Catalytic activity of an isolated domain of Na,K-ATPase expressed in Escherichia coli.

Fusion proteins of glutathione-S-transferase and fragments from the large cytoplasmic domain of the sheep Na,K-ATPase alpha1-subunit were expressed in Escherichia coli. The Na,K-ATPase sequences begin at Ala345 and terminate at either Arg600 (DP600f), Thr610 (DP610f), Gly731 (DP731f), or Glu779 (DP779f). After affinity purification on glutathione-Sepharose, the fusion proteins were labeled with [alpha-32P]-2-N3-ATP, and incorporation of the radiolabel into the fusion proteins was measured by scintillation counting after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Kd values of 220-290 microM for 2-N3-ATP binding to the fusion proteins were obtained from the photolabeling experiments. Approximately 1 mol of 2-N3-ATP was calculated to be incorporated per mole of fusion protein after correction for photochemical incorporation efficiency. Labeling of all of the fusion proteins by 25 microM 2-N3-ATP was reduced in the presence of MgATP, Na2ATP, MgCl2, 2',3'-O-(2,4, 6-trinitrophenyl)-ATP, and p-nitrophenylphosphate, and Ki values of 2-11 mM for Na2ATP, 0.2-5 mM for MgCl2, 0.1-5 mM for MgATP, and 20-300 microM for p-nitrophenylphosphate were calculated for these ligands. All of the fusion proteins catalyze the hydrolysis of p-nitrophenylphosphate. The reaction requires MgCl2 and is inhibited by inorganic phosphate, which is similar to the hydrolysis of p-nitrophenylphosphate by native Na,K-ATPase. Based on these observations, it appears that the soluble fragments from the large cytoplasmic domain of Na,K-ATPase expressed in bacterial cells are folded in an E2-like conformation and are likely to retain much of the native structure.     

Role of the transmembrane domain of FXYD7 in structural and functional interactions with Na,K-ATPase

Members of the FXYD family are tissue-specific regulators of the Na,K-ATPase. Here, we have investigated the contribution of amino acids in the transmembrane (TM) domain of FXYD7 to the interaction with Na,K-ATPase. Twenty amino acids of the TM domain were replaced individually by tryptophan, and combined mutations and alanine insertion mutants were constructed. Wild type and mutant FXYD7 were expressed in Xenopus oocytes with Na,K-ATPase. Mutational effects on the stable association with Na,K-ATPase and on the functional regulation of Na,K-ATPase were determined by co-immunoprecipitation and two-electrode voltage clamp techniques, respectively. Most residues important for the structural and functional interaction of FXYD7 are clustered in a face of the TM helix containing the two conserved glycine residues, but others are scattered over two-thirds of the FXYD TM helix. Ile-35, Ile-43, and Ile-44 are only involved in the stable association with Na,K-ATPase. Glu-26, Met-30, and Ile-44 are important for the functional effect and/or the efficient association of FXYD7 with Na,K-ATPase, consistent with the prediction that these amino acids contact TM domain 9 of the alpha subunit (Li, C., Grosdidier, A., Crambert, G., Horisberger, J.-D., Michielin, O., and Geering, K. (2004) J. Biol. Chem. 279, 38895-38902). Several amino acids that are not implicated in the efficient association of FXYD7 with the Na,K-ATPase are specifically involved in the functional effect of FXYD7. Leu-32 and Phe-37 influence the apparent affinity for external K+, whereas Val-28 and Ile-42 are implicated in the apparent affinity for both external K+ and external Na+. These amino acids act in a synergistic way. These results highlight the important structural and functional role of the TM domain of FXYD7 and delineate the determinants that mediate the complex interactions of FXYD7 with Na,K-ATPase.     

Effect of N-terminal solubility enhancing fusion proteins on yield of purified target protein

We have studied the effect of solubilising N-terminal fusion proteins on the yield of target protein after removal of the fusion partner and subsequent purification using immobilised metal ion affinity chromatography. We compared the yield of 45 human proteins produced from four different expression vectors: three having an N-terminal solubilising fusion protein (the GB1-domain, thioredoxin, or glutathione S-transferase) followed by a protease cleavage site and a His tag, and one vector having only an N-terminal His tag. We have previously observed a positive effect on solubility for proteins produced as fusion proteins compared to proteins produced with only a His tag in Escherichia coli. We find this effect to be less pronounced when we compare the yields of purified target protein after removal of the solubilising fusion although large target-dependent variations are seen. On average, the GB1+His fusion gives significantly higher final yields of protein than the thioredoxin+His fusion or the His tag, whereas GST+His gives lower yields. We also note a strong correlation between solubility and target protein size, and a correlation between solubility and the presence of peptide fragments that are predicted to be natively disordered.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

