Impact of the GK-1 adjuvant on peritoneal macrophages gene expression and phagocytosis.

PURPOSE: The synthetic peptide GK-1 potentiates protective immunity elicited by the influenza vaccine in mice. In order to understand its adjuvant properties, this study was designed to determine the impact of GK-1 on gene expression and phagocytosis of peritoneal macrophages (PMa). METHODS: Increased gene expression of chemokines involved in leukocyte recruitment and of pro-inflammatory mediators was detected by microarray analysis of control and GK-1 treated PMa macrophages. The expression profile was subsequently confirmed by Multiplex Immunoassays analysis to measure cytokines levels, flow cytometer to describe M1/M2 surface markers and an assay to evaluate their phagocytic activity. RESULTS: Treatment of PMa with GK-1 results in development to the classically activated M1 functional macrophage subpopulation with increased expression of the CCL3 and CXCLO2 chemokines, IL-6 and TNF-α proinflammatory cytokines with a concomitant increase in the levels of NO, accompanied by the expression of modulatory factors that downregulate the inflammatory phenotype. GK-1 treated PMa significantly increased their phagocytic activity. CONCLUSION: GK-1 classical activated with enhanced phagocitic capacity may underlie in the increased specific immunity induced when concomitant administered with other antigens.

Comparison of gene expression profiles between pansensitive and multidrug-resistant strains of Mycobacterium tuberculosis.

Mycobacterium tuberculosis has developed resistance to anti-tuberculosis first-line drugs. Multidrug-resistant strains complicate the control of tuberculosis and have converted it into a worldwide public health problem. Mutational studies of target genes have tried to envisage the resistance in clinical isolates; however, detection of these mutations in some cases is not sufficient to identify drug resistance, suggesting that other mechanisms are involved. Therefore, the identification of new markers of susceptibility or resistance to first-line drugs could contribute (1) to specifically diagnose the type of M. tuberculosis strain and prescribe an appropriate therapy, and (2) to elucidate the mechanisms of resistance in multidrug-resistant strains. In order to identify specific genes related to resistance in M. tuberculosis, we compared the gene expression profiles between the pansensitive H37Rv strain and a clinical CIBIN:UMF:15:99 multidrug-resistant isolate using microarray analysis. Quantitative real-time PCR confirmed that in the clinical multidrug-resistant isolate, the esxG, esxH, rpsA, esxI, and rpmI genes were upregulated, while the lipF, groES, and narG genes were downregulated. The modified genes could be involved in the mechanisms of resistance to first-line drugs in M. tuberculosis and could contribute to increased efficiency in molecular diagnosis approaches of infections with drug-resistant strains.