Constantina Foti scite author profile

Long-term immune evasion by the African trypanosome is achieved through repetitive cycles of surface protein replacement with antigenically distinct versions of the dense Variant Surface Glycoprotein (VSG) coat. Thousands of VSG genes and pseudo-genes exist in the parasite genome, that together with genetic recombination mechanisms allow for essentially unlimited immune escape from the host adaptive immune system. The diversity space of the "VSGome" at the protein level was thought to be limited to a few related folds whose structures were determined more than 30 years ago. However, recent progress has shown that the VSGs possess significantly more architectural variation than had been appreciated. Here we combine experimental X-ray crystallography with deep-learning structural prediction using Alphafold to produce models of hundreds of VSG proteins, classifying the VSGome into groups based on protein architecture and oligomerization, contextualizing recent bioinformatics clustering schemes, and extensively mapping VSG-diversity space. We demonstrate that in addition to the structural variability and post-translational modifications observed, VSGs are also characterized by variations in oligomerization state and possess inherent flexibility and alternative conformations, lending additional variability to what is exposed to the immune system. Finally, several additional experimental structures and the hundreds of Alphafold predictions confirm that the molecular surfaces of the VSGs remain distinct from variant to variant, supporting the hypothesis that protein surface diversity is central to the process of antigenic variation used by this organism during infection.

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Structural and Immunological Similarities Between the Metacyclic and Bloodstream Form Variant Surface Glycoproteins of the African Trypanosome

Chandra

Dakovic

Foti

et al. 2022

Preprint

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During infection of mammalian hosts, African trypanosomes thwart immunity using antigenic variation of the dense Variant Surface Glycoprotein (VSG) coat, accessing a large repertoire of thousands of genes and pseudogenes and switching to antigenically distinct copies. The parasite is transferred to mammalian hosts through the bite of the tsetse fly. In the salivary glands of the fly, the pathogen adopts the metacyclic form and expresses a limited repertoire of VSG genes specific to that developmental stage. It has remained unknown whether the metacyclic VSGs possess distinct properties associated with this particular and discrete phase of the parasite life cycle. We show here using bioinformatic, crystallographic, and immunological analyses of three metacyclic VSGs that they closely mirror the known classes of bloodstream form VSGs both in structure and in the immunological responses they elicit.

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Constantina Foti

A Structural Classification of the Variant Surface Glycoproteins of the African Trypanosome

Structural and Immunological Similarities Between the Metacyclic and Bloodstream Form Variant Surface Glycoproteins of the African Trypanosome

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