The central interactive region of human MxA GTPase is involved in GTPase activation and interaction with viral target structures

To define domains of the human MxA GTPase involved in GTP hydrolysis and antiviral activity, we used two monoclonal antibodies (mAb) directed against different regions of the molecule. mAb 2C12 recognizes an epitope in the central interactive region of MxA, whereas mAb M143 is directed against the N-terminal G domain. mAb 2C12 greatly stimulated MxA GTPase activity, suggesting that antibody-mediated crosslinking enhances GTP hydrolysis. In contrast, monovalent Fab fragments of 2C12 abolished GTPase activity, most likely by blocking intramolecular interactions required for GTPase activation. Interestingly, intact IgG molecules and Fab fragments of 2C12 both prevented association of MxA with viral nucleocapsids and neutralized MxA antiviral activity in vivo. mAb M143 had no effect on MxA function, indicating that this antibody binds outside functional regions. These data demonstrate that the central region recognized by 2C12 is critical for regulation of GTPase activity and viral target recognition.     

Dominant-negative mutants of human MxA protein: domains in the carboxy-terminal moiety are important for oligomerization and antiviral activity.

Human MxA protein is an interferon-induced 76-kDa GTPase that exhibits antiviral activity against several RNA viruses. Wild-type MxA accumulates in the cytoplasm of cells. TMxA, a modified form of wild-type MxA carrying a foreign nuclear localization signal, accumulates in the cell nucleus. Here we show that MxA protein is translocated into the nucleus together with TMxA when both proteins are expressed simultaneously in the same cell, demonstrating that MxA molecules form tight complexes in living cells. To define domains important for MxA-MxA interaction and antiviral function in vivo, we expressed mutant forms of MxA together with wild-type MxA or TMxA in appropriate cells and analyzed subcellular localization and interfering effects. An MxA deletion mutant, MxA(359-572), formed heterooligomers with TMxA and was translocated to the nucleus, indicating that the region between amino acid positions 359 and 572 contains an interaction domain which is critical for oligomerization of MxA proteins. Mutant T103A with threonine at position 103 replaced by alanine had lost both GTPase and antiviral activities. T103A exhibited a dominant-interfering effect on the antiviral activity of wild-type MxA rendering MxA-expressing cells susceptible to infection with influenza A virus, Thogoto virus, and vesicular stomatitis virus. To determine which sequences are critical for the dominant-negative effect of T103A, we expressed truncated forms of T103A together with wild-type protein. A C-terminal deletion mutant lacking the last 90 amino acids had lost interfering capacity, indicating that an intact C terminus was required. Surprisingly, a truncated version of MxA representing only the C-terminal half of the molecule exerted also a dominant-negative effect on wild-type function, demonstrating that sequences in the C-terminal moiety of MxA are necessary and sufficient for interference. However, all MxA mutants formed hetero-oligomers with TMxA and were translocated to the nucleus, indicating that physical interaction alone is not sufficient for disturbing wild-type function. We propose that dominant-negative mutants directly influence wild-type activity within hetero-oligomers or else compete with wild-type MxA for a cellular or viral target.     

The pI and pXI assembly proteins serve separate and essential roles in filamentous phage assembly.

Three non-capsid, phage-encoded proteins, pI, pIV and pXI, are required for assembly of the filamentous bacteriophage at the envelope of Escherichia coli. pIV forms the outer membrane component of the assembly site, and pI and pXI are predicted to form the cytoplasmic membrane component. pXI is the result of an in-frame internal translational initiation event in gene I and is identical with the carboxyl-terminal third of pI in amino acid sequence, membrane localization and topology. The two proteins share a cytoplasmic domain predicted to be an amphipathic helix, a transmembrane domain, and a periplasmic domain. By mutating the initiation site for pXI, a phage was made that produced only pI and was shown to absolutely require functional plasmid-encoded pXI for growth. Further mutational analysis was done to examine the functional determinants of the amphipathic helix and periplasmic domains of the pI and pXI proteins. The results show that the amphipathic helix region is very important for pI function but not for pXI function. Mutational analysis of the periplasmic domains of pI and pXI implies that these domains also perform separate functions, and suggests that the interaction between pI and pIV in the periplasm is critical for assembly. The results are discussed with regard to the separate roles that the pI and pXI proteins play in the overall process of phage assembly.     

