Large Membrane Protein Research Articles

Characterization of Drosophila GDNF Receptor-Like and Evidence for Its Evolutionarily Conserved Interaction with Neural Cell Adhesion Molecule (NCAM)/FasII

BackgroundGlial cell line-derived neurotrophic factor (GDNF) family ligands are secreted growth factors distantly related to the TGF-β superfamily. In mammals, they bind to the GDNF family receptor α (Gfrα) and signal through the Ret receptor tyrosine kinase. In order to gain insight into the evolution of the Ret-Gfr-Gdnf signaling system, we have cloned and characterized the first invertebrate Gfr-like cDNA (DmGfrl) from Drosophila melanogaster and generated a DmGfrl mutant allele.ResultsWe found that DmGfrl encodes a large GPI-anchored membrane protein with four GFR-like domains. In line with the fact that insects lack GDNF ligands, DmGfrl mediated neither Drosophila Ret phosphorylation nor mammalian RET phosphorylation. In situ hybridization analysis revealed that DmGfrl is expressed in the central and peripheral nervous systems throughout Drosophila development, but, surprisingly, DmGfrl and DmRet expression patterns were largely non-overlapping. We generated a DmGfrl null allele by genomic FLP deletion and found that both DmGfrl null females and males are viable but display fertility defects. The female fertility defect manifested as dorsal appendage malformation, small size and reduced viability of eggs laid by mutant females. In male flies DmGfrl interacted genetically with the Drosophila Ncam (neural cell adhesion molecule) homolog FasII to regulate fertility.ConclusionOur results suggest that Ret and Gfrl did not function as an in cis receptor-coreceptor pair before the emergence of GDNF family ligands, and that the Ncam-Gfr interaction predated the in cis Ret-Gfr interaction in evolution. The fertility defects that we describe in DmGfrl null flies suggest that GDNF receptor-like has an evolutionarily ancient role in regulating male fertility and a previously unrecognized role in regulating oogenesis.SignificanceThese results shed light on the evolutionary aspects of the structure, expression and function of Ret-Gfrα and Ncam-Gfrα signaling complexes.

Structure of the vacuolar-type ATPase from Saccharomyces cerevisiae at 11-Å resolution

Vacuolar-type ATPases (V-type ATPases) in eukaryotic cells are large membrane protein complexes that acidify various intracellular compartments. The enzymes are regulated by dissociation of the V(1) and V(O) regions of the complex. Here we present the structure of the Saccharomyces cerevisiae V-type ATPase at 11-Å resolution by cryo-EM of protein particles in ice. The structure explains many cross-linking and protein interaction studies. Docking of crystal structures suggests that inhibition of ATPase activity by the dissociated V(1) region involves rearrangement of the N- and C-terminal domains of subunit H and also suggests how this inhibition is triggered upon dissociation. We provide support for this model by demonstrating that mutation of subunit H to increase the rigidity of the linker between its two domains decreases its ability to inhibit ATPase activity.

LAMBADA and InflateGRO2: Efficient Membrane Alignment and Insertion of Membrane Proteins for Molecular Dynamics Simulations

At the beginning of each molecular dynamics membrane simulation stands the generation of a suitable starting structure which includes the working steps of aligning membrane and protein and seamlessly accommodating the protein in the membrane. Here we introduce two efficient and complementary methods based on pre-equilibrated membrane patches, automating these steps. Using a voxel-based cast of the coarse-grained protein, LAMBADA computes a hydrophilicity profile-derived scoring function based on which the optimal rotation and translation operations are determined to align protein and membrane. Employing an entirely geometrical approach, LAMBADA is independent from any precalculated data and aligns even large membrane proteins within minutes on a regular workstation. LAMBADA is the first tool performing the entire alignment process automatically while providing the user with the explicit 3D coordinates of the aligned protein and membrane. The second tool is an extension of the InflateGRO method addressing the shortcomings of its predecessor in a fully automated workflow. Determining the exact number of overlapping lipids based on the area occupied by the protein and restricting expansion, compression and energy minimization steps to a subset of relevant lipids through automatically calculated and system-optimized operation parameters, InflateGRO2 yields optimal lipid packing and reduces lipid vacuum exposure to a minimum preserving as much of the equilibrated membrane structure as possible. Applicable to atomistic and coarse grain structures in MARTINI format, InflateGRO2 offers high accuracy, fast performance, and increased application flexibility permitting the easy preparation of systems exhibiting heterogeneous lipid composition as well as embedding proteins into multiple membranes. Both tools can be used separately, in combination with other methods, or in tandem permitting a fully automated workflow while retaining a maximum level of usage control and flexibility. To assess the performance of both methods, we carried out test runs using 22 membrane proteins of different size and transmembrane structure.

