to aerosolized infection with less virulent Mtb strains. Thus, in this study we addressed the functional role for the IL-22 pathway in immunity to emerging Mtb isolates, using W-Beijing lineage member, Mtb HN878 as a prototype. We show that Mtb HN878 stimulates IL-22 production in TLR2 dependent manner and IL-22 mediates protective immunity during chronic stages of Mtb HN878 infection in mice. Interestingly, IL-22-dependent pathways in both epithelial cells and macrophages mediate protective mechanisms for Mtb HN878 control. Thus, our results project a new protective role for IL-22 in emerging Mtb infections.

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Synergism between Corynebacterium and Streptococcus sanguinis reveals new interactions between oral commensals

Treerat

Redanz

Giacaman

et al. 2020

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The oral microbiome engages in a diverse array of highly sophisticated ecological interactions that are crucial for maintaining symbiosis with the host. Streptococci and corynebacteria are among the most abundant oral commensals and their interactions are critical for normal biofilm development. In this study, we discovered that Streptococcus sanguinis specifically responds to the presence of Corynebacterium durum by dramatically altering its chain morphology and improving its overall fitness. By employing gas chromatography-mass spectrometry (GC-MS) analysis, specific fatty acids were identified in C. durum supernatants that are responsible for the observed effect. Membrane vesicles (MVs) containing these fatty acids were isolated from C. durum supernatants and were able to replicate the chain morphology phenotype in S. sanguinis, suggesting MV as a mediator of interspecies interactions. Furthermore, S. sanguinis responds to C. durum lipids by decreasing the expression of key FASII genes involved in fatty acid synthesis. Several of these genes are also essential for the chain elongation phenotype, which implicates a regulatory connection between lipid metabolism and chain elongation. In addition, C. durum was found to affect the growth, cell aggregation, and phagocytosis of S. sanguinis, revealing a complex association of these species that likely supports oral commensal colonization and survival.

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Role for the Burkholderia pseudomallei Type Three Secretion System Cluster 1 bpscN Gene in Virulence

et al. 2011

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Burkholderia pseudomallei, the causal agent of melioidosis, employs a number of virulence factors during its infection of mammalian cells. One such factor is the type three secretion system (TTSS), which is proposed to mediate the transport and secretion of bacterial effector molecules directly into host cells. The B. pseudomallei genome contains three TTSS gene clusters (designated TTSS1, TTSS2, and TTSS3). Previous research has indicated that neither TTSS1 nor TTSS2 is involved in B. pseudomallei virulence in a hamster infection model. We have characterized a B. pseudomallei mutant lacking expression of the predicted TTSS1 ATPase encoded by bpscN. This mutant was significantly attenuated for virulence in a respiratory melioidosis mouse model of infection. In addition, analyses in vitro showed diminished survival and replication in RAW264.7 cells and an increased level of colocalization with the autophagy marker protein LC3 but an unhindered ability to escape from phagosomes. Taken together, these data provide evidence that the TTSS1 bpscN gene product plays an important role in the intracellular survival of B. pseudomallei and the pathogenesis of murine infection.Burkholderia pseudomallei, the causal agent of melioidosis, is endemic in southeastern Asia and northern Australia (3), with recently diagnosed sporadic cases in southeastern Africa (1), the Americas, New Caledonia, and Mauritius (4). B. pseudomallei infection can present with acute or chronic clinical manifestations, including septic shock, pulmonary infections, benign pulmonitis, pneumonia (21), prostatic abscesses, cerebral abscesses, meningoencephalitis, encephalomyelitis, suppurative parotitis, and conjunctival ulcers (10).Several B. pseudomallei virulence factors have been identified, including the capsule, pili, flagella, lipopolysaccharide, quorum-sensing molecules, and type six and type three secretory systems (6). The type three secretion system (TTSS) is one of six types of secretion systems identified in bacteria and mediates the secretion of effector molecules directly into host cells (24). Structurally, TTSS consist of a membrane-spanning needle which employs hydrophilic and hydrophobic translocators to deliver bacterial effectors directly into the host cell cytoplasm (16). The current view is that the hydrophilic translocators assist the integration of the hydrophobic translocators into the host cell membrane, forming a pore complex (16). It is hypothesized that the initial contact of the needle tip with the host cell membrane triggers the TTSS to secrete effector molecules (16). B. pseudomallei has been shown to assemble a syringe-like TTSS structure, which is proposed to inject critical virulence effectors into the host cell cytoplasm (17).B. pseudomallei has three TTSS gene clusters (designated TTSS1, TTSS2, and TTSS3), and each of these clusters is present on the small chromosome (20). The TTSS1 gene cluster, which was first reported in 1999 by Winstanley et al. (25), shows homology to a TTSS in the plant pathogen Ralstonia solanace...

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