Identification of a regulatory motif in Hsp70 that affects ATPase activity, substrate binding and interaction with HDJ-1.

The Hsp70 family of molecular chaperones has an essential role in the synthesis, folding and translocation of the nascent peptide chain. While the general features of these activities are well documented, less is understood about the regulation of these activities. The ATPase rate is stimulated by non-native proteins, furthermore, interaction with ATP leads to the release of protein substrate concurrent with a conformational change in Hsp70. One interpretation of these data is that the two domains of Hsp70 interact. In the process of mapping the carboxyl-terminal boundary of the substrate binding domain for human Hsp70, we identified a regulatory motif, EEVD, which is conserved at the extreme carboxyl terminus among nearly all cloned cytosolic eukaryotic Hsp70s. Deletion or mutation of EEVD affects the ATPase activity, the ability to interact with substrates, and interferes with the ability of the mutant Hsp70 to interact with HDJ-1 in the refolding of denatured firefly luciferase. Examination of the biophysical properties of the mutant Hsp70s reveals a change in the overall shape and conformation of the protein consistent with reduced interactions between the two domains. These data suggest that the EEVD motif is involved in the intramolecular regulation of Hsp70 function and intermolecular interactions with HDJ-1.     

The cytoplasmic domain of HIV-1 gp41 interacts with the carboxyl-terminal region of alpha-catenin.

To know the cellular protein interactions with the viral protein can give an insight into the molecular mechanisms of the virus life cycle. As the function of the cytoplasmic domain of human immunodeficiency virus type 1 (HIV-1) gp41 is not known clearly, we searched for a cellular protein that interacts with the cytoplasmic domain of the HIV-1 gp41 using the yeast two-hybrid assay system. Screening of HeLa cell cDNA library yielded alpha-catenin cDNA. The cytoplasmic domain of the HIV-1 gp41 and the simian immunodeficiency virus (SIV) gp41 were able to interact with the carboxyl-terminal region of alpha-catenin specifically. Mapping of the interaction sites revealed that the interaction between the domain containing the second helix structure from the carboxyl-terminus of HIV-1 gp41 and the carboxyl-terminal region of alpha-catenin was stronger than other domains of gp41.     

Intra- and intermolecular interactions of the catalytic domains of human CD45 protein tyrosine phosphatase

We have investigated protein-protein interaction between distinct domains of the human CD45 cytoplasmic region using a yeast two-hybrid system. Consequently, we have found that the spacer region between two tandem PTP domains specifically interacts with the membrane-distal PTP domain (D2). This interaction is mediated by a stretch of amino acid residues in the carboxyl-terminal half of the spacer region. Although the membrane proximal region does not directly interact with either of the two PTP domains, it appears to function in stabilizing the interaction between the spacer region and D2. We also demonstrate that the interaction between the spacer region and D2 might take place intramolecularly.     

Characterization of the supporting role of SecE in protein translocation

SecYEG functions as a membrane channel for protein export. SecY constitutes the protein-conducting pore, which is enwrapped by SecE in a V-shaped manner. In its minimal form SecE consists of a single transmembrane segment that is connected to a surface-exposed amphipathic α-helix via a flexible hinge. These two domains are the major sites of interaction between SecE and SecY. Specific cleavage of SecE at the hinge region, which destroys the interaction between the two SecE domains, reduced translocation. When SecE and SecY were disulfide bonded at the two sites of interaction, protein translocation was not affected. This suggests that the SecY and SecE interactions are static, while the hinge region provides flexibility to allow the SecY pore to open.     

Reticulon 3 interacts with NS4B of the hepatitis C virus and negatively regulates viral replication by disrupting NS4B self‐interaction

The non‐structural protein 4B (NS4B) of the hepatitis C virus (HCV) is an endoplasmic reticulum (ER) membrane protein comprising two consecutive amphipathic α‐helical domains (AH1 and AH2). Its self‐oligomerization via the AH2 domain is required for the formation of the membranous web that is necessary for viral replication. Previously, we reported that the host‐encoded ER‐associated reticulon 3 (RTN3) protein is involved in the formation of the replication‐associated membranes of (+)RNA enteroviruses during viral replication. In this study, we demonstrated that the second transmembrane region of RTN3 competed for, and bound to, the AH2 domain of NS4B, thus abolishing NS4B self‐interaction and leading to the downregulation of viral replication. This interaction was mediated by two crucial residues, lysine 52 and tyrosine 63, of AH2, and was regulated by the AH1 domain. The silencing of RTN3 in Huh7 and AVA5 cells harbouring an HCV replicon enhanced the replication of HCV, which was counteracted by the overexpression of recombinant RTN3. The synthesis of viral RNA was also increased in siRNA‐transfected human primary hepatocytes infected with HCV derived from cell culture. Our results demonstrated that RTN3 acted as a restriction factor to limit the replication of HCV.     

