Functional response of the small multidrug resistance protein EmrE to mutations in transmembrane helix 2.

Escherichia coli EmrE is a small multidrug resistance protein encompassing four transmembrane (TM) sequences that oligomerizes to confer resistance to antimicrobials. Here we examined the effects on in vivo protein accumulation and ethidium resistance activity of single residue substitutions at conserved and variable positions in EmrE transmembrane segment 2 (TM2). We found that activity was reduced when conserved residues localized to one TM2 surface were replaced. Our findings suggest that conserved TM2 positions tolerate greater residue diversity than conserved sites in other EmrE TM sequences, potentially reflecting a source of substrate polyspecificity.

Congenital heart block maternal sera autoantibodies target an extracellular epitope on the α1G T-type calcium channel in human fetal hearts.

BACKGROUND: Congenital heart block (CHB) is a transplacentally acquired autoimmune disease associated with anti-Ro/SSA and anti-La/SSB maternal autoantibodies and is characterized primarily by atrioventricular (AV) block of the fetal heart. This study aims to investigate whether the T-type calcium channel subunit α1G may be a fetal target of maternal sera autoantibodies in CHB. METHODOLOGY/PRINCIPAL FINDINGS: We demonstrate differential mRNA expression of the T-type calcium channel CACNA1G (α1G gene) in the AV junction of human fetal hearts compared to the apex (18-22.6 weeks gestation). Using human fetal hearts (20-22 wks gestation), our immunoprecipitation (IP), Western blot analysis and immunofluorescence (IF) staining results, taken together, demonstrate accessibility of the α1G epitope on the surfaces of cardiomyocytes as well as reactivity of maternal serum from CHB affected pregnancies to the α1G protein. By ELISA we demonstrated maternal sera reactivity to α1G was significantly higher in CHB maternal sera compared to controls, and reactivity was epitope mapped to a peptide designated as p305 (corresponding to aa305-319 of the extracellular loop linking transmembrane segments S5-S6 in α1G repeat I). Maternal sera from CHB affected pregnancies also reacted more weakly to the homologous region (7/15 amino acids conserved) of the α1H channel. Electrophysiology experiments with single-cell patch-clamp also demonstrated effects of CHB maternal sera on T-type current in mouse sinoatrial node (SAN) cells. CONCLUSIONS/SIGNIFICANCE: Taken together, these results indicate that CHB maternal sera antibodies readily target an extracellular epitope of α1G T-type calcium channels in human fetal cardiomyocytes. CHB maternal sera also show reactivity for α1H suggesting that autoantibodies can target multiple fetal targets.

Acrylamide concentration determines the direction and magnitude of helical membrane protein gel shifts.

SDS/PAGE is universally used in biochemistry, cell biology, and immunology to resolve minute protein amounts readily from tissue and cell extracts. Although molecular weights of water-soluble proteins are reliably determined from their SDS/PAGE mobility, most helical membrane proteins, which comprise 20-30% of the human genome and the majority of drug targets, migrate to positions that have for decades been unpredictably slower or faster than their actual formula weight, often confounding their identification. Using de novo designed transmembrane-mimetic polypeptides that match the composition of helical membrane-spanning sequences, we quantitate anomalous SDS/PAGE fractionation of helical membrane proteins by comparing the relative mobilities of these polypeptides with typical water-soluble reference proteins on Laemmli gels. We find that both the net charge and effective molecular size of the migrating particles of transmembrane-mimetic species exceed those of the corresponding reference proteins and that gel acrylamide concentration dictates the impact of these two factors on the direction and magnitude of anomalous migration. Algorithms we derived from these data compensate for this differential effect of acrylamide concentration on the SDS/PAGE mobility of a variety of natural membrane proteins. Our results provide a unique means to predict anomalous migration of membrane proteins, thereby facilitating straightforward determination of their molecular weights via SDS/PAGE.

Inside-out signaling promotes dynamic changes in the carcinoembryonic antigen-related cellular adhesion molecule 1 (CEACAM1) oligomeric state to control its cell adhesion properties.

