Structural insights into substrate binding of SLC19A3: Comparing inward-open and outward-open conformations.

Monocarboxylate transporter 8 (MCT8) facilitates cellular uptake and efflux of thyroid hormone (TH). Mutations in MCT8 result in severe intellectual and motor disability known as the Allan-Herndon-Dudley syndrome (AHDS). Previous studies have provided valuable insights into the putative mechanism of substrate binding in the inward-open conformation, required for TH efflux. The current study aims to delineate the mechanism of substrate binding in the outward-open conformation, required for TH uptake. Extensive chemical modification and site-directed mutagenesis studies were used to guide protein homology modeling of MCT8 in the outward-open conformation. Arg271 and Arg445 were modified by phenylglyoxal, which was partially prevented in the presence of substrate. Substrate docking in our outward-open model suggested an important role for His192 and Arg445 in substrate binding. Interestingly, mutations affecting these residues have been identified in patients who have AHDS. In addition, our outward-open model predicted the location of Phe189, Met227, Phe279, Gly282, Phe287, and Phe501 at the substrate-binding center, and their Ala substitution differentially affected the apparent Vmax and Km of T3 transport, with F189A, F279A, and F287A showing the highest impact. Thus, here we present an MCT8 homology model in the outward-open conformation, which supports the important role of His192 and Arg445 in substrate docking and identifies critical residues at the putative substrate-binding center. Our findings provide insights into MCT8 structure and function, which add to our understanding of the pathogenic mechanism of mutations found in patients who have AHDS and can be used to screen for novel substrates and inhibitors.

Towards Identifying Biologically Relevant Intermediate Conformational States in Dopamine Transporter

Structural Dynamics and Energetics of Glucose Transport via Rice SWEET Sugar Transporter

Cocaine, a widely abused psychostimulant, inhibits the dopamine transporter (DAT) by trapping the protein in an outward-open conformation, whereas atypical DAT inhibitors such as benztropine have low abuse liability and prefer less outward-open conformations. Here, we use a spectrum of computational modeling and simulation approaches to obtain the underlying molecular mechanism in atomistic detail. Interestingly, our quantum mechanical calculations and molecular dynamics (MD) simulations suggest that a benztropine derivative JHW007 prefers a different stereoisomeric conformation of tropane in binding to DAT compared to that of a cocaine derivative, CFT. To further investigate the different inhibition mechanisms of DAT, we carried out MD simulations in combination with Markov state modeling analysis of wild-type and Y156F DAT in the absence of any ligand or the presence of CFT or JHW007. Our results indicate that the Y156F mutation and CFT shift the conformational equilibrium toward an outward-open conformation, whereas JHW007 prefers an inward-occluded conformation. Our findings reveal the mechanistic details of DAT inhibition by JHW007 at the atomistic level, which provide clues for rational design of atypical inhibitors.

Heteromeric amino acid transporters (HATs), including y+LAT1-4F2hc complex, are responsible for transporting amino acids across membranes, and mutations in y+LAT1 cause lysinuric protein intolerance (LPI), a hereditary disorder characterized by defective cationic amino acid transport. The relationship between LPI and specific mutations in y+LAT1 has yet to be fully understood. In this study, we characterized the function of y+LAT1-4F2hc complex in mammalian cells and determined the cryo-EM structures of the human y+LAT1-4F2hc complex in two distinct conformations: the apo state in an inward-open conformation and the native substrate-bound state in an outward-open conformation. Structural analysis suggests that Asp243 in y+LAT1 plays a crucial role in coordination with sodium ion and substrate selectivity. Molecular dynamic (MD) simulations further revealed the different transport mechanism of cationic amino acids and neutral amino acids. These results provide important insights into the mechanisms of the substrate binding and working cycle of HATs.

Major histocompatibility complex class I (MHC-I), a key element of the acquired immune system, plays essential roles in activating CD8+ T cells by recognizing intracellular antigens derived from pa...