A specific intermolecular association between the regulatory domains of a Tec family kinase

Interleukin-2 tyrosine kinase (Itk), is a T-cell specific tyrosine kinase of the Tec family. We have examined a novel intermolecular interaction between the SH3 and SH2 domains of Itk. In addition to the interaction between the isolated domains, we have found that the dual SH3/SH2 domain-containing fragment of Itk self-associates in a specific manner in solution. Tec family members contain the SH3, SH2 and catalytic domains common to many kinase families but are distinguished by a unique amino-terminal sequence, which contains a proline-rich stretch. Previous work has identified an intramolecular regulatory association between the proline-rich region and the adjacent SH3 domain of Itk. The intermolecular interaction between the SH3 and SH2 domains of Itk that we describe provides a possible mechanism for displacement of this intramolecular regulatory sequence, a step that may be required for full Tec kinase activation. Additionally, localization of the interacting surfaces on both the SH3 and SH2 domains by chemical shift mapping has provided information about the molecular details of this recognition event. The interaction involves the conserved aromatic binding pocket of the SH3 domain and a newly defined binding surface on the SH2 domain. The interacting residues on the SH2 domain do not conform to the consensus motif for an SH3 proline-rich ligand. Interestingly, we note a striking correlation between the SH2 residues that mediate this interaction and those residues that, when mutated in the Tec family member Btk, cause the hereditary immune disorder, X-linked agamaglobulinemia.     

Lipid binding by Escherichia coli pyruvate oxidase is disrupted by small alterations of the carboxyl-terminal region

Escherichia coli pyruvate oxidase is a membrane-associated flavoprotein dehydrogenase which is greatly activated by lipids and detergents. The carboxyl-terminal region of the protein has been shown to play a critical role in the interaction with lipids. We report mutations generated by chemical and oligonucleotide-mediated site-directed mutagenesis of the poxB gene which result in enzymes defective in lipid activation. Nine mutants were isolated which encode enzymes with point mutations in the carboxyl-terminal segment of the protein. Two mutant lesions introduced termination codons giving enzymes lacking the last nine or three amino acids of the protein which were unable to interact with detergents in vitro and were unable to function in vivo. Of the missense mutants isolated, two were most informative. One was the substitution of Glu-564 with proline in the PoxB16 oxidase. This residue lies in the center of a putative lipid-binding amphipathic alpha-helix (Arg-558 to Thr-568) located close to the carboxyl terminus. Strains producing the PoxB16 oxidase were devoid of oxidase activity in vivo, the enzymes could not be activated by Triton X-100, and were activated poorly by phospholipids in vitro. These results indicated that the PoxB16 oxidase lacked normal lipid-binding ability. Another mutant oxidase (PoxB15) in which proline was substituted for Asp-560 at the beginning of the amphipathic alpha-helix had normal oxidase activity. These findings indicate that the amphipathic alpha-helix structure plays an essential role in the activation and lipid-binding properties of the enzyme. The second informative missense mutation was the substitution of the carboxyl-terminal arginine with glycine. This enzyme showed normal activation in vitro by phospholipids and some detergents, and somewhat reduced activity in vivo. This mutant enzyme appeared to dissociate from detergent vesicles more readily than does the normal enzyme. A model for the membrane interaction of the carboxyl terminus based on the properties of these mutant proteins is presented.     