Cell-cell contacts are fundamental to multicellular organisms and are subject to exquisite levels of control. The carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) can engage in both cis-homophilic (parallel) oligomerization and trans-homophilic (anti-parallel) binding. In this study, we establish that the CEACAM1 transmembrane domain has a propensity to form cis-dimers via the transmembrane-embedded (432)GXXXG(436) motif and that this basal state is overcome when activated calmodulin binds to the CEACAM1 cytoplasmic domain. Although mutation of the (432)GXXXG(436) motif reduced CEACAM1 oligomerization, it did not affect surface localization of the receptor or influence CEACAM1-dependent cellular invasion by the pathogenic Neisseria. The mutation did, however, have a striking effect on CEACAM1-dependent cellular aggregation, increasing both the kinetics of cell-cell association and the size of cellular aggregates formed. CEACAM1 association with tyrosine kinase c-Src and tyrosine phosphatases SHP-1 and SHP-2 was not affected by the (432)GXXXG(436) mutation, consistent with their association with the monomeric form of wild type CEACAM1. Collectively, our results establish that a dynamic oligomer-to-monomer shift in surface-expressed CEACAM1 facilitates trans-homophilic binding and downstream effector signaling.

Design of transmembrane peptides: coping with sticky situations.

Membrane proteins have central roles in cellular processes ranging from nutrient uptake to cell-cell communication, and are key drug targets. However, research on α-helical integral membrane proteins is in its relative infancy vs. water-soluble proteins, largely because of their water insolubility when extracted from their native membrane environment. Peptides with sequences that correspond to the membrane-spanning segments of α-helical integral membrane proteins, termed transmembrane (TM) peptides, provide valuable tools for the characterization of these molecules. Here we describe in detail protocols for the design of TM peptides from the sequences of natural α-helical integral membrane proteins and outline strategies for their synthesis and for improving their solubility properties.

Correction factors for membrane protein molecular weight readouts on sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Membrane proteins are known to migrate anomalously on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) to relative molecular mass (M(r)) values larger or smaller than formula molecular weight. We constructed a database from literature M(r) values reported for 168 nonredundant helical membrane proteins with structures determined to high resolution and found that more than three-quarters of them exhibit this behavior on gels calibrated with commercial standards. Further analysis of the database indicated that the direction of anomalous migration is not a consequence of membrane protein net charge or hydrophobicity. Plots of observed versus formula M(r) values showed that membrane proteins migrating slower than expected read out at 1.13×M(r), whereas those that migrate faster than expected read out at 0.82×M(r) (R(2)~0.98, P<0.0001). These robust trends imply that division of the M(r) readouts of slower or faster migrating analytes by 1.13 or 0.82, respectively, should enhance SDS-PAGE accuracy. Applying this correction procedure to SDS-PAGE readouts of four fast-migrating helical transmembrane (TM) proteins significantly reduced M(r) errors from approximately 20% to 8% (P<0.0001). Our results suggest that hydrophobic standards for SDS-PAGE would significantly improve the performance of the technique applied to membrane proteins.

Sequence hydropathy dominates membrane protein response to detergent solubilization.

The ability to predict from amino acid sequence how membrane protein structures will respond to detergent solubilization would significantly facilitate experimental characterization of these molecules. Here we have investigated and compared the response to solubilization by the "mild" n-dodecyl-ß-D-maltoside (DDM) and "harsh" sodium dodecyl sulfate (SDS) of wild-type and point mutant "hairpin" (helix-loop-helix) membrane proteins derived from the third and fourth TM segments of the human cystic fibrosis transmembrane conductance regulator (CFTR) and the intervening extracellular loop. Circular dichroism spectroscopy, size-exclusion chromatography, and pyrene fluorescence spectroscopy were used to evaluate the secondary structures, hairpin-detergent complex excluded volumes, and hairpin compactness of the detergent-solubilized sequences. Sequence hydrophobicity is found to be the dominant factor dictating membrane protein response to detergent solubilization by DDM and SDS, with hairpin secondary structure exquisitely sensitive to mutation when DDM is used for solubilization. DDM and SDS differ principally in their ability to promote approach of TM segment ends, although hairpin compactness remains sensitive to point mutations. Our overall findings suggest that protein-protein and protein-detergent interactions are determined concomitantly, with the net hydropathy of residues exposed to detergent dominating the observed properties of the solubilized protein.

Protein structure in membrane domains.

Of great interest to the academic and pharmaceutical research communities, helical transmembrane proteins are characterized by their ability to dissolve and fold in lipid bilayers--properties conferred by polypeptide spans termed transmembrane domains (TMDs). The apolar nature of TMDs necessitates the use of membrane-mimetic solvents for many structure and folding studies. This review examines the relationship between TMD structure and solvent environment, focusing on principles elucidated largely in membrane-mimetic environments with single-TMD protein and peptide models. Following a brief description of TMD sequence and conformational characteristics gleaned from the structural database, we present an overview of the conceptual models used to study folding in vitro. The impact of sequence and solvent context on the incorporation of TMDs into membranes, and its role in measurements of TMD self-assembly strengths, is then described. We conclude with a discussion of the nonspecific effects of membrane components on TMD stability.