Split-Doa10: A Naturally Split Polytopic Eukaryotic Membrane Protein Generated by Fission of a Nuclear Gene

Large polytopic membrane proteins often derive from duplication and fusion of genes for smaller proteins. The reverse process, splitting of a membrane protein by gene fission, is rare and has been studied mainly with artificially split proteins. Fragments of a split membrane protein may associate and reconstitute the function of the larger protein. Most examples of naturally split membrane proteins are from bacteria or eukaryotic organelles, and their exact history is usually poorly understood. Here, we describe a nuclear-encoded split membrane protein, split-Doa10, in the yeast Kluyveromyces lactis. In most species, Doa10 is encoded as a single polypeptide with 12–16 transmembrane helices (TMs), but split-KlDoa10 is encoded as two fragments, with the split occurring between TM2 and TM3. The two fragments assemble into an active ubiquitin-protein ligase. The K. lactis DOA10 locus has two ORFs separated by a 508-bp intervening sequence (IVS). A promoter within the IVS drives expression of the C-terminal KlDoa10 fragment. At least four additional Kluyveromyces species contain an IVS in the DOA10 locus, in contrast to even closely related genera, allowing dating of the fission event to the base of the genus. The upstream Kluyveromyces Doa10 fragment with its N-terminal RING-CH and two TMs resembles many metazoan MARCH (Membrane-Associated RING-CH) and related viral RING-CH proteins, suggesting that gene splitting may have contributed to MARCH enzyme diversification. Split-Doa10 is the first unequivocal case of a split membrane protein where fission occurred in a nuclear-encoded gene. Such a split may allow divergent functions for the individual protein segments.

Fks1 and Fks2 Are Functionally Redundant but Differentially Regulated in Candida glabrata: Implications for Echinocandin Resistance

The echinocandins caspofungin, micafungin, and anidulafungin, inhibitors of cell wall β-1,3-glucan synthesis, were recently elevated to first-line agents for treating infections due to the azole-refractory yeast Candida glabrata. In Candida albicans, echinocandin resistance is strictly associated with mutations in Fks1, a large integral membrane protein and putative β-1,3-glucan synthase, while mutations in both Fks1 and its paralog Fks2 (but not Fks3) have been associated with resistance in C. glabrata. To further explore their function, regulation, and role in resistance, C. glabrata fks genes were disrupted and subjected to mutational analysis, and their differential regulation was explored. An fks1Δ fks2Δ double disruptant was not able to be generated; otherwise, all three single and remaining two double disruptants displayed normal growth and echinocandin susceptibility, indicating Fks1-Fks2 redundancy. Selection on echinocandin-containing medium for resistant mutants was dependent on strain background: only fks1Δ and fks1Δ fks3Δ strains consistently yielded mutants exhibiting high-level resistance, all with Fks2 hot spot 1 mutations. Thus, Fks1-Fks2 redundancy attenuates the rate of resistance; further analysis showed that it also attenuates the impact of resistance-conferring mutations. Growth of the fks1Δ and, especially, fks1Δ fks3Δ strains was specifically susceptible to the calcineurin inhibitor FK506. Relatedly, FK506 addition or calcineurin gene CMP2 disruption specifically reversed Fks2-mediated resistance of laboratory mutants and clinical isolates. RNA analysis suggests that transcriptional control is not the sole mechanism by which calcineurin modulates Fks2 activity.