Decision letter: pH- and sodium-induced changes in a sodium/proton antiporter

The taurine transporter (TAUT) mediates cellular taurine uptake, playing a critical role in human health and longevity. In this study, we present cryogenic electron microscopy structures of both mouse and human TAUT in various conformational states. The taurine-bound, occluded forms of mouse and human TAUT reveal the substrate binding pocket and the ion binding sites. The amino group of taurine interacts with Glu406 at the binding site, constituting a key structural feature determining substrate preference. While both imidazole acetic acid and guanidinoethyl sulfonate (GES) inhibit TAUT by competing with taurine for the binding site, GES also functions as a substrate of TAUT. Moreover, mouse TAUT is captured in an inward-open apo conformation, where the tilted movement of transmembrane helix (TM) 1a opens the intracellular gate. Notably, TM6 exhibits two distinct conformational states: the canonical form consisting of two half-helices and a continuous straight helix. In the latter conformation, TM6 partially occupies the substrate binding site, likely promoting taurine release. Together, our findings provide critical insights into the molecular mechanisms by which TAUT recognizes and transports taurine.

Transporter proteins change their conformations to carry their substrate across the cell membrane. The conformational dynamics is vital to understanding the transport function. We have studied the oxalate transporter (OxlT), an oxalate:formate antiporter from Oxalobacter formigenes, significant in avoiding kidney stone formation. The atomic structure of OxlT has been recently solved in the outward-open and occluded states. However, the inward-open conformation is still missing, hindering a complete understanding of the transporter. Here, we performed a Gaussian accelerated molecular dynamics simulation to sample the extensive conformational space of OxlT and successfully predicted the inward-open conformation where cytoplasmic substrate formate binding was preferred over oxalate binding. We also identified critical interactions for the inward-open conformation. The results were complemented by an AlphaFold2 structure prediction. Although AlphaFold2 solely predicted OxlT in the outward-open conformation, mutation of the identified critical residues made it partly predict the inward-open conformation, identifying possible state-shifting mutations.

Molecular Basis of GLUT4 in Glucose Transport: Atomistic Molecular Dynamics Study

γ-Aminobutyric acid (GABA) transporter 1 (GAT1)1 regulates neuronal excitation of the central nervous system by clearing the synaptic cleft of the inhibitory neurotransmitter GABA upon its release from synaptic vesicles. Elevating the levels of GABA in the synaptic cleft, by inhibiting GABA reuptake transporters, is an established strategy to treat neurological disorders, such as epilepsy2. Here we determined the cryo-electron microscopy structure of full-length, wild-type human GAT1 in complex with its clinically used inhibitor tiagabine3, with an ordered part of only 60 kDa. Our structure reveals that tiagabine locks GAT1 in the inward-open conformation, by blocking the intracellular gate of the GABA release pathway, and thus suppresses neurotransmitter uptake. Our results provide insights into the mixed-type inhibition of GAT1 by tiagabine, which is an important anticonvulsant medication. Its pharmacodynamic profile, confirmed by our experimental data, suggests initial binding of tiagabine to the substrate-binding site in the outward-open conformation, whereas our structure presents the drug stalling the transporter in the inward-open conformation, consistent with a two-step mechanism of inhibition4. The presented structure of GAT1 gives crucial insights into the biology and pharmacology of this important neurotransmitter transporter and provides blueprints for the rational design of neuromodulators, as well as moving the boundaries of what is considered possible in single-particle cryo-electron microscopy of challenging membrane proteins.

Structural basis of GABA reuptake inhibition.

Sodium-Glucose Cotransporters (SGLT) mediate the uphill uptake of extracellular sugars and play fundamental roles in sugar metabolism. Although their structures in inward-open and outward-open conformations are emerging from structural studies, the trajectory of how SGLTs transit from the outward-facing to the inward-facing conformation remains unknown. Here, we present the cryo-EM structures of human SGLT1 and SGLT2 in the substrate-bound state. Both structures show an occluded conformation, with not only the extracellular gate but also the intracellular gate tightly sealed. The sugar substrate are caged inside a cavity surrounded by TM1, TM2, TM3, TM6, TM7, and TM10. Further structural analysis reveals the conformational changes associated with the binding and release of substrates. These structures fill a gap in our understanding of the structural mechanisms of SGLT transporters.

Conformational Complexity and Dynamics in a Muscarinic Receptor Revealed by NMR Spectroscopy.

Investigation of the transport cycle of sodium glucose transport proteins through computational simulation.