Novel hydrophobic standards for membrane protein molecular weight determinations via sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) is a universally employed technique that separates proteins on the basis of molecular weight (MW). However, membrane proteins are known to size anomalously on SDS-PAGE calibrated with conventional standards, an issue that complicates interpretation of protein identity, purity, degradation, and/or stoichiometry. Here we describe the preparation of novel polyleucine hydrophobic standards for SDS-PAGE that reduce the average deviation of the apparent MW from the formula MW of natural membrane proteins to 7% versus 20% with commercially available standards. Our results suggest that gel calibration with hydrophobic standards may facilitate the interpretation of membrane protein SDS-PAGE experiments.

Structural, functional, and bioinformatic studies demonstrate the crucial role of an extended peptide binding site for the SH3 domain of yeast Abp1p.

SH3 domains, which are among the most frequently occurring protein interaction modules in nature, bind to peptide targets ranging in length from 7 to more than 25 residues. Although the bulk of studies on the peptide binding properties of SH3 domains have focused on interactions with relatively short peptides (less than 10 residues), a number of domains have been recently shown to require much longer sequences for optimal binding affinity. To gain greater insight into the binding mechanism and biological importance of interactions between an SH3 domain and extended peptide sequences, we have investigated interactions of the yeast Abp1p SH3 domain (AbpSH3) with several physiologically relevant 17-residue target peptide sequences. To obtain a molecular model for AbpSH3 interactions, we solved the structure of the AbpSH3 bound to a target peptide from the yeast actin patch kinase, Ark1p. Peptide target complexes from binding partners Scp1p and Sjl2p were also characterized, revealing that the AbpSH3 uses a common extended interface for interaction with these peptides, despite K(d) values for these peptides ranging from 0.3 to 6 mum. Mutagenesis studies demonstrated that residues across the whole 17-residue binding site are important both for maximal in vitro binding affinity and for in vivo function. Sequence conservation analysis revealed that both the AbpSH3 and its extended target sequences are highly conserved across diverse fungal species as well as higher eukaryotes. Our data imply that the AbpSH3 must bind extended target sites to function efficiently inside the cell.

Peptide models of membrane protein folding.

Given the central roles of membrane proteins in cellular processes ranging from nutrient uptake to cell-cell communication, as well as the importance of these proteins as drug targets, efforts to understand and control their structures are vital in human health and disease. The rational design of membrane proteins with modified properties is thus a highly desirable goal in molecular medicine and biotechnology. However, experimental data showing how individual transmembrane (TM) residues and/or segments direct the packing and folding of membrane proteins into biologically functional entities remain sparse. To address these questions in a systematic manner, helix-helix interactions between two (or more) TM segments must be identified and analyzed. Here we present an overview of the utilization of peptides as models of the TM segments of alpha-helical membrane proteins in uncovering the amino acid sequence motifs and interactions that build these molecules. TM peptide design and production strategies are discussed, and specific examples of the application of TM peptides to the study of membrane proteins are presented. We demonstrate that TM peptides can be routinely produced in sufficient quantities for biophysical analysis, are amenable to a variety of experimental techniques, and can effectively replicate the native helix-helix contacts and key aspects of the natural biological structures of membrane proteins.

The assembly motif of a bacterial small multidrug resistance protein.

Multidrug transporters such as the small multidrug resistance (SMR) family of bacterial integral membrane proteins are capable of conferring clinically significant resistance to a variety of common therapeutics. As antiporter proteins of approximately 100 amino acids, SMRs must self-assemble into homo-oligomeric structures for efflux of drug molecules. Oligomerization centered at transmembrane helix four (TM4) has been implicated in SMR assembly, but the full complement of residues required to mediate its self-interaction remains to be characterized. Here, we use Hsmr, the 110-residue SMR family member of the archaebacterium Halobacterium salinarum, to determine the TM4 residue motif required to mediate drug resistance and SMR self-association. Twelve single point mutants that scan the central portion of the TM4 helix (residues 85-104) were constructed and were tested for their ability to confer resistance to the cytotoxic compound ethidium bromide. Six residues were found to be individually essential for drug resistance activity (Gly(90), Leu(91), Leu(93), Ile(94), Gly(97), and Val(98)), defining a minimum activity motif of (90)GLXLIXXGV(98) within TM4. When the propensity of these mutants to dimerize on SDS-PAGE was examined, replacements of all but Ile resulted in approximately 2-fold reduction of dimerization versus the wild-type antiporter. Our work defines a minimum activity motif of (90)GLXLIXXGV(98) within TM4 and suggests that this sequence mediates TM4-based SMR dimerization along a single helix surface, stabilized by a small residue heptad repeat sequence. These TM4-TM4 interactions likely constitute the highest affinity locus for disruption of SMR function by directly targeting its self-assembly mechanism.

