%0 Journal Article %A Kazuya Segawa %A Naoki Tamura %A Joji Mima %T Homotypic and heterotypic trans-assembly of human Rab-family small GTPases in reconstituted membrane tethering %D 2019 %R 10.1101/544379 %J bioRxiv %P 544379 %X Membrane tethering is a highly regulated event that occurs during the initial physical contact between membrane-bounded transport carriers and their target subcellular membrane compartments, thereby ensuring the spatiotemporal specificity of intracellular membrane trafficking. Although Rab-family small GTPases and specific Rab-interacting effectors, such as coiled-coil tethering proteins and multisubunit tethering complexes, are known to be involved in membrane tethering, how these protein components directly act upon the tethering event remains enigmatic. Here, we investigated the molecular basis of membrane tethering by comprehensively and quantitatively evaluating the intrinsic capacities of 10 representative human Rab-family proteins (Rab1a, 3a, 4a, 5a, 6a, 7a, 9a, 11a, 27a, and 33b) to physically tether two distinct membranes via homotypic and heterotypic Rab-Rab assembly in a chemically defined reconstitution system. All of the Rabs tested, except Rab27a, specifically caused homotypic membrane tethering at physiologically relevant Rab densities on membrane surfaces (e.g., Rab-to-lipid molar ratios of 1:100-1:3,000). Notably, endosomal Rab5a retained its intrinsic potency to drive efficient homotypic tethering even at concentrations below the Rab-to-lipid ratio of 1:3,000. Comprehensive reconstitution studies further uncovered that heterotypic combinations of human Rab-family isoforms, including Rab1a/6a, Rab1a/9a, and Rab1a/33b, can directly and selectively mediate membrane tethering. Rab1a and Rab9a, in particular, synergistically triggered very rapid and efficient membrane tethering reactions through their heterotypic trans-assembly on two opposing membranes. Thus, our findings establish that, in the physiological context, homotypic and heterotypic trans-assembly of Rab-family small GTPases can provide the essential molecular machinery necessary to drive membrane tethering in eukaryotic endomembrane systems. %U https://www.biorxiv.org/content/biorxiv/early/2019/02/08/544379.full.pdf