Invariant NKT cells in adrenoleukodystrophy patients and mice.

X-linked adrenoleukodystrophy (X-ALD) is a severe neurological disease characterized by progressive demyelination within the CNS, adrenal insufficiency, and is associated with an accumulation of saturated very long chain fatty acids in plasma and tissues of patients. iNKT cells, a distinct lineage of T cells recognizing glycolipid antigens through CD1d molecules, exert immunoregulatory functions and can prevent various immune mediated-pathologies. In ALD patients, but not in ALD deficient mice, iNKT cell frequency and CD1d expression on the surface of B cells are slightly decreased. However, such minor differences might not influence the pathogenesis of the disease.

[The role of human dendritic cells in tuberculosis: protector or non-protector?]. / Rôle des cellules dendritiques humaines dans la tuberculose: protecteur ou non protecteur?

INTRODUCTION: Mycobacterium tuberculosis, the cause of tuberculosis remains a pathogenic organism capable of infecting a large number of individuals and of resisting the immune response of the infected host. The main constituents of this response are the antigen presenting cells such as dendritic cells, macrophages and T lymphocytes. BACKGROUND: Comparative study of the interactions between M. tuberculosis and the antigen presenting cells has shown that dendritic cells do not permit intracellular growth of M. tuberculosis, unlike that seen in macrophages. A hostile intracellular compartment creates a bacteriostatic environment. M. tuberculosis is internalised by binding to a C-type lectin receptor (DC-SIGN). VIEWPOINT: This receptor recognises polysaccharide compounds on the surface of M. tuberculosis. This sugar-lectin bond may compensate for the bond between bacterial compounds and Toll receptors, partially inhibiting the protective inflammatory reaction or compensating for an excessive inflammatory reaction. CONCLUSIONS: This bond encourages both the persistence of quiescent bacteria in the dendritic cells and the reciprocal adaptation of the host and the bacteria over the course of time.

Neutral-red reaction is related to virulence and cell wall methyl-branched lipids in Mycobacterium tuberculosis.

Searching for virulence marking tests for Mycobacterium tuberculosis, Dubos and Middlebrook reported in 1948 that in an alkaline aqueous solution of neutral-red, the cells of the virulent H37Rv M. tuberculosis strain fixed the dye and became red in color, whereas the cells of the avirulent H37Ra M. tuberculosis strain remained unstained. In the 1950 and 1960s, fresh isolates of M. tuberculosis were tested for this neutral-red cytochemical reaction and it was reported that they were neutral-red positive, whereas other mycobacteria of diverse environmental origins that were non-pathogenic for guinea pigs were neutral-red negative. However, neutral-red has not really been proven to be a virulence marker. To test if virulence is in fact correlated to neutral-red, we studied a clinical isolate of M. tuberculosis that was originally neutral-red positive but, after more than 1 year passing through culture mediums, turned neutral-red negative. We found that, in comparison to the original neutral-red positive strain, this neutral-red negative variant was attenuated in two murine models of experimental tuberculosis. Lipid analysis showed that this neutral-red negative natural mutant lost the capacity to synthesize pthiocerol dimycocerosates, a cell wall methyl-branched lipid that has been related to virulence in M. tuberculosis. We also studied the neutral-red of different gene-targeted M. tuberculosis mutants unable to produce pthiocerol dimycocerosates or other cell wall methyl-branched lipids such as sulfolipids, and polyacyltrehaloses. We found a negative neutral-red reaction in mutants that were deficient in more than one type of methyl-branched lipids. We conclude that neutral-red is indeed a marker of virulence and it indicates important perturbations in the external surface of M. tuberculosis cells.