Abstract
Binding of the macrophage lectin mincle to trehalose dimycolate, a key glycolipid virulence factor on the surface of Mycobacterium tuberculosis and Mycobacterium bovis, initiates responses that can lead both to toxicity and to protection of these pathogens from destruction. Crystallographic structural analysis, site-directed mutagenesis, and binding studies with glycolipid mimics have been used to define an extended binding site in the C-type carbohydrate recognition domain (CRD) of bovine mincle that encompasses both the headgroup and a portion of the attached acyl chains. One glucose residue of the trehalose Glcα1-1Glcα headgroup is liganded to a Ca(2+) in a manner common to many C-type CRDs, whereas the second glucose residue is accommodated in a novel secondary binding site. The additional contacts in the secondary site lead to a 36-fold higher affinity for trehalose compared with glucose. An adjacent hydrophobic groove, not seen in other C-type CRDs, provides a docking site for one of the acyl chains attached to the trehalose, which can be targeted with small molecule analogs of trehalose dimycolate that bind with 52-fold higher affinity than trehalose. The data demonstrate how mincle bridges between the surfaces of the macrophage and the mycobacterium and suggest the possibility of disrupting this interaction. In addition, the results may provide a basis for design of adjuvants that mimic the ability of mycobacteria to stimulate a response to immunization that can be employed in vaccine development.
Highlights
Mincle facilitates establishment of persistent infections of macrophages by Mycobacterium tuberculosis
Binding of the macrophage lectin mincle to trehalose dimycolate, a key glycolipid virulence factor on the surface of Mycobacterium tuberculosis and Mycobacterium bovis, initiates responses that can lead both to toxicity and to protection of these pathogens from destruction
Not seen in other C-type carbohydrate recognition domain (CRD), provides a docking site for one of the acyl chains attached to the trehalose, which can be targeted with small molecule analogs of trehalose dimycolate that bind with 52-fold higher affinity than trehalose
Summary
Mincle facilitates establishment of persistent infections of macrophages by Mycobacterium tuberculosis. Trehalose dimycolate, which is a characteristic component of the mycobacterial surface, is referred to as cord factor It comprises a Glc␣1–1Glc␣ headgroup and two complex branched and hydroxylated acyl chains attached to the 6-OH groups of each of the sugar residues. The importance of mincle in the interaction of macrophages with mycobacteria stems both from its ability to interact with trehalose dimycolate and from its association with the common Fc receptor-1␥ subunit, which activates the Syk-CARD signaling pathway (12, 13). This interaction leads to granuloma formation and may participate in directing the macrophages to tolerate rather than destroy internalized mycobacteria (14). Small molecule mimics of trehalose dimycolate have been generated to establish the importance of different parts of the glycolipid for recognition
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