High-throughput counter-diffusion capillary crystallization andin situdiffraction using high-pressure freezing in protein crystallography

Post-crystallization treatments such as manual fishing of crystals and soaking in cryoprotectant solutions, especially of large macromolecular complexes and membrane proteins, are cumbersome and often lead to crystal damage and reduced diffraction data quality. Here, a capillary crystallization plate is presented that simultaneously allows counter-diffusion crystallization at the nanolitre scale in a high-throughput screening mode, low-temperaturein situdiffraction data collection from crystals after cryoprotection and low-temperaturein situdata collection of crystals without the addition of any cryoprotectant after high-pressure (HP) freezing. The development of this plate and plunge cooling of crystals in the capillaries is a major step towards implementing automatedin situhigh-throughput crystal diffraction data collection at a synchrotron beamline. In combination with HP freezing this offers a new opportunity to obtain structural information from fragile crystals of supramolecular complexes that might otherwise not be feasible.

Topogenesis of heterologously expressed fragments of the human Y4 GPCR

Fragments of large membrane proteins have the potential to facilitate structural analysis by NMR, but their folding state remains a concern. Here we determined the quality of folding upon heterologous expression for a series of N- or C-terminally truncated fragments of the human Y4 G-protein coupled receptor, amounting to six different complementation pairs. As the individual fragments lack a specific function that could be used to ascertain proper folding, we instead assessed folding on a basic level by studying their membrane topology and by comparing it to well-established structural models of GPCRs. The topology of the fragments was determined using a reporter assay based on C-terminal green fluorescent protein- or alkaline phosphatase-fusions. N-terminal fusions to Lep or Mistic were used if a periplasmic orientation of the N-terminus of the fragments was expected based on predictions. Fragments fused to Mistic expressed at comparably high levels, whereas Lep fusions were produced to a much lower extent. Though none of the fragments exclusively adopted one orientation, often the correct topology predominated. In addition, systematic analysis of the fragment series suggested that the C-terminal half of the Y4 receptor is more important for adopting the correct topology than the N-terminal part. Using the detergent dodecylphosphocholine, selected fragments were solubilized from the membrane and proved sufficiently stable to allow purification. Finally, as a first step toward reconstituting a functional receptor from two fragments, we observed a physical interaction between complementing fragments pairs upon co-expression.

Compressed sensing reconstruction of undersampled 3D NOESY spectra: application to large membrane proteins

Central to structural studies of biomolecules are multidimensional experiments. These are lengthy to record due to the requirement to sample the full Nyquist grid. Time savings can be achieved through undersampling the indirectly-detected dimensions combined with non-Fourier Transform (FT) processing, provided the experimental signal-to-noise ratio is sufficient. Alternatively, resolution and signal-to-noise can be improved within a given experiment time. However, non-FT based reconstruction of undersampled spectra that encompass a wide signal dynamic range is strongly impeded by the non-linear behaviour of many methods, which further compromises the detection of weak peaks. Here we show, through an application to a larger α-helical membrane protein under crowded spectral conditions, the potential use of compressed sensing (CS) l (1)-norm minimization to reconstruct undersampled 3D NOESY spectra. Substantial signal overlap and low sensitivity make this a demanding application, which strongly benefits from the improvements in signal-to-noise and resolution per unit time achieved through the undersampling approach. The quality of the reconstructions is assessed under varying conditions. We show that the CS approach is robust to noise and, despite significant spectral overlap, is able to reconstruct high quality spectra from data sets recorded in far less than half the amount of time required for regular sampling.

BmVMP90, a large vitelline membrane protein of the domesticated silkmoth Bombyx mori, is an essential component of the developing ovarian follicle

We present the characterization of BmVMP90, a vitelline membrane protein (VMP) of the silkmoth Bombyx mori bearing similarities with dipteran VMPs whose existence had recently been suggested by an in silico analysis of the silkmoth genome and follicular cell RNA expression analyses. Using a specific antibody, we determine the presence of BmVMP90 protein in ovarian follicular cell extracts at the end of vitellogenesis and in vitelline membrane extracts but not in the chorion of fractionated eggshells isolated from ovulated follicles. Whole mount follicle immunofluorescence studies reveal a pattern of BmVMP90 deposition matching the «imprinted» pattern of follicular cells on the vitelline membrane surface. Antisense DNA-directed inhibition BmVMP90 expression in ex vivo cultures of early vitellogenic follicles produced a phenotype of kidney- or bean-shaped follicles with detached follicular epithelia, suggestive of the importance of BmVMP90 for the integrity of developing follicles and normal deposition of the chorion structure that follows vitelline membrane formation but no adverse effects on the execution of the follicular cell-imprinted program of choriogenesis per se.

