Carbohydrates as templates for control of distance-geometry in de novo-designed proteins

An understanding of very complex natural systems can often only be achieved through detailed studies of systems with a reduced complexity. Thus, de novo design of proteins allows the study of fundamental forces determining protein folding and stability, as well as protein-protein interactions, by analyses of protein models of structural motifs. In addition, de novo design may lead to new biomimetic molecules with novel properties. In a synthetic approach to achieve structural economy, rigid templates, sometimes called topological scaffolds, have been used to connect secondary-structure elements, most notably alpha-helices. By positioning the helices on the template, the unfavorable entropy of protein folding is reduced. In a novel class of chimeric molecules called carboproteins, carbohydrates are used as templates for de novo design of protein models. Recently, a strategy relying on chemoselective ligation of C-terminal peptide aldehydes to tetra-aminooxy functionalized monosaccharides has provided 7-kDa 4-alpha-helix bundle carboproteins.

α-Helices in the Type III Secretion Effectors: A Prevalent Feature with Versatile Roles

Type III Secretion Systems (T3SSs) are multicomponent nanomachines located at the cell envelope of Gram-negative bacteria. Their main function is to transport bacterial proteins either extracellularly or directly into the eukaryotic host cell cytoplasm. Type III Secretion effectors (T3SEs), latest to be secreted T3S substrates, are destined to act at the eukaryotic host cell cytoplasm and occasionally at the nucleus, hijacking cellular processes through mimicking eukaryotic proteins. A broad range of functions is attributed to T3SEs, ranging from the manipulation of the host cell's metabolism for the benefit of the bacterium to bypassing the host's defense mechanisms. To perform this broad range of manipulations, T3SEs have evolved numerous novel folds that are compatible with some basic requirements: they should be able to easily unfold, pass through the narrow T3SS channel, and refold to an active form when on the other side. In this review, the various folds of T3SEs are presented with the emphasis placed on the functional and structural importance of α-helices and helical domains.