A transmembrane segment determines the steady-state localization of an ion-transporting adenosine triphosphatase

The H,K-adenosine triphosphatase (ATPase) of gastric parietal cells is targeted to a regulated membrane compartment that fuses with the apical plasma membrane in response to secretagogue stimulation. Previous work has demonstrated that the alpha subunit of the H, K-ATPase encodes localization information responsible for this pump's apical distribution, whereas the beta subunit carries the signal responsible for the cessation of acid secretion through the retrieval of the pump from the surface to the regulated intracellular compartment. By analyzing the sorting behaviors of a number of chimeric pumps composed of complementary portions of the H, K-ATPase alpha subunit and the highly homologous Na,K-ATPase alpha subunit, we have identified a portion of the gastric H,K-ATPase, which is sufficient to redirect the normally basolateral Na,K-ATPase to the apical surface in transfected epithelial cells. This motif resides within the fourth of the H,K-ATPase alpha subunit's ten predicted transmembrane domains. Although interactions with glycosphingolipid-rich membrane domains have been proposed to play an important role in the targeting of several apical membrane proteins, the apically located chimeras are not found in detergent-insoluble complexes, which are typically enriched in glycosphingolipids. Furthermore, a chimera incorporating the Na, K-ATPase alpha subunit fourth transmembrane domain is apically targeted when both of its flanking sequences derive from H,K-ATPase sequence. These results provide the identification of a defined apical localization signal in a polytopic membrane transport protein, and suggest that this signal functions through conformational interactions between the fourth transmembrane spanning segment and its surrounding sequence domains.     

PDZ domains facilitate binding of high temperature requirement protease A (HtrA) and tail-specific protease (Tsp) to heterologous substrates through recognition of the small stable RNA A (ssrA)-encoded peptide

The Escherichia coli protease HtrA has two PDZ domains, and sequence alignments predict that the E. coli protease Tsp has a single PDZ domain. PDZ domains are composed of short sequences (80-100 amino acids) that have been implicated in a range of protein:protein interactions. The PDZ-like domain of Tsp may be involved in binding to the extreme COOH-terminal sequence of its substrate, whereas the HtrA PDZ domains are involved in subunit assembly and are predicted to be responsible for substrate binding and subsequent translocation into the active site. E. coli has a system of protein quality control surveillance mediated by the ssrA-encoded peptide tagging system. This system tags misfolded proteins or protein fragments with an 11-amino acid peptide that is recognized by a battery of cytoplasmic and periplasmic proteases as a degradation signal. Here we show that both HtrA and Tsp are able to recognize the ssrA-encoded peptide tag with apparent K(D) values of approximately 5 and 390 nm, respectively, and that their PDZ-like domains mediate this recognition. Fusion of the ssrA-encoded peptide tag to the COOH terminus of a heterologous protein (glutathione S-transferase) renders it sensitive to digestion by Tsp but not HtrA. These observations support the prediction that the HtrA PDZ domains facilitate substrate binding and the differential proteolytic responses of HtrA and Tsp to SsrA-tagged glutathione S-transferase are interpreted in terms of the structure of HtrA.     

Fcγ1 fragment of IgG1 as a powerful affinity tag in recombinant Fc-fusion proteins: immunological,biochemical and therapeutic properties

Affinity tags are vital tools for the production of high-throughput recombinant proteins. Several affinity tags, such as the hexahistidine tag, maltose-binding protein, streptavidin-binding peptide tag, calmodulin-binding peptide, c-Myc tag, glutathione S-transferase and FLAG tag, have been introduced for recombinant protein production. The fragment crystallizable (Fc) domain of the IgG1 antibody is one of the useful affinity tags that can facilitate detection, purification and localization of proteins and can improve the immunogenicity, modulatory effects, physicochemical and pharmaceutical properties of proteins. Fcγ recombinant forms a group of recombinant proteins called Fc-fusion proteins (FFPs). FFPs are widely used in drug discovery, drug delivery, vaccine design and experimental research on receptor–ligand interactions. These fusion proteins have become successful alternatives to monoclonal antibodies for drug developments. In this review, the physicochemical, biochemical, immunological, pharmaceutical and therapeutic properties of recombinant FFPs were discussed as a new generation of bioengineering strategies.     