The heptad repeat domain 1 of Mitofusin has membrane destabilization function in mitochondrial fusion

Mitochondria are double‐membrane‐bound organelles that constantly change shape through membrane fusion and fission. Outer mitochondrial membrane fusion is controlled by Mitofusin, whose molecular architecture consists of an N‐terminal GTPase domain, a first heptad repeat domain (HR1), two transmembrane domains, and a second heptad repeat domain (HR2). The mode of action of Mitofusin and the specific roles played by each of these functional domains in mitochondrial fusion are not fully understood. Here, using a combination of in situ and in vitro fusion assays, we show that HR1 induces membrane fusion and possesses a conserved amphipathic helix that folds upon interaction with the lipid bilayer surface. Our results strongly suggest that HR1 facilitates membrane fusion by destabilizing the lipid bilayer structure, notably in membrane regions presenting lipid packing defects. This mechanism for fusion is thus distinct from that described for the heptad repeat domains of SNARE and viral proteins, which assemble as membrane‐bridging complexes, triggering close membrane apposition and fusion, and is more closely related to that of the C‐terminal amphipathic tail of the Atlastin protein.     

Mass spectrometry analysis of HIV-1 Vif reveals an increase in ordered structure upon oligomerization in regions necessary for viral infectivity

HIV-1 Vif, an accessory protein in the viral genome, performs an important role in viral pathogenesis by facilitating the degradation of APOBEC3G, an endogenous cellular inhibitor of HIV-1 replication. In this study, intrinsically disordered regions are predicted in HIV-1 Vif using sequence-based algorithms. Intrinsic disorder may explain why traditional structure determination of HIV-1 Vif has been elusive, making structure-based drug design impossible. To characterize HIV-1 Vif's structural topology and to map the domains involved in oligomerization we used chemical cross-linking, proteolysis, and mass spectrometry. Cross-linking showed evidence of monomer, dimer, and trimer species via denaturing gel analysis and an additional tetramer via western blot analysis. We identified 47 unique linear peptides and 24 (13 intramolecular; 11 intermolecular) noncontiguous, cross-linked peptides, among the noncross-linked monomer, cross-linked monomer, cross-linked dimer, and cross-linked trimer samples. Almost complete peptide coverage of the N-terminus is observed in all samples analyzed, however reduced peptide coverage in the C-terminal region is observed in the dimer and trimer samples. These differences in peptide coverage or "protections" between dimer and trimer indicate specific differences in packing between the two oligomeric forms. Intramolecular cross-links within the monomer suggest that the N-terminus is likely folded into a compact domain, while the C-terminus remains intrinsically disordered. Upon oligomerization, as evidenced by the intermolecular cross-links, the C-terminus of one Vif protein becomes ordered by wrapping back on the N-terminal domain of another. In addition, the majority of the intramolecular cross-links map to regions that have been previously reported to be necessary for viral infectivity. Thus, this data suggests HIV-1 Vif is in a dynamic equilibrium between the various oligomers potentially allowing it to interact with other binding partners.     

The crystal structure of Escherichia coli group 4 capsule protein GfcC reveals a domain organization resembling that of Wza

We report the 1.9 ? resolution crystal structure of enteropathogenic Escherichia coli GfcC, a periplasmic protein encoded by the gfc operon, which is essential for assembly of group 4 polysaccharide capsule (O-antigen capsule). Presumed gene orthologs of gfcC are present in capsule-encoding regions of at least 29 genera of Gram-negative bacteria. GfcC, a member of the DUF1017 family, is comprised of tandem β-grasp (ubiquitin-like) domains (D2 and D3) and a carboxyl-terminal amphipathic helix, a domain arrangement reminiscent of that of Wza that forms an exit pore for group 1 capsule export. Unlike the membrane-spanning C-terminal helix from Wza, the GfcC C-terminal helix packs against D3. Previously unobserved in a β-grasp domain structure is a 48-residue helical hairpin insert in D2 that binds to D3, constraining its position and sequestering the carboxyl-terminal amphipathic helix. A centrally located and invariant Arg115 not only is essential for proper localization but also forms one of two mostly conserved pockets. Finally, we draw analogies between a GfcC protein fused to an outer membrane β-barrel pore in some species and fusion proteins necessary for secreting biofilm-forming exopolysaccharides.     

