Publications

2022

Wu, Xuelan, et al. “Structural Advances in Sterol-Sensing Domain-Containing Proteins”. Trends in Biochemical Sciences, Elsevier, 2022.

2021

Gao, Shuai, and Nieng Yan. “Structural Basis of the Modulation of the Voltage-Gated Calcium Ion Channel Cav1. 1 by Dihydropyridine Compounds”. Angewandte Chemie International Edition, vol. 60, no. 6, Wiley Online Library, 2021, pp. 3131–3137.
Gao, Shuai, et al. “Structure of Human Cav2. 2 Channel Blocked by the Painkiller Ziconotide”. Nature, vol. 596, no. 7870, Nature Publishing Group, 2021, pp. 143–147.
Li, Zhangqiang, et al. “Structure of Human Nav1. 5 Reveals the Fast Inactivation-Related Segments As a Mutational Hotspot for the Long QT Syndrome”. Proceedings of the National Academy of Sciences, vol. 118, no. 11, National Acad Sciences, 2021.
Li, Zhangqiang, et al. “Structural Basis for Pore Blockade of the Human Cardiac Sodium Channel Nav1. 5 by the Antiarrhythmic Drug Quinidine”. Angewandte Chemie, vol. 133, no. 20, Wiley Online Library, 2021, pp. 11575–11581.
Pan, Xiaojing, et al. “Comparative Structural Analysis of Human Nav1. 1 and Nav1. 5 Reveals Mutational Hotspots for Sodium Channelopathies”. Proceedings of the National Academy of Sciences, vol. 118, no. 11, National Acad Sciences, 2021.
Yan, Renhong, et al. “A Structure of Human Scap Bound to Insig-2 Suggests How Their Interaction Is Regulated by Sterols”. Science, vol. 371, no. 6533, American Association for the Advancement of Science, 2021, p. eabb2224.
Yan, Renhong, et al. “Structural Basis for Sterol Sensing by Scap and Insig”. Cell Reports, vol. 35, no. 13, Elsevier, 2021, p. 109299.

2020

Gao, Shuai, et al. “Employing NaChBac for Cryo-EM Analysis of Toxin Action on Voltage-Gated Na Channels in Nanodisc”. 2020. Proc Natl Acad Sci U S A, 2020, doi:10.1073/pnas.1922903117.

NaChBac, the first bacterial voltage-gated Na (Na) channel to be characterized, has been the prokaryotic prototype for studying the structure-function relationship of Na channels. Discovered nearly two decades ago, the structure of NaChBac has not been determined. Here we present the single particle electron cryomicroscopy (cryo-EM) analysis of NaChBac in both detergent micelles and nanodiscs. Under both conditions, the conformation of NaChBac is nearly identical to that of the potentially inactivated NaAb. Determining the structure of NaChBac in nanodiscs enabled us to examine gating modifier toxins (GMTs) of Na channels in lipid bilayers. To study GMTs in mammalian Na channels, we generated a chimera in which the extracellular fragment of the S3 and S4 segments in the second voltage-sensing domain from Na1.7 replaced the corresponding sequence in NaChBac. Cryo-EM structures of the nanodisc-embedded chimera alone and in complex with HuwenToxin IV (HWTX-IV) were determined to 3.5 and 3.2 Å resolutions, respectively. Compared to the structure of HWTX-IV-bound human Na1.7, which was obtained at an overall resolution of 3.2 Å, the local resolution of the toxin has been improved from ∼6 to ∼4 Å. This resolution enabled visualization of toxin docking. NaChBac can thus serve as a convenient surrogate for structural studies of the interactions between GMTs and Na channels in a membrane environment.

Han, Yimo, et al. “High-Yield Monolayer Graphene Grids for Near-Atomic Resolution Cryoelectron Microscopy”. 2020. Proc Natl Acad Sci U S A, vol. 117, no. 2, 2020, pp. 1009-14, doi:10.1073/pnas.1919114117.

Cryogenic electron microscopy (cryo-EM) has become one of the most powerful techniques to reveal the atomic structures and working mechanisms of biological macromolecules. New designs of the cryo-EM grids-aimed at preserving thin, uniform vitrified ice and improving protein adsorption-have been considered a promising approach to achieving higher resolution with the minimal amount of materials and data. Here, we describe a method for preparing graphene cryo-EM grids with up to 99% monolayer graphene coverage that allows for more than 70% grid squares for effective data acquisition with improved image quality and protein density. Using our graphene grids, we have achieved 2.6-Å resolution for streptavidin, with a molecular weight of 52 kDa, from 11,000 particles. Our graphene grids increase the density of examined soluble, membrane, and lipoproteins by at least 5-fold, affording the opportunity for structural investigation of challenging proteins which cannot be produced in large quantity. In addition, our method employs only simple tools that most structural biology laboratories can access. Moreover, this approach supports customized grid designs targeting specific proteins, owing to its broad compatibility with a variety of nanomaterials.

Qian, Hongwu, et al. “Structural Basis for Catalysis and Substrate Specificity of Human ACAT1”. 2020. Nature, vol. 581, no. 7808, 2020, pp. 333-8, doi:10.1038/s41586-020-2290-0.

As members of the membrane-bound O-acyltransferase (MBOAT) enzyme family, acyl-coenzyme A:cholesterol acyltransferases (ACATs) catalyse the transfer of an acyl group from acyl-coenzyme A to cholesterol to generate cholesteryl ester, the primary form in which cholesterol is stored in cells and transported in plasma. ACATs have gained attention as potential drug targets for the treatment of diseases such as atherosclerosis, Alzheimer's disease and cancer. Here we present the cryo-electron microscopy structure of human ACAT1 as a dimer of dimers. Each protomer consists of nine transmembrane segments, which enclose a cytosolic tunnel and a transmembrane tunnel that converge at the predicted catalytic site. Evidence from structure-guided mutational analyses suggests that acyl-coenzyme A enters the active site through the cytosolic tunnel, whereas cholesterol may enter from the side through the transmembrane tunnel. This structural and biochemical characterization helps to rationalize the preference of ACAT1 for unsaturated acyl chains, and provides insight into the catalytic mechanism of enzymes within the MBOAT family.

