Characterization of the glucosyltransferases that assemble the side chains of the Indian Leishmania donovani lipophosphoglycan.

The life cycle of Leishmania parasites within its sand fly vector involves the development of extracellular promastigotes from a noninfective, "procyclic" stage into an infective, "metacyclic" stage that is adapted for transmission in the fly and survival in the mammalian host. Lipophosphoglycan (LPG), the predominant surface glycoconjugate in both procyclic and metacyclic stages, is a critical virulence determinant. LPG is a multidomain molecule; the structural polymorphisms among species lie in branching from the backbone 6Galbeta1,4Man(alpha1)-PO(4) repeat units and in the composition of the small oligosaccharide caps. We have recently demonstrated that the LPG from an Indian isolate of Leishmania donovani differs from a Sudanese strain by possessing one or two side chain beta(1,3)-linked glucose residues. We now have characterized the glucosyltransferase activities responsible for glucosylating the LPG. When incubated with UDP-[(3)H]glucose and Mn(2+), microsomal membranes from the Indian isolate transferred [(3)H]glucose to the repeat units of the exogenous acceptor Sudanese L. donovani LPG, which does not contain any side chain branching. Glucose addition was maximal at 28 degrees C, the optimal growth temperature of procyclic L. donovani. Consistent with the lack of side chain branching in its LPG, Sudanese L. donovani showed minimal glucosyltransferase activity. Indian metacyclic promastigotes, in contrast to procyclic promastigotes, express no glucose side chains off the repeat units. Therefore, we compared the relative activity of the glucosyltransferases in microsomes from procyclic and metacyclic promastigotes and observed approximately 80% less activity in the latter. These results provide evidence that the glucose side chain addition to LPG is developmentally regulated during the parasite's life cycle and that the glucosyltransferases of L. donovani are strain specific.

Intra-species and stage-specific polymorphisms in lipophosphoglycan structure control Leishmania donovani-sand fly interactions.

The Leishmania lipophosphoglycan conveys the ability for the parasites to avoid destruction in diverse host environments. During its life cycle within the sand fly vector, the parasite differentiates from a dividing procyclic promastigote stage that avoids expulsion from the midgut by attaching to the gut wall, to a nondividing metacyclic promastigote stage that is unable to attach to the midgut and migrates to the mouth parts for reinfection of a mammalian host. Lipophosphoglycan plays an integral role during this transition. Structurally, lipophosphoglycan is a multidomain glycoconjugate whose polymorphisms among species lie in the backbone Gal(beta 1,4)Man(alpha 1)-PO(4) repeating units and the oligosaccharide cap. We have characterized the lipophosphoglycan from an Indian L. donovani isolate. Unlike East African isolates, which express unsubstituted repeats and a galactose- and mannose-terminating cap, procyclic lipophosphoglycan from the Indian isolate consists of beta1,3-linked glucose residues that branch off the backbone repeats (n approximately 17) and also terminate the cap. Of biological significance, metacyclic lipophosphoglycan lacks the glucose residues while doubling the number of repeats. The importance of these developmental modifications in lipophosphoglycan structure was determined using binding experiments to Phlebotomus argentipes midguts. Procyclic promastigotes and procyclic LPG were able to bind to sand fly midguts in vitro whereas metacyclic parasites and LPG lost this capacity. These results demonstrate that the Leishmania adapts the synthesis of terminally exposed sugars of its LPG to manipulate parasite-sand fly interactions.