Transmembrane helix 1 contributes to substrate translocation and protein stability of bile acid transporter SLC10A2.

The human apical sodium-dependent bile acid transporter (hASBT, SLC10A2) plays a critical role in the enterohepatic circulation of bile acids, as well as in cholesterol homeostasis. ASBT reclaims bile acids from the distal ileum via active sodium co-transport, in a multistep process, orchestrated by key residues in exofacial loop regions, as well as in membrane-spanning helices. Here, we unravel the functional contribution of highly conserved transmembrane helix 1 (TM1) on the hASBT transport cycle. Consecutive cysteine substitution of individual residues along the TM1 helix (Ile(29)-Gly(50)), as well as exofacial Asn(27) and Asn(28), resulted in functional impairment of ∼70% of mutants, despite appreciable cell surface expression for all but G50C. Cell surface expression of G50C and G50A was rescued upon MG132 treatment as well as cyclosporine A, but not by FK506 or bile acids, suggesting that Gly(50) is involved in hASBT folding. TM1 accessibility to membrane-impermeant MTSET remains confined to the exofacial half of the helix along a single, discrete face. Substrate protection from MTSET labeling was temperature-dependent for L34C, T36C, and L38C, consistent with conformational changes playing a role in solvent accessibility for these mutants. Residue Leu(30) was shown to be critical for both bile acid and sodium affinity, while Asn(27), Leu(38), Thr(39), and Met(46) participate in sodium co-transport. Combined, our data demonstrate that TM1 plays a pivotal role in ASBT function and stability, thereby providing further insight in its dynamic transport mechanism.

Conserved aspartic acid residues lining the extracellular loop 1 of sodium-coupled bile acid transporter ASBT Interact with Na+ and 7alpha-OH moieties on the ligand cholestane skeleton.

Functional contributions of residues Val-99-Ser-126 lining extracellular loop (EL) 1 of the apical sodium-dependent bile acid transporter were determined via cysteine-scanning mutagenesis, thiol modification, and in silico interpretation. Despite membrane expression for all but three constructs (S112C, Y117C, S126C), most EL1 mutants (64%) were inactivated by cysteine mutation, suggesting a functional role during sodium/bile acid co-transport. A negative charge at conserved residues Asp-120 and Asp-122 is required for transport function, whereas neutralization of charge at Asp-124 yields a functionally active transporter. D124A exerts low affinity for common bile acids except deoxycholic acid, which uniquely lacks a 7alpha-hydroxyl (OH) group. Overall, we conclude that (i) Asp-122 functions as a Na(+) sensor, binding one of two co-transported Na(+) ions, (ii) Asp-124 interacts with 7alpha-OH groups of bile acids, and (iii) apolar EL1 residues map to hydrophobic ligand pharmacophore features. Based on these data, we propose a comprehensive mechanistic model involving dynamic salt bridge pairs and hydrogen bonding involving multiple residues to describe sodium-dependent bile acid transporter-mediated bile acid and cation translocation.

Dynamin 2 regulates riboflavin endocytosis in human placental trophoblasts.

Riboflavin is thoroughly established to be indispensable in a multitude of cellular oxidation-reduction reactions through its conversion to coenzyme forms flavin mononucleotide and flavin adenine dinucleotide. Despite its physiological importance, little is known about specific mechanisms or proteins involved in regulating its cellular entry in humans. Studies involving biochemical modulators and immunological inhibition assays have indirectly revealed that riboflavin internalization and trafficking occurs at least in part through a clathrin-dependent receptor-mediated endocytic process. Here, using a two-tiered strategy involving RNA interference and the overexpression of dominant-negative constructs, we directly show the involvement of this endocytic mechanism through the requirement of the pluripotent endocytic vesicle scission enzyme, dynamin 2 GTPase, in human placental trophoblasts. Similar to the endocytic control ligand, transferrin, riboflavin is shown to exhibit 50% dependence on the functional expression of dynamin 2 for its active cellular entry. Furthermore, this reduced vitamin uptake correlates with >2-fold higher riboflavin association at the cell surface. In addition, fluorescent ligand endocytosis assays showing colocalization between rhodamine-riboflavin and the immunostained caveolar coat protein, caveolin 1, suggest that the active absorption of this important nutrient involves multiple and distinct endocytosis pathways.