Qian, Hongwu, et al. “Structural Basis of Low-PH-Dependent Lysosomal Cholesterol Egress by NPC1 and NPC2”. Cell, 2020, p. 06/2020, doi:10.1016/j.cell.2020.05.020.

Lysosomal cholesterol egress requires two proteins, NPC1 and NPC2, whose defects are responsible for Niemann-Pick disease type C (NPC). Here, we present systematic structural characterizations that reveal the molecular basis for low-pH-dependent cholesterol delivery from NPC2 to the transmembrane (TM) domain of NPC1. At pH 8.0, similar structures of NPC1 were obtained in nanodiscs and in detergent at resolutions of 3.6 Å and 3.0 Å, respectively. A tunnel connecting the N-terminal domain (NTD) and the transmembrane sterol-sensing domain (SSD) was unveiled. At pH 5.5, the NTD exhibits two conformations, suggesting the motion for cholesterol delivery to the tunnel. A putative cholesterol molecule is found at the membrane boundary of the tunnel, and TM2 moves toward formation of a surface pocket on the SSD. Finally, the structure of the NPC1-NPC2 complex at 4.0 Å resolution was obtained at pH 5.5, elucidating the molecular basis for cholesterol handoff from NPC2 to NPC1(NTD).

Wang, Lie, et al. “Structure and Mechanism of Human Diacylglycerol O-acyltransferase 1”. 2020. Nature, vol. 581, no. 7808, 2020, pp. 329-32, doi:10.1038/s41586-020-2280-2.

Diacylglycerol O-acyltransferase 1 (DGAT1) synthesizes triacylglycerides and is required for dietary fat absorption and fat storage in humans. DGAT1 belongs to the membrane-bound O-acyltransferase (MBOAT) superfamily, members of which are found in all kingdoms of life and are involved in the acylation of lipids and proteins. How human DGAT1 and other mammalian members of the MBOAT family recognize their substrates and catalyse their reactions is unknown. The absence of three-dimensional structures also hampers rational targeting of DGAT1 for therapeutic purposes. Here we present the cryo-electron microscopy structure of human DGAT1 in complex with an oleoyl-CoA substrate. Each DGAT1 protomer has nine transmembrane helices, eight of which form a conserved structural fold that we name the MBOAT fold. The MBOAT fold in DGAT1 forms a hollow chamber in the membrane that encloses highly conserved catalytic residues. The chamber has separate entrances for each of the two substrates, fatty acyl-CoA and diacylglycerol. DGAT1 can exist as either a homodimer or a homotetramer and the two forms have similar enzymatic activity. The N terminus of DGAT1 interacts with the neighbouring protomer and these interactions are required for enzymatic activity.

Yao, Xia, et al. “Cryo-EM Analysis of a Membrane Protein Embedded in the Liposome”. Proceedings of the National Academy of Sciences, National Academy of Sciences, 2020, doi:10.1073/pnas.2009385117.
Membrane proteins (MPs), encoded by \~30% of the coding genes, play vital roles in numerous physiological processes. MPs are targets of more than half of the FDA-approved drugs. High-resolution structural studies of functional membrane proteins under near-physiological conditions are required to provide an in-depth mechanistic understanding and to facilitate drug discovery. To embed the proteins into liposomes represents a strategy to mimic native membrane conditions. Here we present a convenient workflow for cryo-EM analysis of liposome-embedded MPs using the prototypal protein AcrB. Our method sets the foundation for future investigation of MPs in the presence of electrochemical gradients and for the understanding of the interdependence of integral or peripheral MPs and various membrane properties.Membrane proteins (MPs) used to be the most difficult targets for structural biology when X-ray crystallography was the mainstream approach. With the resolution revolution of single-particle electron cryo-microscopy (cryo-EM), rapid progress has been made for structural elucidation of isolated MPs. The next challenge is to preserve the electrochemical gradients and membrane curvature for a comprehensive structural elucidation of MPs that rely on these chemical and physical properties for their biological functions. Toward this goal, here we present a convenient workflow for cryo-EM structural analysis of MPs embedded in liposomes, using the well-characterized AcrB as a prototype. Combining optimized proteoliposome isolation, cryo-sample preparation on graphene grids, and an efficient particle selection strategy, the three-dimensional (3D) reconstruction of AcrB embedded in liposomes was obtained at 3.9 Å resolution. The conformation of the homotrimeric AcrB remains the same when the surrounding membranes display different curvatures. Our approach, which can be widely applied to cryo-EM analysis of MPs with distinctive soluble domains, lays out the foundation for cryo-EM analysis of integral or peripheral MPs whose functions are affected by transmembrane electrochemical gradients or/and membrane curvatures.

2019

Brown, Andrew, et al. “The Shape of Human Squalene Epoxidase Expands the Arsenal Against Cancer”. 2019. Nat Commun, vol. 10, no. 1, 2019, p. 888, doi:10.1038/s41467-019-08866-y.

Squalene epoxidase (also known as squalene monooxygenase, EC 1.14.99.7) is a key rate-limiting enzyme in cholesterol biosynthesis. Anil Padyana and colleagues report the long awaited structure of human squalene epoxidase (SQLE). They solved the crystal structure of the catalytic domain of human SQLE alone and in complex with two similar pharmacological inhibitors and elucidate their mechanism of action. SQLE is the target of fungicides and of increasing interest in human health and disease, particularly as a new anti-cancer target. Indeed, in a companion paper, Christopher Mahoney and colleagues performed an inhibitor screen with cancer cell lines and identified SQLE as an unique vulnerability in a subset of neuroendocrine tumours, where SQLE inhibition caused a toxic accumulation of the substrate squalene. The SQLE structure will facilitate the development of improved inhibitors. Here, we comment on these two studies in the wider context of the field and discuss possible future directions.

Chi, Ximin, et al. “Molecular Basis for Allosteric Regulation of the Type 2 Ryanodine Receptor Channel Gating by Key Modulators”. 2019. Proc Natl Acad Sci U S A, vol. 116, no. 51, 2019, pp. 25575-82, doi:10.1073/pnas.1914451116.

