MBL has been shown to be involved in the control of many microorganisms, including bacteria, fungi, parasites and viruses [6–9], and MBL deficiency has been associated with an increased frequency of various infections, including sepsis, aspergillosis,
meningococcal disease and invasive pneumococcal infections [8,10–13]. Intracellular pathogens, including Mycobacterium tuberculosis, co-opt macrophage phagocytosis to assist with establishing and disseminating infection [14]. Therefore, it has been proposed that high MBL GSK126 mw serum levels may lead to increased tuberculosis infections (TB) through promotion of M. tuberculosis opsonization [15]. This has been strengthened by studies demonstrating that MBL enhances phagocytic activity against other mycobacteria and demonstration of a protective effect of MBL deficiency against at least some forms of M. leprae infection [15–18]. A number of clinical and genetic studies have been performed to consider the impact of MBL levels or MBL polymorphisms on the development of TB. Results from these studies have been conflicting or contradictory, and it has been unclear whether MBL deficiency states result in increased susceptibility to tuberculosis infection. To attempt to clarify this APO866 concentration situation, therefore, we carried out a meta-analysis of studies
considering the association between MBL deficiency and tuberculosis infection. For the meta-analysis, we included all published studies that considered the association between tuberculosis and MBL2 polymorphisms. A literature search for the MeSH terms ‘tuberculosis OR TB OR mycobacteria’ and ‘MBL OR mannose-binding lectin OR mannose-binding protein’ was performed using Medline and PubMed and abstracts were reviewed for relevance. No language restrictions were applied to the search strategy. References of articles were also reviewed for additional relevant citations not included in the original search
protocol. Two of the authors (J.T.D. selleck chemical and D.P.E.) independently reviewed the full text of all articles to ensure that they met preset criteria for inclusion. The primary outcome considered in the meta-analysis was the association between pulmonary tuberculosis infection and the presence of MBL2 polymorphisms in patients without human immunodeficiency virus (HIV). For the primary analysis, and to allow appropriate comparison of all studies, cases and controls were classified as AA (wild-type MBL2 genotype), AO (structural gene polymorphism heterozygous MBL2 genotype) or OO (compound heterozygote MBL2 genotype). Subsequent analyses were also performed for the association between pulmonary tuberculosis and MBL2 polymorphisms in HIV-positive patients, and of the association between tuberculosis and serum MBL levels.