Residues within transmembrane domains 4 and 6 of the Na,K-ATPase alpha subunit are important for Na+ selectivity

The Na,K- and H,K-ATPases are plasma membrane enzymes responsible for the active exchange of extracellular K(+) for cytoplasmic Na(+) or H(+), respectively. At present, the structural determinants for the specific function of these ATPases remain poorly understood. To investigate the cation selectivity of these ATPases, we constructed a series of Na,K-ATPase mutants in which residues in the membrane spanning segments of the alpha subunit were changed to the corresponding residues common to gastric H,K-ATPases. Thus, mutants were created with substitutions in transmembrane domains TM1, TM4, TM5, TM6, TM7, and TM8 independently or together (designated TMAll). The function of each mutant was assessed after coexpression with the beta subunit in Sf-9 cells using baculoviruses. The enzymatic properties of TM1, TM7, and TM8 mutants were similar to the wild-type Na,K-ATPase, and while TM5 showed modest changes in apparent affinity for Na(+), TM4, TM6, and TMAll displayed an abnormal activity. This resulted in a Na(+)-independent hydrolysis of ATP, a 2-fold higher K(0.5) for Na(+) activation, and the ability to function at low pH. These results suggest a loss of discrimination for Na(+) over H(+) for the enzymes. In addition, TM4, TM6, and TMAll mutants exhibited a 1.5-fold lower affinity for K(+) and a 4-5-fold decreased sensitivity to vanadate. Altogether, these results provide evidence that residues in transmembrane domains 4 and 6 of the alpha subunit of the Na,K-ATPase play an important role in determining the specific cation selectivity of the enzyme and also its E1/E2 conformational equilibrium.     

Overview of tag protein fusions: from molecular and biochemical fundamentals to commercial systems

In response to the rapidly growing field of proteomics, the use of recombinant proteins has increased greatly in recent years. Recombinant hybrids containing a polypeptide fusion partner, termed affinity tag, to facilitate the purification of the target polypeptides are widely used. Many different proteins, domains, or peptides can be fused with the target protein. The advantages of using fusion proteins to facilitate purification and detection of recombinant proteins are well-recognized. Nevertheless, it is difficult to choose the right purification system for a specific protein of interest. This review gives an overview of the most frequently used and interesting systems: Arg-tag, calmodulin-binding peptide, cellulose-binding domain, DsbA, c-myc-tag, glutathione S-transferase, FLAG-tag, HAT-tag, His-tag, maltose-binding protein, NusA, S-tag, SBP-tag, Strep-tag, and thioredoxin.     

ATP-induced conformational changes of the nucleotide-binding domain of Na,K-ATPase

The Na,K-ATPase hydrolyzes ATP to drive the coupled extrusion and uptake of Na+ and K+ ions across the plasma membrane. Here, we report two high-resolution NMR structures of the 213-residue nucleotide-binding domain of rat alpha1 Na,K-ATPase, determined in the absence and the presence of ATP. The nucleotide binds in the anti conformation and shows a relative paucity of interactions with the protein, reflecting the low-affinity ATP-binding state. Binding of ATP induces substantial conformational changes in the binding pocket and in residues located in the hinge region connecting the N- and P-domains. Structural comparison with the Ca-ATPase stabilized by the inhibitor thapsigargin, E2(TG), and the model of the H-ATPase in the E1 form suggests that the observed changes may trigger the series of events necessary for the release of the K+ ions and/or disengagement of the A-domain, leading to the eventual transfer of the gamma-phosphate group to the invariant Asp369.     

Caveolin-Na/K-ATPase interactions: Role of transmembrane topology in non-genomic steroid signal transduction

Progesterone and its polar metabolite(s) trigger the meiotic divisions in the amphibian oocyte through a non-genomic signaling system at the plasma membrane. Published site-directed mutagenesis studies of ouabain binding and progesterone-ouabain competition studies indicate that progesterone binds to a 23 amino acid extracellular loop of the plasma membrane α-subunit of Na/K-ATPase. Integral membrane proteins such as caveolins are reported to form Na/K-ATPase-peptide complexes essential for signal transduction. We have characterized the progesterone-induced Na/K-ATPase-caveolin (CAV-1)-steroid 5α-reductase interactions initiating the meiotic divisions. Peptide sequence analysis algorithms indicate that CAV-1 contains two plasma membrane spanning helices, separated by as few as 1-2 amino acid residues at the cell surface. The CAV-1 scaffolding domain, reported to interact with CAV-1 binding (CB) motifs in signaling proteins, overlaps transmembrane (TM) helix 1. The α-subunit of Na/K-ATPase (10 TM helices) contains double CB motifs within TM-1 and TM-10. Steroid 5α-reductase (6 TM helices), an initial step in polar steroid formation, contains CB motifs overlapping TM-1 and TM-6. Computer analysis predicts that interaction between antipathic strands may bring CB motifs and scaffolding domains into close proximity, initiating allostearic changes. Progesterone binding to the α-subunit may thus facilitate CB motif:CAV-1 interaction, which in turn induces helix-helix interaction and generates both a signaling cascade and formation of polar steroids.     