The type 2 ryanodine receptor (RyR2) is responsible for releasing Ca from the sarcoplasmic reticulum of cardiomyocytes, subsequently leading to muscle contraction. Here, we report 4 cryo-electron microscopy (cryo-EM) structures of porcine RyR2 bound to distinct modulators that, together with our published structures, provide mechanistic insight into RyR2 regulation. Ca alone induces a contraction of the central domain that facilitates the dilation of the S6 bundle but is insufficient to open the pore. The small-molecule agonist PCB95 helps Ca to overcome the barrier for opening. FKBP12.6 induces a relaxation of the central domain that decouples it from the S6 bundle, stabilizing RyR2 in a closed state even in the presence of Ca and PCB95. Although the channel is open when PCB95 is replaced by caffeine and adenosine 5'-triphosphate (ATP), neither of the modulators alone can sufficiently counter the antagonistic effect to open the channel. Our study marks an important step toward mechanistic understanding of the sophisticated regulation of this key channel whose aberrant activity engenders life-threatening cardiac disorders.

Gong, Deshun, et al. “Modulation of Cardiac Ryanodine Receptor 2 by Calmodulin”. 2019. Nature, vol. 572, no. 7769, 2019, pp. 347-51, doi:10.1038/s41586-019-1377-y.

The high-conductance intracellular calcium (Ca) channel RyR2 is essential for the coupling of excitation and contraction in cardiac muscle. Among various modulators, calmodulin (CaM) regulates RyR2 in a Ca-dependent manner. Here we reveal the regulatory mechanism by which porcine RyR2 is modulated by human CaM through the structural determination of RyR2 under eight conditions. Apo-CaM and Ca-CaM bind to distinct but overlapping sites in an elongated cleft formed by the handle, helical and central domains. The shift in CaM-binding sites on RyR2 is controlled by Ca binding to CaM, rather than to RyR2. Ca-CaM induces rotations and intradomain shifts of individual central domains, resulting in pore closure of the PCB95 and Ca-activated channel. By contrast, the pore of the ATP, caffeine and Ca-activated channel remains open in the presence of Ca-CaM, which suggests that Ca-CaM is one of the many competing modulators of RyR2 gating.

Jiang, Xin, et al. “Engineered XylE As a Tool for Mechanistic Investigation and Ligand Discovery of the Glucose Transporters GLUTs”. Cell Discov, vol. 5, 2019, p. 14, doi:10.1038/s41421-019-0082-1.
Liu, Ying, et al. “Cryo-EM Structure of L-Fucokinase GDP-Fucose Pyrophosphorylase (FKP) in Bacteroides Fragilis”. 2019. Protein Cell, vol. 10, no. 5, 2019, pp. 365-9, doi:10.1007/s13238-018-0576-x.
Pan, Xiaojing, et al. “Molecular Basis for Pore Blockade of Human Na Channel Na1.2 by the μ-Conotoxin KIIIA”. 2019. Science, vol. 363, no. 6433, 2019, pp. 1309-13, doi:10.1126/science.aaw2999.

The voltage-gated sodium channel Na1.2 is responsible for the initiation and propagation of action potentials in the central nervous system. We report the cryo-electron microscopy structure of human Na1.2 bound to a peptidic pore blocker, the μ-conotoxin KIIIA, in the presence of an auxiliary subunit, β2, to an overall resolution of 3.0 angstroms. The immunoglobulin domain of β2 interacts with the shoulder of the pore domain through a disulfide bond. The 16-residue KIIIA interacts with the extracellular segments in repeats I to III, placing Lys at the entrance to the selectivity filter. Many interacting residues are specific to Na1.2, revealing a molecular basis for KIIIA specificity. The structure establishes a framework for the rational design of subtype-specific blockers for Na channels.

Qian, Hongwu, et al. “Inhibition of Tetrameric Patched1 by Sonic Hedgehog through an Asymmetric Paradigm”. 2019. Nat Commun, vol. 10, no. 1, 2019, p. 2320, doi:10.1038/s41467-019-10234-9.

The Hedgehog (Hh) pathway controls embryonic development and postnatal tissue maintenance and regeneration. Inhibition of Hh receptor Patched (Ptch) by the Hh ligands relieves suppression of signaling cascades. Here, we report the cryo-EM structure of tetrameric Ptch1 in complex with the palmitoylated N-terminal signaling domain of human Sonic hedgehog (ShhN) at a 4:2 stoichiometric ratio. The structure shows that four Ptch1 protomers are organized as a loose dimer of dimers. Each dimer binds to one ShhN through two distinct inhibitory interfaces, one mainly through the N-terminal peptide and the palmitoyl moiety of ShhN and the other through the Ca-mediated interface on ShhN. Map comparison reveals that the cholesteryl moiety of native ShhN occupies a recently identified extracellular steroid binding pocket in Ptch1. Our structure elucidates the tetrameric assembly of Ptch1 and suggests an asymmetric mode of action of the Hh ligands for inhibiting the potential cholesterol transport activity of Ptch1.

Shen, Huaizong, et al. “Structures of Human Na1.7 Channel in Complex With Auxiliary Subunits and Animal Toxins”. 2019. Science, vol. 363, no. 6433, 2019, pp. 1303-8, doi:10.1126/science.aaw2493.

Voltage-gated sodium channel Na1.7 represents a promising target for pain relief. Here we report the cryo-electron microscopy structures of the human Na1.7-β1-β2 complex bound to two combinations of pore blockers and gating modifier toxins (GMTs), tetrodotoxin with protoxin-II and saxitoxin with huwentoxin-IV, both determined at overall resolutions of 3.2 angstroms. The two structures are nearly identical except for minor shifts of voltage-sensing domain II (VSD), whose S3-S4 linker accommodates the two GMTs in a similar manner. One additional protoxin-II sits on top of the S3-S4 linker in VSD The structures may represent an inactivated state with all four VSDs "up" and the intracellular gate closed. The structures illuminate the path toward mechanistic understanding of the function and disease of Na1.7 and establish the foundation for structure-aided development of analgesics.

Zhao, Yanyu, et al. “Cryo-EM Structures of Apo and Antagonist-Bound Human Ca3.1”. 2019. Nature, vol. 576, no. 7787, 2019, pp. 492-7, doi:10.1038/s41586-019-1801-3.