Detergent binding explains anomalous SDS-PAGE migration of membrane proteins.

Migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) that does not correlate with formula molecular weights, termed "gel shifting," appears to be common for membrane proteins but has yet to be conclusively explained. In the present work, we investigate the anomalous gel mobility of helical membrane proteins using a library of wild-type and mutant helix-loop-helix ("hairpin") sequences derived from transmembrane segments 3 and 4 of the human cystic fibrosis transmembrane conductance regulator (CFTR), including disease-phenotypic residue substitutions. We find that these hairpins migrate at rates of -10% to +30% vs. their actual formula weights on SDS-PAGE and load detergent at ratios ranging from 3.4-10 g SDS/g protein. We additionally demonstrate that mutant gel shifts strongly correlate with changes in hairpin SDS loading capacity (R(2) = 0.8), and with hairpin helicity (R(2) = 0.9), indicating that gel shift behavior originates in altered detergent binding. In some cases, this differential solvation by SDS may result from replacing protein-detergent contacts with protein-protein contacts, implying that detergent binding and folding are intimately linked. The CF-phenotypic V232D mutant included in our library may thus disrupt CFTR function via altered protein-lipid interactions. The observed interdependence between hairpin migration, SDS aggregation number, and conformation additionally suggests that detergent binding may provide a rapid and economical screen for identifying membrane proteins with robust tertiary and/or quaternary structures.

Distinctions between hydrophobic helices in globular proteins and transmembrane segments as factors in protein sorting.

Transmembrane (TM) segments in proteins can be distinguished in amino acid sequences as continuous stretches of hydrophobic residues. However, examination of a data base of helical water-soluble (globular) proteins revealed that nearly one-third contained helices of sufficient length to span a bilayer (> or =19 residues) that had mean hydrophobicity > or =actual TM segments. We now report that synthetic peptides corresponding to these globular protein sequences, which we termed "delta-helices," behave like native TM sequences and readily insert into membrane mimetic environments in helical conformations. As well, certain delta-helix sequences can integrate into the membrane bilayer when placed into a membrane-targeted chimeric protein. We establish that delta-helices can be distinguished computationally from bona fide TM segments by the decreased frequency of occurrence of Ile/Val residues and by their relatively decreased solvent accessibilities (versus other globular helices) within tertiary structure. The further observations that (i) delta-helices generally contain three or more charged residues and (ii) delta-helices display relatively even distribution of these charged residues along their lengths, rather than concentration near their N and C termini as observed for TM segments, may constitute key recognition factors in diverting delta-helices from the membrane in vivo. Although a discrete biological role for delta-helices remains to be pinpointed, our overall results suggest that such segments may be required for globular protein folding and identify additional factors that may be important in the correct selection of TM segments by the cellular machinery.

Recognition of non-canonical peptides by the yeast Fus1p SH3 domain: elucidation of a common mechanism for diverse SH3 domain specificities.

The yeast Fus1p SH3 domain binds to peptides containing the consensus motif, R(S/T)(S/T)SL, which is a sharp contrast to most SH3 domains, which bind to PXXP-containing peptides. Here, we have demonstrated that this domain binds to R(S/T)(S/T)SL-containing peptides derived from two putative in vivo binding partners from yeast proteins, Bnr1p and Ste5p, with K(d) values in the low micromolar range. The R(S/T)(S/T)SL consensus motif is necessary, but not sufficient for binding to the Fus1p SH3 domain, as residues lying N-terminal to the consensus motif also play a critical role in the binding reaction. Through mutagenesis studies and comparisons to other SH3 domains, we have discovered that the Fus1p SH3 domain utilizes a portion of the same binding surface as typical SH3 domains. However, the PXXP-binding surface, which plays the predominant role in binding for most SH3 domains, is debilitated in the WT domain by the substitution of unusual residues at three key conserved positions. By replacing these residues, we created a version of the Fus1p SH3 domain that binds to a PXXP-containing peptide with extremely high affinity (K(d)= 40 nM). Based on our data and analysis, we have clearly delineated two distinct surfaces comprising the typical SH3-domain-binding interface and show that one of these surfaces is the primary mediator of almost every "non-canonical" SH3-domain-mediated interaction described in the literature. Within this framework, dramatic alterations in SH3 domain specificity can be simply explained as a modulation of the binding strengths of these two surfaces.