Blot overlays with 32P-labeled fusion proteins

Proteins labeled with 32P can be used as sensitive "prime" in blot overlays to detect binding proteins or domains. Small G-protein Ras can bind GTP with extremely high affinity (Kd approximately 10(-11)-10(-12) M) in the presence of Mg2+. We have taken advantage of this property of Ras to develop a vector that expresses proteins of interest such as glutathione S-transferase (GST)/Ras fusion proteins for noncovalent labeling with [gamma-32P]GTP. The labeling efficiency of this method is >60% and involves a single short incubation step. We have previously identified several binding proteins for the second SH3 domain of the adaptor Nck using this method. Here we illustrate the overlay method using the GST/Ras system and compare results with the SH3 domain labeled by phosphorylation with [gamma-32P]ATP. Both methods are similarly specific and sensitive; however, we show that signals are dependent primarily on GST-mediated probe dimerization. These dimeric probes allow a more stable probe-target complex similar to immunoglobulin interactions, thus significantly improving the sensitivity of the technique.     

Oligomerization through hemopexin and cytoplasmic domains regulates the activity and turnover of membrane-type 1 matrix metalloproteinase.

The formation of multimeric complexes by membrane-type 1 matrix metalloproteinase (MT1-MMP) may facilitate its autocatalytic inactivation or proMMP-2 activation on the cell surface. To characterize these processes, we expressed various glutathione S-transferase/MT1-MMP fusion proteins in human HT-1080 fibrosarcoma cells and SV40-transformed lung fibroblasts and analyzed their effects on MT1-MMP activity and potential homophilic interactions. We report here that MT1-MMP is expressed on the cell surface as oligomeric 200--240-kDa complexes containing both the active 60-kDa and autocatalytically processed 43-kDa species. Overexpression of a glutathione S-transferase/MT1-MMP fusion protein containing the transmembrane and cytoplasmic domains of MT1-MMP inhibited the phorbol 12-myristate 13-acetate-induced autocatalytic cleavage of endogenous MT1-MMP to the 43-kDa species, but not proMMP-2 activation. On the other hand, a similar fusion protein with the hemopexin, transmembrane, and cytoplasmic domains inhibited proMMP-2 activation in a dominant-negative fashion. These results suggest that both the autocatalytic cleavage of MT1-MMP and proMMP-2 activation may be regulated by oligomerization through the cytoplasmic and hemopexin domains. Indeed, either domain, when attached to the cell membrane by a transmembrane domain, formed stable homophilic complexes. Copurification of MT1-MMP with these fusion proteins correlated with their cell-surface co-localization. Thus, MT1-MMP oligomerization through the hemopexin, transmembrane, and cytoplasmic domains controls its catalytic activity.     

Increased solubility of integrin betaA domain using maltose-binding protein as a fusion tag

In proteomics research, generation of recombinant proteins in their native, soluble form with large quantity is often a challenging task. To tackle the expression difficulties, different expression vectors with distinct affinity fusion tags, i.e. pET-43.1a (N-utilization substance A tag), pMAL-cRI (maltose binding protein tag) (MBP tag), pGEX-4T-2 (glutathione S-transferase tag), and pET-15b (hexahistidine tag) were compared for their effects on the productivity and solubility, which were assessed by SDS-PAGE and immunoblotting, of the integrin betaA domain. The incubation temperatures were tested for its effects on these parameters. Our data suggested that MBP tag enhanced the yield and solubility of the betaA domain protein, which can also be recognized using an anti-CD18 antibody, at room temperature incubation. Thus, the nature of fusion partner chosen for expression in bacteria and its incubation temperature would significantly affect the yield and solubility of the recombinant target protein.     

Crystal structure of non-fused glutathione S-transferase from Schistosoma japonicum in complex with glutathione

Schistosoma japonicum glutathione S-transferase (SjGST) is a common fusion tag in recombinant protein production, and its 3-dimensional structure has been studied in the context of drug design. We have determined the crystal structure of non-fused SjGST complexed with glutathione, and compare it to complexes between glutathione and SjGST fusion proteins.     

