tuberculosis, and tetanic toxoid. Analysis of the specific immune response to mycobacterial antigens in comparison to the NS culture revealed an increase in spot-forming cells both in RR and RR/HIV when cells were stimulated with ML [Fig. 2a,b; RR NS = 135 (30–260) versus ML = 830 (50–5380); P < 0·01; RR/HIV NS = 202·5 (40·0–2560) versus ML = 2260 (50·0–7380); P < 0·05]. The ML p38 peptide

did not modulate the frequency of IFN-γ-producing cells after 48 hr of culture in the PBMCs of the different groups tested. ML peptide p69, which induces a T CD8 response, increased the selleck screening library frequency of IFN-γ-producing cells in the PBMCs of RR patients when compared with NS cells [Fig. 2a,b; RR NS = 140 (50–250) versus Temsirolimus manufacturer p69 = 830 (390–1000); P < 0·05]. However, no significant differences were observed between the PBMCs of RR/HIV stimulated or not with p69 (Fig. 2a,b). In addition, an increase in IFN-γ production in both RR and RR/HIV cells stimulated in vitro with p69 was also observed in contrast to cells in the HC group under the same conditions [Fig. 2b; HC 370 (70–650) versus RR/HIV 830 (250–1960); P < 0·05]. Although M. tuberculosis stimulation induced spots in both RR and RR/HIV cells, there

were no significant differences when compared with unstimulated cells or the HC group. Tetanus toxoid induced an increase in IFN-γ production only in the HC group when compared with NS cells (Fig 2a,b). As expected, PHA stimulation induced a greater number of spots in the HC, RR and RR/HIV groups when compared with the NS cells (Fig. 2a,b). HIV infection induces Erastin in vivo significant immunological impairment, resulting in the increased expression of activation markers such as CD38 and HLA-DR in CD8+ T cells. This increased expression has been associated with particular clinical outcomes.[24] The next step was to evaluate whether ML stimulation modulates the activation of the immune system in RR/HIV co-infected patients. For this purpose, cellular activation parameters were investigated by analysing the surface expression

markers CD25, CD69 and CD38 in both CD4 and CD8 T cells in the PBMC cell culture after stimulation with irradiated ML for 24 hr. As observed in Fig. 3(a), ML increased CD4+ CD69+ T-cell frequencies in the HC and RR groups but not in the RR/HIV patients that presented a greater percentage of CD4+ CD69+ cells in the NS cell culture regardless of ML stimulus [Fig. 3a,b; HC NS = 2·78 (1·57–5·42) versus ML = 9·33 (4·97–17·43), P < 0·01; RR NS = 2·27 (0·57–8·72) versus ML = 10·39 (7·27–18·87), P < 0·01]. Although ML did not affect the expression of CD4+ T-cell activation markers in RR/HIV patients, an increase in CD8+ CD69+ T-cell frequencies in ML-stimulated cells was observed in this group compared with the NS cells [Fig. 4a,b; NS = 13·90 (5·16–22·80) versus ML = 44·49 (21·69–56·90), P < 0·05].