Dynamics of a bacterial multidrug ABC transporter in the inward- and outward-facing conformations

The study of membrane proteins remains a challenging task, and approaches to unravel their dynamics are scarce. Here, we applied hydrogen/deuterium exchange (HDX) coupled to mass spectrometry to probe the motions of a bacterial multidrug ATP-binding cassette (ABC) transporter, BmrA, in the inward-facing (resting state) and outward-facing (ATP-bound) conformations. Trypsin digestion and global or local HDX support the transition between inward- and outward-facing conformations during the catalytic cycle of BmrA. However, in the resting state, peptides from the two intracellular domains, especially ICD2, show a much faster HDX than in the closed state. This shows that these two subdomains are very flexible in this conformation. Additionally, molecular dynamics simulations suggest a large fluctuation of the Cα positions from ICD2 residues in the inward-facing conformation of a related transporter, MsbA. These results highlight the unexpected flexibility of ABC exporters in the resting state and underline the power of HDX coupled to mass spectrometry to explore conformational changes and dynamics of large membrane proteins.

Accurate de novo structure prediction of large transmembrane protein domains using fragment-assembly and correlated mutation analysis

A new de novo protein structure prediction method for transmembrane proteins (FILM3) is described that is able to accurately predict the structures of large membrane proteins domains using an ensemble of two secondary structure prediction methods to guide fragment selection in combination with a scoring function based solely on correlated mutations detected in multiple sequence alignments. This approach has been validated by generating models for 28 membrane proteins with a diverse range of complex topologies and an average length of over 300 residues with results showing that TM-scores>0.5 can be achieved in almost every case following refinement using MODELLER. In one of the most impressive results, a model of mitochondrial cytochrome c oxidase polypeptide I was obtained with a TM-score>0.75 and an rmsd of only 5.7Å over all 514 residues. These results suggest that FILM3 could be applicable to a wide range of transmembrane proteins of as-yet-unknown 3D structure given sufficient homologous sequences.

The VC1777–VC1779 proteins are members of a sialic acid-specific subfamily of TRAP transporters (SiaPQM) and constitute the sole route of sialic acid uptake in the human pathogen Vibrio cholerae

Sialic acids are nine-carbon amino sugars that are present on all mucous membranes and are often used by bacteria as nutrients. In pathogenic Vibrio the genes for sialic acid catabolism (SAC) are known to be important for host colonization, yet the route for sialic acid uptake is not proven. Vibrio cholerae contains a tripartite ATP-independent periplasmic (TRAP) transporter, SiaPQM (VC1777-VC1779), encoded by genes within the Vibrio pathogenicity island-2 (VPI-2), which are adjacent to the SAC genes nanA, nanE and nanK. We demonstrate a correlation of the occurrence of VPI-2 and the ability of Vibrio to grow on the common sialic acid N-acetylneuraminic acid (Neu5Ac), and that a V. cholerae N16961 mutant defective in vc1777, encoding the large membrane protein component of the TRAP transporter, SiaM, is unable to grow on Neu5Ac as the sole carbon source. Using the genome context and known structures of the SiaP protein component of the TRAP transporter, we define a subfamily of Neu5Ac-specific TRAP transporters, of which the vc1777-vc1779 genes are the only representatives in V. cholerae. A recent report has suggested that an entirely different TRAP transporter (VC1927-VC1929) is the Neu5Ac transporter in V. cholerae. Bioinformatics and genomic analysis suggest strongly that this is a C(4)-dicarboxylate-specific TRAP transporter, and indeed disruption of vc1929 results in a defect in growth on C(4)-dicarboxylates but not Neu5Ac. Together these data demonstrate unequivocally that the siaPQM-encoded TRAP transporter within VPI-2 is the sole sialic acid transporter in V. cholerae.

