Tuberculosis
(TB), one of the deadliest infectious diseases, is
caused by Mycobacterium tuberculosis (MTB) and remains a public health
problem nowadays. Conventional MTB DNA
detection methods require sophisticated infrastructure and well-trained
personnel, which leads to increasing complexity and high cost for
diagnostics and limits their wide accessibility in low-resource settings.
To address these issues, we have developed a low-cost photothermal
biosensing method for the quantitative genetic detection of pathogens
such as MTB DNA on a paper hybrid device
using a thermometer. First, DNA capture probes were simply immobilized
on paper through a one-step surface modification process. After DNA
sandwich hybridization, oligonucleotide-functionalized gold nanoparticles
(AuNPs) were introduced on paper and then catalyzed the oxidation
reaction of 3,3′,5,5′-tetramethylbenzidine (TMB). The
produced oxidized TMB, acting as a strong photothermal agent, was
used for the photothermal biosensing of MTB DNA under 808 nm laser irradiation. Under optimal conditions, the
on-chip quantitative detection of the target DNA was readily achieved
using an inexpensive thermometer as a signal recorder. This method
does not require any expensive analytical instrumentation but can
achieve higher sensitivity and there are no color interference issues,
compared to conventional colorimetric methods. The method was further
validated by detecting genomic DNA with high specificity. To the best
of our knowledge, this is the first photothermal biosensing strategy
for quantitative nucleic acid analysis on microfluidics using a thermometer,
which brings fresh inspirations on the development of simple, low-cost,
and miniaturized photothermal diagnostic platforms for quantitative
detection of a variety of diseases at the point of care.
The 6-kDa early secreted antigenic target (ESAT-6; EsxA) of Mycobacterium tuberculosis was first identified as a potent T-cell antigen, and it is now recognized as a pore-forming toxin that is essential for virulence of M. tuberculosis. ESAT-6 is secreted through the ESX-1 secretion system (Type VII) of M. tuberculosis and has been implicated to mediate mycobacterial cytosolic translocation within the host macrophages by rupturing the phagosomal membranes. Recent studies have made significant progresses in understanding of the mechanism of ESAT-6 membrane interaction and its role in M. tuberculosis pathogenesis, but important questions still remain to be answered. Here, we summarize the current progress in study of ESAT-6 membrane interaction and its roles in pathogenesis and discuss some of the key remaining questions for future investigation.
The Mycobacterium tuberculosis virulence factor EsxA and its chaperone EsxB are secreted as a heterodimer (EsxA:B) and are crucial for mycobacterial escape from phagosomes and cytosolic translocation. Current findings support the idea that for EsxA to interact with host membranes, EsxA must dissociate from EsxB at low pH. However, the molecular mechanism by which the EsxA:B heterodimer separates is not clear. In the present study, using liposome-leakage and cytotoxicity assays, LC-MS/MS–based proteomics, and CCF-4 FRET analysis, we obtained evidence that the Nα-acetylation of the Thr-2 residue on EsxA, a post-translational modification that is present in mycobacteria but absent in Escherichia coli, is required for the EsxA:B separation. Substitutions at Thr-2 that precluded Nα-acetylation inhibited the heterodimer separation and hence prevented EsxA from interacting with the host membrane, resulting in attenuated mycobacterial cytosolic translocation and virulence. Molecular dynamics simulations revealed that at low pH, the Nα-acetylated Thr-2 makes direct and frequent “bind-and-release” contacts with EsxB, which generates a force that pulls EsxB away from EsxA. In summary, our findings provide evidence that the Nα-acetylation at Thr-2 of EsxA facilitates dissociation of the EsxA:B heterodimer required for EsxA membrane permeabilization and mycobacterial cytosolic translocation and virulence.
Interaction between bacterial toxins and cellular surface receptors is an important component of the host-pathogen interaction. Anthrax toxin protective antigen (PA) binds to the cell surface receptor, enters the cell through receptor-mediated endocytosis, and forms a pore on the endosomal membrane that translocates toxin enzymes into the cytosol of the host cell. As the major receptor for anthrax toxin in vivo, anthrax toxin receptor 2 (ANTXR2) plays an essential role in anthrax toxin action by providing the toxin with a high-affinity binding anchor on the cell membrane and a path of entry into the host cell. ANTXR2 also acts as a molecular clamp by shifting the pH threshold of PA pore formation to a more acidic pH range, which prevents premature pore formation at neutral pH before the toxin reaches the designated intracellular location. Most recent studies have suggested that the disulfide bond in the immunoglobulin (Ig)-like domain of ANTXR2 plays an essential role in anthrax toxin action. Here we will review the roles of ANTXR2 in anthrax toxin action, with an emphasis on newly updated knowledge.
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