Among the ten subtypes of mammalian voltage-gated calcium (Ca) channels, Ca3.1-Ca3.3 constitute the T-type, or the low-voltage-activated, subfamily, the abnormal activities of which are associated with epilepsy, psychiatric disorders and pain. Here we report the cryo-electron microscopy structures of human Ca3.1 alone and in complex with a highly Ca3-selective blocker, Z944, at resolutions of 3.3 Å and 3.1 Å, respectively. The arch-shaped Z944 molecule reclines in the central cavity of the pore domain, with the wide end inserting into the fenestration on the interface between repeats II and III, and the narrow end hanging above the intracellular gate like a plug. The structures provide the framework for comparative investigation of the distinct channel properties of different Ca subfamilies.

Zhao, Yanyu, et al. “Molecular Basis for Ligand Modulation of a Mammalian Voltage-Gated Ca Channel”. 2019. Cell, vol. 177, no. 6, 2019, pp. 1495-1506.e12, doi:10.1016/j.cell.2019.04.043.

The L-type voltage-gated Ca (Ca) channels are modulated by various compounds exemplified by 1,4-dihydropyridines (DHP), benzothiazepines (BTZ), and phenylalkylamines (PAA), many of which have been used for characterizing channel properties and for treatment of hypertension and other disorders. Here, we report the cryoelectron microscopy (cryo-EM) structures of Ca1.1 in complex with archetypal antagonistic drugs, nifedipine, diltiazem, and verapamil, at resolutions of 2.9 Å, 3.0 Å, and 2.7 Å, respectively, and with a DHP agonist Bay K 8644 at 2.8 Å. Diltiazem and verapamil traverse the central cavity of the pore domain, directly blocking ion permeation. Although nifedipine and Bay K 8644 occupy the same fenestration site at the interface of repeats III and IV, the coordination details support previous functional observations that Bay K 8644 is less favored in the inactivated state. These structures elucidate the modes of action of different Ca ligands and establish a framework for structure-guided drug discovery.

2018

Deng, Dong, and Nieng Yan. “Crystallization and Structural Determination of the Human Glucose Transporters GLUT1 and GLUT3”. Methods Mol Biol, vol. 1713, 2018, pp. 15-29, doi:10.1007/978-1-4939-7507-5_2.
Overexpression, purification, and crystallization of eukaryotic membrane proteins represent a major challenge for structural biology. In recent years, we have solved the crystal structures of the human glucose transporters GLUT1 in the inward-open conformation at 3.17 Å resolution and GLUT3 in the outward-open and occluded conformations at 2.4 and 1.5 Å resolutions, respectively. Structural elucidation of these transporters in three distinct functional states reveal the molecular basis for the alternating access transport cycle of this prototypal solute carrier family. It established the molecular foundation for future dynamic and kinetic investigations of these GLUTs, and will likely facilitate structure-based ligand development. In this chapter, we present the detailed protocols of recombinant protein expression, purification, and crystallization of GLUT1 and GLUT3, which may help the pursuit of structural elucidation of other eukaryotic membrane proteins.
Gong, Xin, et al. “Structural Basis for the Recognition of Sonic Hedgehog by Human Patched1”. 2018. Science, vol. 361, no. 6402, 2018, doi:10.1126/science.aas8935.

The Hedgehog (Hh) pathway involved in development and regeneration is activated by the extracellular binding of Hh to the membrane receptor Patched (Ptch). We report the structures of human Ptch1 alone and in complex with the N-terminal domain of human Sonic hedgehog (ShhN) at resolutions of 3.9 and 3.6 angstroms, respectively, as determined by cryo-electron microscopy. Ptch1 comprises two interacting extracellular domains, ECD1 and ECD2, and 12 transmembrane segments (TMs), with TMs 2 to 6 constituting the sterol-sensing domain (SSD). Two steroid-shaped densities are resolved in both structures, one enclosed by ECD1/2 and the other in the membrane-facing cavity of the SSD. Structure-guided mutational analysis shows that interaction between ShhN and Ptch1 is steroid-dependent. The structure of a steroid binding-deficient Ptch1 mutant displays pronounced conformational rearrangements.

Gong, Deshun, et al. “Structure of the Human Plasma Membrane Ca-ATPase 1 in Complex With Its Obligatory Subunit Neuroplastin”. 2018. Nat Commun, vol. 9, no. 1, 2018, p. 3623, doi:10.1038/s41467-018-06075-7.

Plasma membrane Ca-ATPases (PMCAs) are key regulators of global Ca homeostasis and local intracellular Ca dynamics. Recently, Neuroplastin (NPTN) and basigin were identified as previously unrecognized obligatory subunits of PMCAs that dramatically increase the efficiency of PMCA-mediated Ca clearance. Here, we report the cryo-EM structure of human PMCA1 (hPMCA1) in complex with NPTN at a resolution of 4.1 Å for the overall structure and 3.9 Å for the transmembrane domain. The single transmembrane helix of NPTN interacts with the TM-linker and TM10 of hPMCA1. The subunits are required for the hPMCA1 functional activity. The NPTN-bound hPMCA1 closely resembles the E1-Mg structure of endo(sarco)plasmic reticulum Ca ATPase and the Ca site is exposed through a large open cytoplasmic pathway. This structure provides insight into how the subunits bind to the PMCAs and serves as an important basis for understanding the functional mechanisms of this essential calcium pump family.

Pan, Xiaojing, et al. “Structure of the Human Voltage-Gated Sodium Channel Na1.4 in Complex With β1”. 2018. Science, vol. 362, no. 6412, 2018, doi:10.1126/science.aau2486.

Voltage-gated sodium (Na) channels, which are responsible for action potential generation, are implicated in many human diseases. Despite decades of rigorous characterization, the lack of a structure of any human Na channel has hampered mechanistic understanding. Here, we report the cryo-electron microscopy structure of the human Na1.4-β1 complex at 3.2-Å resolution. Accurate model building was made for the pore domain, the voltage-sensing domains, and the β1 subunit, providing insight into the molecular basis for Na permeation and kinetic asymmetry of the four repeats. Structural analysis of reported functional residues and disease mutations corroborates an allosteric blocking mechanism for fast inactivation of Na channels. The structure provides a path toward mechanistic investigation of Na channels and drug discovery for Na channelopathies.