Defining the defect in F508 del CFTR: a soluble problem?

Previously reported crystal structures of CFTR F508 del-NBD1 were determined in the presence of solubilizing mutations. In this issue of Chemistry & Biology, Pissarra et al. (2008) show that partial rescue of the trafficking and gating defects of full-length CFTR occurs in vivo upon recapitulation of the solubilizing F494N/Q637R or F428S/F494N/Q637R substitutions in cis with F508 del.

Surface recognition elements of membrane protein oligomerization.

Although certain membrane proteins are functional as monomeric polypeptides, others must assemble into oligomers to carry out their biological roles. High-resolution membrane protein structures provide a valuable resource for examining the sequence features that facilitate-or preclude-assembly of membrane protein monomers into multimeric structures. Here we have utilized a data set of 28 high-resolution alpha-helical membrane protein structures comprising 32 nonredundant polypeptides to address this issue. The lipid-exposed surfaces of membrane proteins that have reached their fully assembled and functional biological units have been compared with those of the individual subunits that build quaternary structures. Though the overall amino acid composition of each set of surfaces is similar, a key distinction-the distribution of small-xxx-small motifs-delineates subunits from membrane proteins that have reached a functioning oligomeric state. Quaternary structure formation may therefore be dictated by small-xxx-small motifs that are not satisfied by intrachain contacts.

Role of the extracellular loop in the folding of a CFTR transmembrane helical hairpin.

The folding of membrane-spanning domains into their native functional forms depends on interactions between transmembrane (TM) helices joined by covalent loops. However, the importance of these covalent linker regions in mediating the strength of helix-helix associations has not been systematically addressed. Here we examine the potential structural impact of cystic fibrosis-phenotypic mutations in the extracellular loop 2 (ECL2) on interactions between the TM3 and TM4 helices of the cystic fibrosis transmembrane conductance regulator (CFTR) in constructs containing CFTR residues 194-241. When the effects of replacements in ECL2 (including the CF-phenotypic mutants E217G and Q220R) were evaluated in a library of wild-type and mutant TM3-ECL2-TM4 hairpin constructs, we found that SDS-PAGE gel migration rates differed over a range of nearly 40% +/- the wild-type position and that decreased migration rates correlate with increasing hairpin alpha-helical content as measured by circular dichroism spectra in sodium dodecyl sulfate micelles. The decreased mobility of TM3/4 constructs by introduction of non-native residues is interpreted in terms of an elongation or "opening" of the helical hairpin and concomitant destabilization of membrane-based helix-helix interactions. Our results support a role for short loop regions in dictating the stability of membrane protein folds and highlight the interplay between membrane-embedded helix-helix interactions and loop conformation in influencing the structure of membrane proteins.

The biologically relevant targets and binding affinity requirements for the function of the yeast actin-binding protein 1 Src-homology 3 domain vary with genetic context.

Many protein-protein interaction domains bind to multiple targets. However, little is known about how the interactions of a single domain with many proteins are controlled and modulated under varying cellular conditions. In this study, we investigated the in vivo effects of Abp1p SH3 domain mutants that incrementally reduce target-binding affinity in four different yeast mutant backgrounds in which Abp1p activity is essential for growth. Although the severity of the phenotypic defects observed generally increased as binding affinity was reduced, some genetic backgrounds (prk1 Delta and sla1 Delta) tolerated large affinity reductions while others (sac6 Delta and sla2 Delta) were much more sensitive to these reductions. To elucidate the mechanisms behind these observations, we determined that Ark1p is the most important Abp1p SH3 domain interactor in prk1 Delta cells, but that interactions with multiple targets, including Ark1p and Scp1p, are required in the sac6 Delta background. We establish that the Abp1p SH3 domain makes different, functionally important interactions under different genetic conditions, and these changes in function are reflected by changes in the binding affinity requirement of the domain. These data provide the first evidence of biological relevance for any Abp1p SH3 domain-mediated interaction. We also find that considerable reductions in binding affinity are tolerated by the cell with little effect on growth rate, even when the actin cytoskeletal morphology is significantly perturbed.