IP3 receptor processing by the ERAD pathway

Inositol 1,4,5‐trisphosphate (IP3) receptors are large ER membrane proteins which form tetrameric channels that govern the release of Ca2+ stored within the ER lumen of vertebrate cells. They are named for their ability to bind to and be opened by the second messenger IP3, which is generated at the plasma membrane in response to cell surface receptor activation. Thus, IP3 receptors are pivotal in signaling pathways that couple extracellular hormones, neurotransmitters and growth factors to increases in cytoplasmic Ca2+ concentration and the regulation of Ca2+‐dependent events (e.g. secretion, fertilization, apoptosis and gene expression). Surprisingly, when IP3 receptors are activated they are rapidly destroyed via the ER‐associated degradation (ERAD) pathway, a ubiquitination‐and proteasome‐dependent mechanism that clears the ER of aberrant proteins. I will review recent studies aimed at identifying which ERAD pathway components mediate IP3 receptor ERAD, focusing on a novel complex composed of the ER membrane proteins erlin 1 and 2 which binds to IP3 receptors immediately after they are activated, and the E3 ligase RNF170, which participates in IP3 receptor ubiquitination.

Structural investigations of ClC‐ec1, a large integral membrane protein, using solution‐state NMR and nanodisc technology

CLC antiporters mediate Cl−/H+ exchange across cell membranes in organisms ranging from E. coli to humans via coupling of protein conformational changes to ion binding, unbinding and translocation. X‐ray crystallographic structures have provided essential molecular pictures, but details of conformational changes remain elusive. We are using solution state NMR to probe conformational change in ClC‐ec1, a CLC homolog of known structure. 13C labeling of lysine residues is achieved by post translational reductive methylation. 1H‐13C HSQC spectra reveal reversible, substrate‐dependent spectral changes that may reflect conformational changes. To address the concern that the detergent‐solubilized protein is not in a native environment, we are also using nanodiscs, which consist of two amphipathic helices wrapped around a bilayer patch of lipids surrounding the membrane‐embedded protein. The monomeric, 13C‐methylated mutant form of ClC‐ec1 was incorporated into discs and tested for homogeneity and monodispersity. The 1H‐13C HSQC spectra show substrate‐dependent spectral changes in this system, although further experiments will be needed to determine if these represent functionally‐relevant conformational changes. These studies demonstrate the potential for using solution‐state NMR and nanodisc technology to study ClC‐ec1 in a native lipid environment.Supported by: National Science Foundation

Self‐Organization of Transitional ER Sites

We are studying the biogenesis and dynamics of transitional ER (tER) sites using the budding yeast Pichia pastoris. Previously, we showed that P. pastoris tER sites are long‐lived structures that form de novo, fuse upon collision, and grow or shrink to attain a steady‐state size. This behavior can be explained by a self‐organization model. Specifically, we postulate that capture of new tER components is balanced by shrinkage driven by the budding of COPII coated transport vesicles. To test this model, we used a genetic screen to identify Sec16 as a key player in tER organization. Sec16 is a large peripheral ER membrane protein that interacts with multiple COPII components. Our results suggest that Sec16 acts as a negative regulator of ER export. According to this view, Sec16 functions primarily to control tER dynamics rather than to nucleate tER site formation. Sec16 defines a new level of regulation for the ER export system.

MmpL Genes Are Associated with Mycolic Acid Metabolism in Mycobacteria and Corynebacteria

SummaryMycolic acids are vital components of the cell wall of the tubercle bacillus Mycobacterium tuberculosis and are required for viability and virulence. While mycolic acid biosynthesis is studied extensively, components involved in mycolate transport remain unidentified. We investigated the role of large membrane proteins encoded by mmpL genes in mycolic acid transport in mycobacteria and the related corynebacteria. MmpL3 was found to be essential in mycobacteria and conditional depletion of MmpL3 in Mycobacterium smegmatis resulted in loss of cell wall mycolylation, and of the cell wall-associated glycolipid, trehalose dimycolate. In parallel, an accumulation of trehalose monomycolate (TMM) was observed, suggesting that mycolic acids were transported as TMM. In contrast to mycobacteria, we found redundancy in the role of two mmpL genes, in Corynebacterium glutamicum; a complete loss of trehalose-associated and cell wall bound corynomycolates was observed in an NCgl0228-NCgl2769 double mutant, but not in individual single mutants. Our studies highlight the role of mmpL genes in mycolic acid metabolism and identify potential new targets for anti-TB drug development.