Shen, Huaizong, et al. “Structural Basis for the Modulation of Voltage-Gated Sodium Channels by Animal Toxins”. 2018. Science, vol. 362, no. 6412, 2018, doi:10.1126/science.aau2596.

Animal toxins that modulate the activity of voltage-gated sodium (Na) channels are broadly divided into two categories-pore blockers and gating modifiers. The pore blockers tetrodotoxin (TTX) and saxitoxin (STX) are responsible for puffer fish and shellfish poisoning in humans, respectively. Here, we present structures of the insect Na channel NaPaS bound to a gating modifier toxin Dc1a at 2.8 angstrom-resolution and in the presence of TTX or STX at 2.6-Å and 3.2-Å resolution, respectively. Dc1a inserts into the cleft between VSD and the pore of NaPaS, making key contacts with both domains. The structures with bound TTX or STX reveal the molecular details for the specific blockade of Na access to the selectivity filter from the extracellular side by these guanidinium toxins. The structures shed light on structure-based development of Na channel drugs.

Yan, Renhong, et al. “Human SEIPIN Binds Anionic Phospholipids”. 2018. Dev Cell, vol. 47, no. 2, 2018, pp. 248-256.e4, doi:10.1016/j.devcel.2018.09.010.

The biogenesis of lipid droplets (LDs) and the development of adipocytes are two key aspects of mammalian fat storage. SEIPIN, an integral membrane protein of the endoplasmic reticulum (ER), plays a critical role in both LD formation and adipogenesis. The molecular function of SEIPIN, however, has yet to be elucidated. Here, we report the cryogenic electron microscopy structure of human SEIPIN at 3.8 Å resolution. SEIPIN exists as an undecamer, and this oligomerization state is critical for its physiological function. The evolutionarily conserved lumenal domain of SEIPIN forms an eight-stranded β sandwich fold. Both full-length SEIPIN and its lumenal domain can bind anionic phospholipids including phosphatidic acid. Our results suggest that SEIPIN forms a scaffold that helps maintain phospholipid homeostasis and surface tension of the ER.

Zhang, Juanrong, et al. “Simulating the Ion Permeation and Ion Selection for a Eukaryotic Voltage-Gated Sodium Channel NaPaS”. 2018. Protein Cell, vol. 9, no. 6, 2018, pp. 580-5, doi:10.1007/s13238-018-0522-y.

2017

Huang, Weiyun, et al. “Structure-Based Assessment of Disease-Related Mutations in Human Voltage-Gated Sodium Channels”. 2017. Protein Cell, vol. 8, no. 6, 2017, pp. 401-38, doi:10.1007/s13238-017-0372-z.

Voltage-gated sodium (Na) channels are essential for the rapid upstroke of action potentials and the propagation of electrical signals in nerves and muscles. Defects of Na channels are associated with a variety of channelopathies. More than 1000 disease-related mutations have been identified in Na channels, with Na1.1 and Na1.5 each harboring more than 400 mutations. Na channels represent major targets for a wide array of neurotoxins and drugs. Atomic structures of Na channels are required to understand their function and disease mechanisms. The recently determined atomic structure of the rabbit voltage-gated calcium (Ca) channel Ca1.1 provides a template for homology-based structural modeling of the evolutionarily related Na channels. In this Resource article, we summarized all the reported disease-related mutations in human Na channels, generated a homologous model of human Na1.7, and structurally mapped disease-associated mutations. Before the determination of structures of human Na channels, the analysis presented here serves as the base framework for mechanistic investigation of Na channelopathies and for potential structure-based drug discovery.

Ke, Meng, et al. “Molecular Determinants for the Thermodynamic and Functional Divergence of Uniporter GLUT1 and Proton Symporter XylE”. 2017. PLoS Comput Biol, vol. 13, no. 6, 2017, p. e1005603, doi:10.1371/journal.pcbi.1005603.

GLUT1 facilitates the down-gradient translocation of D-glucose across cell membrane in mammals. XylE, an Escherichia coli homolog of GLUT1, utilizes proton gradient as an energy source to drive uphill D-xylose transport. Previous studies of XylE and GLUT1 suggest that the variation between an acidic residue (Asp27 in XylE) and a neutral one (Asn29 in GLUT1) is a key element for their mechanistic divergence. In this work, we combined computational and biochemical approaches to investigate the mechanism of proton coupling by XylE and the functional divergence between GLUT1 and XylE. Using molecular dynamics simulations, we evaluated the free energy profiles of the transition between inward- and outward-facing conformations for the apo proteins. Our results revealed the correlation between the protonation state and conformational preference in XylE, which is supported by the crystal structures. In addition, our simulations suggested a thermodynamic difference between XylE and GLUT1 that cannot be explained by the single residue variation at the protonation site. To understand the molecular basis, we applied Bayesian network models to analyze the alteration in the architecture of the hydrogen bond networks during conformational transition. The models and subsequent experimental validation suggest that multiple residue substitutions are required to produce the thermodynamic and functional distinction between XylE and GLUT1. Despite the lack of simulation studies with substrates, these computational and biochemical characterizations provide unprecedented insight into the mechanistic difference between proton symporters and uniporters.

Qian, Hongwu, et al. “Structure of the Human Lipid Exporter ABCA1”. 2017. Cell, vol. 169, no. 7, 2017, pp. 1228-1239.e10, doi:10.1016/j.cell.2017.05.020.

ABCA1, an ATP-binding cassette (ABC) subfamily A exporter, mediates the cellular efflux of phospholipids and cholesterol to the extracellular acceptor apolipoprotein A-I (apoA-I) for generation of nascent high-density lipoprotein (HDL). Mutations of human ABCA1 are associated with Tangier disease and familial HDL deficiency. Here, we report the cryo-EM structure of human ABCA1 with nominal resolutions of 4.1 Å for the overall structure and 3.9 Å for the massive extracellular domain. The nucleotide-binding domains (NBDs) display a nucleotide-free state, while the two transmembrane domains (TMDs) contact each other through a narrow interface in the intracellular leaflet of the membrane. In addition to TMDs and NBDs, two extracellular domains of ABCA1 enclose an elongated hydrophobic tunnel. Structural mapping of dozens of disease-related mutations allows potential interpretation of their diverse pathogenic mechanisms. Structural-based analysis suggests a plausible "lateral access" mechanism for ABCA1-mediated lipid export that may be distinct from the conventional alternating-access paradigm.