Screening of fusion partners for high yield expression and purification of bioactive viscotoxins

Viscotoxins are small cationic proteins found in European mistletoe Viscum album. They are highly toxic towards phytopathogenic fungi and cancer cells. Heterologous expression of viscotoxins would broaden the spectrum of methods to be applied for better understanding of their structure and function and satisfy possible biopharmaceutical needs. Here, we evaluated 13 different proteins as a fusion partners for expression in Escherichia coli cells: His6 tag and His6-tagged versions of GB1, ZZ tag, Z tag, maltose binding protein, NusA, glutathione S-transferase, thioredoxin, green fluorescent protein, as well as periplasmic and cytosolic versions of DsbC and DsbA. The fusion to thioredoxin gave the highest yield of soluble viscotoxin. The His6-tagged fusion protein was captured with Ni(2+) affinity chromatography, subsequently cleaved with tobacco etch virus protease. Selective precipitation by acidification of the cleavage mixture was followed by cation exchange chromatography. This protocol yielded 5.2mg of visctoxin A3 from 1l of culture medium corresponding to a recovery rate of 68%. Mass spectrometry showed a high purity of the sample and the presence of three disulfide bridges in the recombinant viscotoxin. Proper folding of the protein was confirmed by heteronuclear NMR spectra recorded on a uniformly 15N-labeled sample. Recombinant viscotoxins prepared using this protocol are toxic to HeLa cells and preserve the activity differences between isoforms B and A3 found in native proteins.     

Swiveling domain mechanism in pyruvate phosphate dikinase

Pyruvate phosphate dikinase (PPDK) catalyzes the reversible conversion of phosphoenolpyruvate (PEP), AMP, and Pi to pyruvate and ATP. The enzyme contains two remotely located reaction centers: the nucleotide partial reaction takes place at the N-terminal domain, and the PEP/pyruvate partial reaction takes place at the C-terminal domain. A central domain, tethered to the N- and C-terminal domains by two closely associated linkers, contains a phosphorylatable histidine residue (His455). The molecular architecture suggests a swiveling domain mechanism that shuttles a phosphoryl group between the two reaction centers. In an early structure of PPDK from Clostridium symbiosum, the His445-containing domain (His domain) was positioned close to the nucleotide binding domain and did not contact the PEP/pyruvate-binding domain. Here, we present the crystal structure of a second conformational state of C. symbiosum PPDK with the His domain adjacent to the PEP-binding domain. The structure was obtained by producing a three-residue mutant protein (R219E/E271R/S262D) that introduces repulsion between the His and nucleotide-binding domains but preserves viable interactions with the PEP/pyruvate-binding domain. Accordingly, the mutant enzyme is competent in catalyzing the PEP/pyruvate half-reaction but the overall activity is abolished. The new structure confirms the swivel motion of the His domain. In addition, upon detachment from the His domain, the two nucleotide-binding subdomains undergo a hinge motion that opens the active-site cleft. A similar hinge motion is expected to accompany nucleotide binding (cleft closure) and release (cleft opening). A model of the coupled swivel and cleft opening motions was generated by interpolation between two end conformations, each with His455 positioned for phosphoryl group transfer from/to one of the substrates. The trajectory of the His domain avoids major clashes with the partner domains while preserving the association of the two linker segments.     

The transmembrane domain sequence affects the structure and function of the Newcastle disease virus fusion protein

The role of specific sequences in the transmembrane (TM) domain of Newcastle disease virus (NDV) fusion (F) protein in the structure and function of this protein was assessed by replacing this domain with the F protein TM domains from two other paramyxoviruses, Sendai virus (SV) and measles virus (MV), or the TM domain of the unrelated glycoprotein (G) of vesicular stomatitis virus (VSV). Mutant proteins with the SV or MV F protein TM domains were expressed, transported to cell surfaces, and proteolytically cleaved at levels comparable to that of the wild-type protein, while mutant proteins with the VSV G protein TM domain were less efficiently expressed on cell surfaces and proteolytically cleaved. All mutant proteins were defective in all steps of membrane fusion, including hemifusion. In contrast to the wild-type protein, the mutant proteins did not form detectable complexes with the NDV hemagglutinin-neuraminidase (HN) protein. As determined by binding of conformation-sensitive antibodies, the conformations of the ectodomains of the mutant proteins were altered. These results show that the specific sequence of the TM domain of the NDV F protein is important for the conformation of the preactivation form of the ectodomain, the interactions of the protein with HN protein, and fusion activity.     

