Isoprenoids are synthesized by the prenyltransferase superfamily, which is subdivided according to the product stereoisomerism and length. In short- and medium-chain isoprenoids, product length correlates with active site volume. However, enzymes synthesizing long-chain products and rubber synthases fail to conform to this paradigm, because of an unexpectedly small active site. Here, we focused on the human cis -prenyltransferase complex (h cis -PT), residing at the endoplasmic reticulum membrane and playing a crucial role in protein glycosylation. Crystallographic investigation of h cis -PT along the reaction cycle revealed an outlet for the elongating product. Hydrogen-deuterium exchange mass spectrometry analysis showed that the hydrophobic active site core is flanked by dynamic regions consistent with separate inlet and outlet orifices. Last, using a fluorescence substrate analog, we show that product elongation and membrane association are closely correlated. Together, our results support direct membrane insertion of the elongating isoprenoid during catalysis, uncoupling active site volume from product length.
The conserved Tweety homolog (TTYH) family consists of three paralogs in vertebrates, displaying a ubiquitous expression pattern. Although considered as ion channels for almost two decades, recent structural and functional analyses refuted this role. Intriguingly, while all paralogs shared a dimeric stoichiometry following detergent solubilization, their structures revealed divergence in their relative subunit orientation. Here, we determined the stoichiometry of intact mouse TTYH (mTTYH) complexes in cells. Using cross-linking and single-molecule fluorescence microscopy, we demonstrate that mTTYH1 and mTTYH3 form tetramers at the plasma membrane, stabilized by interactions between their extracellular domains. Using blue-native PAGE, fluorescence-detection size-exclusion chromatography, and hydrogen/deuterium exchange mass spectrometry (HDX-MS), we reveal that detergent solubilization results in tetramers destabilization, leading to their dissolution into dimers. Moreover, HDX-MS demonstrates that the extracellular domains are stabilized in the context of the tetrameric mTTYH complex. Together, our results expose the innate tetrameric organization of TTYH complexes at the cell membrane. Future structural analyses of these assemblies in native membranes are required to illuminate their long-sought cellular function.
The conserved Tweety homolog (TTYH) family consists of three paralogs in vertebrates, displaying a ubiquitous expression pattern. Although considered as ion channels for almost two decades, recent structural and functional analyses refuted this role. Intriguingly, while all paralogs, studied following detergent solubilization, shared a dimeric stoichiometry, their spatial organization differed. Here, we determined the stoichiometry of intact mouse TTYH (mTTYH) complexes in cells. Using cross-linking and single-molecule fluorescence microscopy, we demonstrated that mTTYH1 and mTTYH3 form tetramers at the plasma membrane. Blue-native PAGE and fluorescence-detection size-exclusion chromatography analyses revealed that detergent solubilization results in the dissolution of tetramers into dimers, suggesting a dimer-of-dimers assembly mode. As cross-linking analysis of the soluble extracellular domains also showed tetrameric stoichiometry, we explored the effect of membrane solubilization and disulfide bridges integrity and established their contribution to tetramer stability. Future studies of the native tetrameric TTYH characterized here may illuminate their long-sought cellular function.
Isoprenoids are the largest group of natural products, found in all living organisms and play an essential role in numerous cellular processes. These compounds are synthesized by prenyltransferases, catalyzing the condensation reaction between an allylic diphosphate primer and a variable number of isopentenyl diphosphate (C5) units. This superfamily of enzymes can be subdivided into trans- or cis-prenyltransferases according to the stereoisomerism of the product. The cis branch can be further classified according to product length. While the active site volume was suggested to determine the final length in enzymes synthesizing short- and medium-chain products (up to C60), long-chain enzymes (up to C120) and rubber synthases (>C10,000) fail to conform to this paradigm. Here, to resolve the structural basis for long-chain isoprenoid synthesis, we focused on the human cis-prenyltransferase complex (hcis-PT). This enzyme, peripheral to the endoplasmic reticulum membrane, produces the precursor for dolichol phosphate, a membrane residing glycosyl carrier. In line with its crucial role in the cellular protein glycosylation machinery, disease-causing mutations in hcis-PT were shown to result in a wide spectrum of clinical phenotypes. The crystallographic structures of hcis-PT in four different substrate/product-bound conformations revealed an outlet enabling product elongation into the bulk solvent. Moreover, hydrogen-deuterium exchange mass spectrometry analysis in solution showed that the hydrophobic active site core is flanked by dynamic regions consistent with separate inlet and outlet orifices. Finally, using a fluorescent substrate analog and a fluorescently-labeled lipid nanodiscs, we show that product elongation and membrane association are closely correlated. Together, our results support directional product synthesis in long-chain enzymes and rubber synthases, with a distinct substrate inlet and product outlet, allowing direct membrane insertion of the elongating isoprenoid during catalysis. This mechanism uncouples active site volume from product length and circumvents the need to expulse hydrophobic product into a polar environment prior to membrane insertion.
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