Shen, Huaizong, et al. “Structure of a Eukaryotic Voltage-Gated Sodium Channel at Near-Atomic Resolution”. 2017. Science, vol. 355, no. 6328, 2017, doi:10.1126/science.aal4326.

Voltage-gated sodium (Na) channels are responsible for the initiation and propagation of action potentials. They are associated with a variety of channelopathies and are targeted by multiple pharmaceutical drugs and natural toxins. Here, we report the cryogenic electron microscopy structure of a putative Na channel from American cockroach (designated NaPaS) at 3.8 angstrom resolution. The voltage-sensing domains (VSDs) of the four repeats exhibit distinct conformations. The entrance to the asymmetric selectivity filter vestibule is guarded by heavily glycosylated and disulfide bond-stabilized extracellular loops. On the cytoplasmic side, a conserved amino-terminal domain is placed below VSD, and a carboxy-terminal domain binds to the III-IV linker. The structure of NaPaS establishes an important foundation for understanding function and disease mechanism of Na and related voltage-gated calcium channels.

Wu, Jianping, et al. “Structure-Function Relationship of the Voltage-Gated Calcium Channel Ca1.1 Complex”. Adv Exp Med Biol, vol. 981, 2017, pp. 23-39, doi:10.1007/978-3-319-55858-5_2.
Voltage-gated calcium (Ca) channels are miniature membrane transistors that convert membrane electrical signals to intracellular Ca transients that trigger many physiological events. In mammals, there are ten subtypes of Ca channel, among which Ca1.1 is the first Caα1 to be cloned. Ca1.1 is specified for the excitation-contraction coupling of skeletal muscles, and has been a prototype in the structural investigations of Ca channels. This article summarized the recent advances in the structural elucidation of Ca1.1 and the mechanistic insights derived from the 3.6 Å structure obtained using single-particle, electron cryomicroscopy. The structure of the Ca1.1 complex established the framework for mechanistic understanding of excitation-contraction coupling and provides the template for molecular interpretations of the functions and disease mechanisms of Ca and Na channels.
Yan, Nieng. “A Glimpse of Membrane Transport through Structures-Advances in the Structural Biology of the GLUT Glucose Transporters”. 2017. J Mol Biol, vol. 429, no. 17, 2017, pp. 2710-25, doi:10.1016/j.jmb.2017.07.009.

The cellular uptake of glucose is an essential physiological process, and movement of glucose across biological membranes requires specialized transporters. The major facilitator superfamily glucose transporters GLUTs, encoded by the SLC2A genes, have been a paradigm for functional, mechanistic, and structural understanding of solute transport in the past century. This review starts with a glimpse into the structural biology of membrane proteins and particularly membrane transport proteins, enumerating the landmark structures in the past 25years. The recent breakthrough in the structural elucidation of GLUTs is then elaborated following a brief overview of the research history of these archetypal transporters, their functional specificity, and physiological and pathophysiological significances. Structures of GLUT1, GLUT3, and GLUT5 in distinct transport and/or ligand-binding states reveal detailed mechanisms of the alternating access transport cycle and substrate recognition, and thus illuminate a path by which structure-based drug design may be applied to help discover novel therapeutics against several debilitating human diseases associated with GLUT malfunction and/or misregulation.

Yan, Zhen, et al. “Structure of the Na1.4-β1 Complex from Electric Eel”. 2017. Cell, vol. 170, no. 3, 2017, pp. 470-482.e11, doi:10.1016/j.cell.2017.06.039.

Voltage-gated sodium (Na) channels initiate and propagate action potentials. Here, we present the cryo-EM structure of EeNa1.4, the Na channel from electric eel, in complex with the β1 subunit at 4.0 Å resolution. The immunoglobulin domain of β1 docks onto the extracellular L5 and L6 loops of EeNa1.4 via extensive polar interactions, and the single transmembrane helix interacts with the third voltage-sensing domain (VSD). The VSDs exhibit "up" conformations, while the intracellular gate of the pore domain is kept open by a digitonin-like molecule. Structural comparison with closed NaPaS shows that the outward transfer of gating charges is coupled to the iris-like pore domain dilation through intricate force transmissions involving multiple channel segments. The IFM fast inactivation motif on the III-IV linker is plugged into the corner enclosed by the outer S4-S5 and inner S6 segments in repeats III and IV, suggesting a potential allosteric blocking mechanism for fast inactivation.

Yu, Xinzhe, et al. “Dimeric Structure of the uracil:Proton Symporter UraA Provides Mechanistic Insights into the SLC4 23 26 Transporters”. 2017. Cell Res, vol. 27, no. 8, 2017, pp. 1020-33, doi:10.1038/cr.2017.83.

The Escherichia coli uracil:proton symporter UraA is a prototypical member of the nucleobase/ascorbate transporter (NAT) or nucleobase/cation symporter 2 (NCS2) family, which corresponds to the human solute carrier family SLC23. UraA consists of 14 transmembrane segments (TMs) that are organized into two distinct domains, the core domain and the gate domain, a structural fold that is also shared by the SLC4 and SLC26 transporters. Here we present the crystal structure of UraA bound to uracil in an occluded state at 2.5 Å resolution. Structural comparison with the previously reported inward-open UraA reveals pronounced relative motions between the core domain and the gate domain as well as intra-domain rearrangement of the gate domain. The occluded UraA forms a dimer in the structure wherein the gate domains are sandwiched by two core domains. In vitro and in vivo biochemical characterizations show that UraA is at equilibrium between dimer and monomer in all tested detergent micelles, while dimer formation is necessary for the transport activity. Structural comparison between the dimeric UraA and the recently reported inward-facing dimeric UapA provides important insight into the transport mechanism of SLC23 transporters.

2016

Bai, Xiao-Chen, et al. “The Central Domain of RyR1 Is the Transducer for Long-Range Allosteric Gating of Channel Opening”. 2016. Cell Res, vol. 26, no. 9, 2016, pp. 995-1006, doi:10.1038/cr.2016.89.