The role of the second and third extracellular loops of the adenosine A1 receptor in activation and allosteric modulation

The adenosine A1 receptor is a member of the large membrane protein family that signals through G proteins, the G protein-coupled receptors (GPCRs). GPCRs consist of seven transmembrane domains connected by three intracellular and three extracellular loops. Their N-terminus is extracellular, the C-terminal tail is in the cytoplasm. The transmembrane domains in receptor subfamilies that bind the same endogenous ligand, such as dopamine or adenosine, tend to be highly similar. In contrast, the loop regions can vary greatly, both in sequence and in length, and the role these loops have in the activation mechanism of the receptors remains unclear. Here, we investigated the activating role of the second and third extracellular loop of the human adenosine A1 receptor. By means of an (Ala)3 mutagenic scan in which consecutive sets of three amino acids were mutated into alanine residues in EL2 and a classical alanine scan in EL3, we revealed a strong regulatory role for the second extracellular loop (EL2) of the human adenosine A1 receptor. Besides many residues in the second and the third extracellular loops important for adenosine A1 receptor activation, we also identified two residues in EL2, a tryptophan and a glutamate, that affect the influence of the allosteric modulator PD81,723. These results, combined with a comparison of the different receptor loop regions, provide insight in the activation mechanism of this typical class A GPCR and further emphasize the unique pharmacological profile the loops can provide to individual receptors, even within subfamilies of GPCRs.

Time-resolved protein nanocrystallography using an X-ray free-electron laser

We demonstrate the use of an X-ray free electron laser synchronized with an optical pump laser to obtain X-ray diffraction snapshots from the photoactivated states of large membrane protein complexes in the form of nanocrystals flowing in a liquid jet. Light-induced changes of Photosystem I-Ferredoxin co-crystals were observed at time delays of 5 to 10 µs after excitation. The result correlates with the microsecond kinetics of electron transfer from Photosystem I to ferredoxin. The undocking process that follows the electron transfer leads to large rearrangements in the crystals that will terminally lead to the disintegration of the crystals. We describe the experimental setup and obtain the first time-resolved femtosecond serial X-ray crystallography results from an irreversible photo-chemical reaction at the Linac Coherent Light Source. This technique opens the door to time-resolved structural studies of reaction dynamics in biological systems.

Cell‐free synthesis of membrane subunits of ATP synthase in phospholipid bicelles: NMR shows subunit a fold similar to the protein in the cell membrane

NMR structure determination of large membrane proteins is hampered by broad spectral lines, overlap, and ambiguity of signal assignment. Chemical shift and NOE assignment can be facilitated by amino acid selective isotope labeling in cell-free protein synthesis system. However, many biological detergents are incompatible with the cell-free synthesis, and membrane proteins often have to be synthesized in an insoluble form. We report cell-free synthesis of subunits a and c of the proton channel of Escherichia coli ATP synthase in a soluble form in a mixture of phosphatidylcholine derivatives. In comparison, subunit a was purified from the cell-free system and from the bacterial cell membranes. NMR spectra of both preparations were similar, indicating that our procedure for cell-free synthesis produces protein structurally similar to that prepared from the cell membranes.

The Membrane Proteins SiaQ and SiaM Form an Essential Stoichiometric Complex in the Sialic Acid Tripartite ATP-independent Periplasmic (TRAP) Transporter SiaPQM (VC1777–1779) from Vibrio cholerae

Tripartite ATP-independent periplasmic (TRAP) transporters are widespread in bacteria but poorly characterized. They contain three subunits, a small membrane protein, a large membrane protein, and a substrate-binding protein (SBP). Although the function of the SBP is well established, the membrane components have only been studied in detail for the sialic acid TRAP transporter SiaPQM from Haemophilus influenzae, where the membrane proteins are genetically fused. Herein, we report the first in vitro characterization of a truly tripartite TRAP transporter, the SiaPQM system (VC1777-1779) from the human pathogen Vibrio cholerae. The active reconstituted transporter catalyzes unidirectional Na(+)-dependent sialic acid uptake having similar biochemical features to the orthologous system in H. influenzae. However, using this tripartite transporter, we demonstrate the tight association of the small, SiaQ, and large, SiaM, membrane proteins that form a 1:1 complex. Using reconstituted proteoliposomes containing particular combinations of the three subunits, we demonstrate biochemically that all three subunits are likely to be essential to form a functional TRAP transporter.