Structural and functional interaction sites between Na,K-ATPase and FXYD proteins

Several members of the FXYD protein family are tissue-specific regulators of Na,K-ATPase that produce distinct effects on its apparent K(+) and Na(+) affinity. Little is known about the interaction sites between the Na,K-ATPase alpha subunit and FXYD proteins that mediate the efficient association and/or the functional effects of FXYD proteins. In this study, we have analyzed the role of the transmembrane segment TM9 of the Na,K-ATPase alpha subunit in the structural and functional interaction with FXYD2, FXYD4, and FXYD7. Mutational analysis combined with expression in Xenopus oocytes reveals that Phe(956), Glu(960), Leu(964), and Phe(967) in TM9 of the Na,K-ATPase alpha subunit represent one face interacting with the three FXYD proteins. Leu(964) and Phe(967) contribute to the efficient association of FXYD proteins with the Na,K-ATPase alpha subunit, whereas Phe(956) and Glu(960) are essential for the transmission of the functional effect of FXYD proteins on the apparent K(+) affinity of Na,K-ATPase. The relative contribution of Phe(956) and Glu(960) to the K(+) effect differs for different FXYD proteins, probably reflecting the intrinsic differences of FXYD proteins on the apparent K(+) affinity of Na,K-ATPase. In contrast to the effect on the apparent K(+) affinity, Phe(956) and Glu(960) are not involved in the effect of FXYD2 and FXYD4 on the apparent Na(+) affinity of Na,K-ATPase. The mutational analysis is in good agreement with a docking model of the Na,K-ATPase/FXYD7 complex, which also predicts the importance of Phe(956), Glu(960), Leu(964), and Phe(967) in subunit interaction. In conclusion, by using mutational analysis and modeling, we show that TM9 of the Na,K-ATPase alpha subunit exposes one face of the helix that interacts with FXYD proteins and contributes to the stable interaction with FXYD proteins, as well as mediating the effect of FXYD proteins on the apparent K(+) affinity of Na,K-ATPase.     

Characterization of interactions of Nck with Sos and dynamin

One of the adaptor proteins, Nck, comprises a single SH2 domain and three SH3 domains that are important in protein-protein interactions. The in vivo association of Nck with the guanine nucleotide exchange factor Sos has been well documented; however, the precise nature of the interaction is unclear. To determine which SH3 domains are involved in the Nck-Sos interaction, individual SH3 domains of Nck were generated as glutathione S-transferase fusion proteins. We found that exclusively the third (C-terminal) SH3 domain of Nck has the ability to bind to Sos. In addition, in [35S]methionine labelled K562 cells, a 100,000 Mr protein was found to be associated with the third SH3 domain of Nck. This protein was identified as dynamin, a GTP-binding protein that has been implicated in clathrin-coated vesicle formation. Dynamin and Nck co-precipitated when cell lysates were immunoprecipitated with anti-Nck antibody. These data suggest that Nck may contribute to Ras activation and the function of dynamin in membrane trafficking through its third SH3 domain.     

Transmembrane domain helix packing stabilizes integrin alphaIIbbeta3 in the low affinity state

Regulated changes in the affinity of integrin adhesion receptors ("activation") play an important role in numerous biological functions including hemostasis, the immune response, and cell migration. Physiological integrin activation is the result of conformational changes in the extracellular domain initiated by the binding of cytoplasmic proteins to integrin cytoplasmic domains. The conformational changes in the extracellular domain are likely caused by disruption of intersubunit interactions between the alpha and beta transmembrane (TM) and cytoplasmic domains. Here, we reasoned that mutation of residues contributing to alpha/beta interactions that stabilize the low affinity state should lead to integrin activation. Thus, we subjected the entire intracellular domain of the beta3 integrin subunit to unbiased random mutagenesis and selected it for activated mutants. 25 unique activating mutations were identified in the TM and membrane-proximal cytoplasmic domain. In contrast, no activating mutations were identified in the more distal cytoplasmic tail, suggesting that this region is dispensable for the maintenance of the inactive state. Among the 13 novel TM domain mutations that lead to integrin activation were several informative point mutations that, in combination with computational modeling, suggested the existence of a specific TM helix-helix packing interface that maintains the low affinity state. The interactions predicted by the model were used to identify additional activating mutations in both the alpha and beta TM domains. Therefore, we propose that helical packing of the alpha and beta TM domains forms a clasp that regulates integrin activation.