The ryanodine receptors (RyRs) are intracellular calcium channels responsible for rapid release of Ca(2+) from the sarcoplasmic/endoplasmic reticulum (SR/ER) to the cytoplasm, which is essential for the excitation-contraction (E-C) coupling of cardiac and skeletal muscles. The near-atomic resolution structure of closed RyR1 revealed the molecular details of this colossal channel, while the long-range allosteric gating mechanism awaits elucidation. Here, we report the cryo-EM structures of rabbit RyR1 in three closed conformations at about 4 Å resolution and an open state at 5.7 Å. Comparison of the closed RyR1 structures shows a breathing motion of the cytoplasmic platform, while the channel domain and its contiguous Central domain remain nearly unchanged. Comparison of the open and closed structures shows a dilation of the S6 tetrahelical bundle at the cytoplasmic gate that leads to channel opening. During the pore opening, the cytoplasmic "O-ring" motif of the channel domain and the U-motif of the Central domain exhibit coupled motion, while the Central domain undergoes domain-wise displacement. These structural analyses provide important insight into the E-C coupling in skeletal muscles and identify the Central domain as the transducer that couples the conformational changes of the cytoplasmic platform to the gating of the central pore.

Deng, Dong, and Nieng Yan. “GLUT, SGLT, and SWEET: Structural and Mechanistic Investigations of the Glucose Transporters”. 2016. Protein Sci, vol. 25, no. 3, 2016, pp. 546-58, doi:10.1002/pro.2858.

Glucose is the primary fuel to life on earth. Cellular uptake of glucose is a fundamental process for metabolism, growth, and homeostasis. Three families of secondary glucose transporters have been identified in human, including the major facilitator superfamily glucose facilitators GLUTs, the sodium-driven glucose symporters SGLTs, and the recently identified SWEETs. Structures of representative members or their prokaryotic homologs of all three families were obtained. This review focuses on the recent advances in the structural elucidation of the glucose transporters and the mechanistic insights derived from these structures, including the molecular basis for substrate recognition, alternating access, and stoichiometric coupling of co-transport.

Gong, Xin, et al. “Structural Insights into the Niemann-Pick C1 (NPC1)-Mediated Cholesterol Transfer and Ebola Infection”. 2016. Cell, vol. 165, no. 6, 2016, pp. 1467-78, doi:10.1016/j.cell.2016.05.022.

Niemann-Pick disease type C (NPC) is associated with mutations in NPC1 and NPC2, whose gene products are key players in the endosomal/lysosomal egress of low-density lipoprotein-derived cholesterol. NPC1 is also the intracellular receptor for Ebola virus (EBOV). Here, we present a 4.4 Å structure of full-length human NPC1 and a low-resolution reconstruction of NPC1 in complex with the cleaved glycoprotein (GPcl) of EBOV, both determined by single-particle electron cryomicroscopy. NPC1 contains 13 transmembrane segments (TMs) and three distinct lumenal domains A (also designated NTD), C, and I. TMs 2-13 exhibit a typical resistance-nodulation-cell division fold, among which TMs 3-7 constitute the sterol-sensing domain conserved in several proteins involved in cholesterol metabolism and signaling. A trimeric EBOV-GPcl binds to one NPC1 monomer through the domain C. Our structural and biochemical characterizations provide an important framework for mechanistic understanding of NPC1-mediated intracellular cholesterol trafficking and Ebola virus infection.

Gong, Xin, et al. “Complex Structure of the Fission Yeast SREBP-SCAP Binding Domains Reveals an Oligomeric Organization”. 2016. Cell Res, vol. 26, no. 11, 2016, pp. 1197-11, doi:10.1038/cr.2016.123.

Sterol regulatory element-binding protein (SREBP) transcription factors are master regulators of cellular lipid homeostasis in mammals and oxygen-responsive regulators of hypoxic adaptation in fungi. SREBP C-terminus binds to the WD40 domain of SREBP cleavage-activating protein (SCAP), which confers sterol regulation by controlling the ER-to-Golgi transport of the SREBP-SCAP complex and access to the activating proteases in the Golgi. Here, we biochemically and structurally show that the carboxyl terminal domains (CTD) of Sre1 and Scp1, the fission yeast SREBP and SCAP, form a functional 4:4 oligomer and Sre1-CTD forms a dimer of dimers. The crystal structure of Sre1-CTD at 3.5 Å and cryo-EM structure of the complex at 5.4 Å together with in vitro biochemical evidence elucidate three distinct regions in Sre1-CTD required for Scp1 binding, Sre1-CTD dimerization and tetrameric formation. Finally, these structurally identified domains are validated in a cellular context, demonstrating that the proper 4:4 oligomeric complex formation is required for Sre1 activation.

Jiang, Xin, et al. “Crystal Structure of a LacY-Nanobody Complex in a Periplasmic-Open Conformation”. 2016. Proc Natl Acad Sci U S A, vol. 113, no. 44, 2016, pp. 12420-5, doi:10.1073/pnas.1615414113.

The lactose permease of Escherichia coli (LacY), a dynamic polytopic membrane protein, catalyzes galactoside-H symport and operates by an alternating access mechanism that exhibits multiple conformations, the distribution of which is altered by sugar binding. We have developed single-domain camelid nanobodies (Nbs) against a mutant in an outward (periplasmic)-open conformation to stabilize this state of the protein. Here we describe an X-ray crystal structure of a complex between a double-Trp mutant (Gly46→Trp/Gly262→Trp) and an Nb in which free access to the sugar-binding site from the periplasmic cavity is observed. The structure confirms biochemical data indicating that the Nb binds stoichiometrically with nanomolar affinity to the periplasmic face of LacY primarily to the C-terminal six-helix bundle. The structure is novel because the pathway to the sugar-binding site is constricted and the central cavity containing the galactoside-binding site is empty. Although Phe27 narrows the periplasmic cavity, sugar is freely accessible to the binding site. Remarkably, the side chains directly involved in binding galactosides remain in the same position in the absence or presence of bound sugar.

Peng, Wei, et al. “Structural Basis for the Gating Mechanism of the Type 2 Ryanodine Receptor RyR2”. 2016. Science, vol. 354, no. 6310, 2016, doi:10.1126/science.aah5324.

