Abstract

It is generally thought that Mycobacterium tuberculosis (Mtb)-specific CD4+ Th1 cells producing IFN-γ are essential for protection against tuberculosis (TB). In some studies, protection has recently been associated with polyfunctional subpopulation of Mtb-specific Th1 cells, i.e., with cells able to simultaneously secrete several type 1 cytokines. However, the role for Mtb-specific Th1 cells and their polyfunctional subpopulations during established TB disease is not fully defined. Pulmonary TB is characterized by a great variability of disease manifestations. To address the role for Mtb-specific Th1 responses during TB, we investigated how Th1 and other immune cells correlated with particular TB manifestations, such as the degree of pulmonary destruction, TB extent, the level of bacteria excretion, clinical disease severity, clinical TB forms, and “Timika X-ray score,” an integrative parameter of pulmonary TB pathology. In comparison with healthy Mtb-exposed controls, TB patients (TBP) did not exhibit deficiency in Mtb-specific cytokine-producing CD4+ cells circulating in the blood and differed by a polyfunctional profile of these cells, which was biased toward the accumulation of bifunctional TNF-α+IFN-γ+IL-2− lymphocytes. Importantly, however, severity of different TB manifestations was not associated with Mtb-specific cytokine-producing cells or their polyfunctional profile. In contrast, several TB manifestations were strongly correlated with leukocyte numbers, the percent or the absolute number of lymphocytes, segmented or band neutrophils. In multiple alternative statistical analyses, band neutrophils appeared as the strongest positive correlate of pulmonary destruction, bacteria excretion, and “Timika X-ray score.” In contrast, clinical TB severity was primarily and inversely correlated with the number of lymphocytes in the blood. The results suggest that: (i) different TB manifestations may be driven by distinct mechanisms; (ii) quantitative parameters and polyfunctional profile of circulating Mtb-specific CD4+ cells play a minor role in determining TB severity; and (iii) general shifts in production/removal of granulocytic and lymphocytic lineages represent an important factor of TB pathogenesis. Mechanisms leading to these shifts and their specific role during TB are yet to be determined but are likely to involve changes in human hematopoietic system.

Highlights

  • Tuberculosis (TB) is currently the deadliest infectious disease of humans [1]

  • Previous studies have indicated that Mycobacterium tuberculosis (Mtb)-specific CD4 T-cell responses differ between TB patients (TBP) and subjects with latent TB infection (LTBI), data on the character of the differences are not uniform [18,19,20,21,22]

  • Tuberculosis patients had higher frequencies of TNF-α+ cells compared to all healthy groups, higher frequencies of IFN-γ+producing cells compared to TB contacts (TBC), and higher frequencies of all Mtb-specific cells compared to HD (Figure 2A)

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Summary

Introduction

Tuberculosis (TB) is currently the deadliest infectious disease of humans [1]. In 2015, there were an estimated 10.4 million new TB cases worldwide and 1.8 million TB deaths including 0.4 million deaths resulting from TB among people living with HIV [1]. Elaboration of new strategies for TB prevention and treatment will likely benefit from deeper understanding of mechanisms that protect host against TB onset and mediate protection or pathology during TB disease. It is generally assumed that host protection against TB relies on IFN-γ-producing CD4+ T cells that are able to activate macrophages for Mycobacterium tuberculosis (Mtb) killing [2, 3]. In several experimental models, the levels of Th1/IFN-γ responses measured following vaccination or CD4+ T-cell depletion did not correlate with a degree of protection evaluated as Mtb load or survival time of Mtb-infected animals [8,9,10,11,12,13]. IFN-γ-mediated protection was attributed to the inhibition of deleterious Th17 response instead of suppression of Mtb replication [14]. In an elegant study by Sakai et al, IFN-γ accounted for only ~30% of the cumulative CD4+ T-cell-mediated reduction in murine lung bacterial loads, and overproduction of IFN-γ by individual CD4+ T cells was lethal [16]

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