AI Article Synopsis
- There's a new type of tuberculosis called "MKR superspreader" that spreads quickly and is hard to treat because it's resistant to many drugs.
- In experiments, scientists found that this MKR strain grows faster in immune cells (macrophages) than a standard strain.
- They discovered that certain genes in these immune cells react differently to the MKR strain, which could help find new ways to fight this tough infection.
Article Abstract
The upsurge of multidrug-resistant infections has rendered tuberculosis the principal cause of death among infectious diseases. A clonal outbreak multidrug-resistant triggering strain of was identified in Kanchanaburi Province, labelled "MKR superspreader," which was found to subsequently spread to other regions, as revealed by prior epidemiological reports in Thailand. Herein, we showed that the MKR displayed a higher growth rate upon infection into host macrophages in comparison with the H37Rv reference strain. To further elucidate MKR's biology, we utilized RNA-Seq and differential gene expression analyses to identify host factors involved in the intracellular viability of the MKR. A set of host genes function in the cellular response to lipid pathway was found to be uniquely up-regulated in host macrophages infected with the MKR, but not those infected with H37Rv. Within this set of genes, the IL-36 cytokines which regulate host cell cholesterol metabolism and resistance against mycobacteria attracted our interest, as our previous study revealed that the MKR elevated genes associated with cholesterol breakdown during its growth inside host macrophages. Indeed, when comparing macrophages infected with the MKR to H37Rv-infected cells, our RNA-Seq data showed that the expression ratio of , the negative regulator of the IL-36 pathway, to that of was greater in macrophages infected with the MKR. Furthermore, the MKR's intracellular survival and increased intracellular cholesterol level in the MKR-infected macrophages were diminished with decreased expression. Overall, our results indicated that could serve as a new target against this emerging multidrug-resistant strain.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9578452 | PMC |
| http://dx.doi.org/10.1080/21505594.2022.2135268 | DOI Listing |
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