RyR2 is a high-conductance intracellular calcium (Ca) channel that controls the release of Ca from the sarco(endo)plasmic reticulum of a variety of cells. Here, we report the structures of RyR2 from porcine heart in both the open and closed states at near-atomic resolutions determined using single-particle electron cryomicroscopy. Structural comparison reveals a breathing motion of the overall cytoplasmic region resulted from the interdomain movements of amino-terminal domains (NTDs), Helical domains, and Handle domains, whereas almost no intradomain shifts are observed in these armadillo repeats-containing domains. Outward rotations of the Central domains, which integrate the conformational changes of the cytoplasmic region, lead to the dilation of the cytoplasmic gate through coupled motions. Our structural and mutational characterizations provide important insights into the gating and disease mechanism of RyRs.

Wu, Jianping, et al. “Structure of the Voltage-Gated Calcium Channel Ca(v)1.1 at 3.6 Å Resolution”. 2016. Nature, vol. 537, no. 7619, 2016, pp. 191-6, doi:10.1038/nature19321.

The voltage-gated calcium (Ca) channels convert membrane electrical signals to intracellular Ca-mediated events. Among the ten subtypes of Ca channel in mammals, Ca1.1 is specified for the excitation-contraction coupling of skeletal muscles. Here we present the cryo-electron microscopy structure of the rabbit Ca1.1 complex at a nominal resolution of 3.6 Å. The inner gate of the ion-conducting α1-subunit is closed and all four voltage-sensing domains adopt an 'up' conformation, suggesting a potentially inactivated state. The extended extracellular loops of the pore domain, which are stabilized by multiple disulfide bonds, form a windowed dome above the selectivity filter. One side of the dome provides the docking site for the α2δ-1-subunit, while the other side may attract cations through its negative surface potential. The intracellular I-II and III-IV linker helices interact with the β-subunit and the carboxy-terminal domain of α1, respectively. Classification of the particles yielded two additional reconstructions that reveal pronounced displacement of β and adjacent elements in α1. The atomic model of the Ca1.1 complex establishes a foundation for mechanistic understanding of excitation-contraction coupling and provides a three-dimensional template for molecular interpretations of the functions and disease mechanisms of Ca and Na channels.

2015

Deng, Dong, et al. “Molecular Basis of Ligand Recognition and Transport by Glucose Transporters”. 2015. Nature, vol. 526, no. 7573, 2015, pp. 391-6, doi:10.1038/nature14655.

The major facilitator superfamily glucose transporters, exemplified by human GLUT1-4, have been central to the study of solute transport. Using lipidic cubic phase crystallization and microfocus X-ray diffraction, we determined the structure of human GLUT3 in complex with D-glucose at 1.5 Å resolution in an outward-occluded conformation. The high-resolution structure allows discrimination of both α- and β-anomers of D-glucose. Two additional structures of GLUT3 bound to the exofacial inhibitor maltose were obtained at 2.6 Å in the outward-open and 2.4 Å in the outward-occluded states. In all three structures, the ligands are predominantly coordinated by polar residues from the carboxy terminal domain. Conformational transition from outward-open to outward-occluded entails a prominent local rearrangement of the extracellular part of transmembrane segment TM7. Comparison of the outward-facing GLUT3 structures with the inward-open GLUT1 provides insights into the alternating access cycle for GLUTs, whereby the C-terminal domain provides the primary substrate-binding site and the amino-terminal domain undergoes rigid-body rotation with respect to the C-terminal domain. Our studies provide an important framework for the mechanistic and kinetic understanding of GLUTs and shed light on structure-guided ligand design.

Fernández-Capetillo, Óscar, et al. “Hopes for the Year Ahead”. 2015. Nature, vol. 517, no. 7532, 2015, pp. 111-3, doi:10.1038/nj7532-111a.
Gong, Xin, et al. “Structure of the WD40 Domain of SCAP from Fission Yeast Reveals the Molecular Basis for SREBP Recognition”. 2015. Cell Res, vol. 25, no. 4, 2015, pp. 401-11, doi:10.1038/cr.2015.32.

The sterol regulatory element-binding protein (SREBP) and SREBP cleavage-activating protein (SCAP) are central players in the SREBP pathway, which control the cellular lipid homeostasis. SCAP binds to SREBP through their carboxyl (C) domains and escorts SREBP from the endoplasmic reticulum to the Golgi upon sterol depletion. A conserved pathway, with the homologues of SREBP and SCAP being Sre1 and Scp1, was identified in fission yeast Schizosaccharomyces pombe. Here we report the in vitro reconstitution of the complex between the C domains of Sre1 and Scp1 as well as the crystal structure of the WD40 domain of Scp1 at 2.1 Å resolution. The structure reveals an eight-bladed β-propeller that exhibits several distinctive features from a canonical WD40 repeat domain. Structural and biochemical characterization led to the identification of two Scp1 elements that are involved in Sre1 recognition, an Arg/Lys-enriched surface patch on the top face of the WD40 propeller and a 30-residue C-terminal tail. The structural and biochemical findings were corroborated by in vivo examinations. These studies serve as a framework for the mechanistic understanding and further functional characterization of the SREBP and SCAP proteins in fission yeast and higher organisms.

Ren, Ruobing, et al. “PROTEIN STRUCTURE. Crystal Structure of a Mycobacterial Insig Homolog Provides Insight into How These Sensors Monitor Sterol Levels”. 2015. Science, vol. 349, no. 6244, 2015, pp. 187-91, doi:10.1126/science.aab1091.

Insulin-induced gene 1 (Insig-1) and Insig-2 are endoplasmic reticulum membrane-embedded sterol sensors that regulate the cellular accumulation of sterols. Despite their physiological importance, the structural information on Insigs remains limited. Here we report the high-resolution structures of MvINS, an Insig homolog from Mycobacterium vanbaalenii. MvINS exists as a homotrimer. Each protomer comprises six transmembrane segments (TMs), with TM3 and TM4 contributing to homotrimerization. The six TMs enclose a V-shaped cavity that can accommodate a diacylglycerol molecule. A homology-based structural model of human Insig-2, together with biochemical characterizations, suggest that the central cavity of Insig-2 accommodates 25-hydroxycholesterol, whereas TM3 and TM4 engage in Scap binding. These analyses provide an important framework for further functional and mechanistic understanding of Insig proteins and the sterol regulatory element-binding protein pathway.