Formation of native-like mammalian sperm cell chromatin with folded bull protamine

The DNA of most vertebrate sperm cells is packaged by protamines. The primary structure of mammalian protamine I can be divided into three domains, a central DNA binding domain that is arginine-rich and amino- and carboxyl-terminal domains that are rich in cysteine residues. In native bull sperm chromatin, intramolecular disulfide bonds hold the terminal domains of bull protamine folded back onto the central DNA binding domain, whereas intermolecular disulfide bonds between DNA-bound protamines help stabilize the chromatin of mature mammalian sperm cells. Folded bull protamine was used to condense DNA in vitro under various solution conditions. Using transmission electron microscopy and light scattering, we show that bull protamine forms particles with DNA that are morphologically similar to the subunits of native bull sperm chromatin. In addition, the stability provided by intermolecular disulfide bonds formed between bull protamine molecules within in vitro DNA condensates is comparable with that observed for native bull sperm chromatin. The importance of the bull protamine terminal domains in controlling the bull sperm chromatin morphology is indicated by our observation that DNA condensates formed under identical conditions with a fish protamine, which lacks cysteine-rich terminal domains, do not produce as uniform structures as bull protamine. A model is also presented for the bull protamine.DNA complex in native sperm cell chromatin that provides an explanation for the positions of the cysteine residues in bull protamine that form intermolecular disulfide bonds.     

Partial proteolysis of simian virus 40 T antigen reveals intramolecular contacts between domains and conformation changes upon hexamer assembly

Simian virus 40 large tumor antigen (Tag) is a multi-functional viral protein that binds specifically to SV40 origin DNA, serves as the replicative DNA helicase, and orchestrates the assembly and operation of the viral replisome. Tag associated with Mg-ATP forms hexamers and, in the presence of SV40 origin DNA, double hexamers. Limited tryptic digestion of monomeric Tag revealed three major stable structural domains. The N-terminal domain spans amino acids 1-130, the central domain comprises amino acids 131-476, and the C-terminal domain extends from amino acid 513 to amino acid 698. Co-immunoprecipitation of digestion products of monomeric Tag suggests that the N-terminal domain associates stably with sequences located in the central region of the same Tag molecule. Hexamer formation protected the tryptic cleavage sites in the exposed region between the central and C-terminal domains. Upon hexamerization, this exposed region also became less accessible to a monoclonal antibody whose epitope maps in that region. The tryptic digestion products of the soluble hexamer and the DNA-bound double hexamer were indistinguishable. A low-resolution model of the intramolecular and intermolecular interactions among Tag domains in the double hexamer is proposed.     

Antigelling and antisickling bisphenyl oligopeptides and peptide analogues have similar structural features

Single-crystal X-ray diffraction was used to determine the three-dimensional structures of two antigelling oligopeptides, L-lysyl-L-phenylalanyl-L-phenylalanine and L-phenylalanylglycylglycyl-D-phenylalanine, and two antisickling peptide analogues, L-phenylalanine benzyl ester and N-phenylacetyl-L-phenylalanine. Although these bisphenyl compounds are chemically quite different from one another, they demonstrate unusual structural similarities: The molecules have compact conformations in which the two phenyl rings are positioned approximately 5 A apart with interplanar angles approaching 90 degrees, thereby making intramolecular edge-to-face interactions. In addition, the polar atoms, nitrogen and oxygen, are in close proximity without forming intramolecular hydrogen bonds. The relative spatial distribution of polar and nonpolar atoms renders the structures compact and amphipathic. The intramolecular edge-to-face interaction between two aromatic rings, which brings a hydrogen atom with relative positive charge near the pi-electron cloud with relative negative charge, is enthalpically favorable and maintains the molecules in a compact and amphipathic conformation. Nonbonded potential energy calculations were used to characterize the energetics of the aromatic-aromatic interaction, and they showed that the observed geometry is stabilized enthalpically by a favorable interaction on the order of -1 to -2 kcal/mol. Structural differences between the two antisickling and the two antigelling agents suggest that molecular volume limits red cell membrane passage. These data provide a molecular structural framework from which to design and synthesize amphipathic bisphenyl compounds that both bind to deoxy sickle cell hemoglobin and cross the erythrocyte membrane.     

The role of the carboxyl terminus in ClC chloride channel function

The human muscle chloride channel ClC-1 has a 398-amino acid carboxyl-terminal domain that resides in the cytoplasm and contains two CBS (cystathionine-beta-synthase) domains. To examine the role of this region, we studied various carboxyl-terminal truncations by heterologous expression in mammalian cells, whole-cell patch clamp recording, and confocal imaging. Channel constructs lacking parts of the distal CBS domain, CBS2, did not produce functional channels, whereas deletion of CBS1 was tolerated. ClC channels are dimeric proteins with two ion conduction pathways (protopores). In heterodimeric channels consisting of one wild type subunit and one subunit in which the carboxyl terminus was completely deleted, only the wild type protopore was functional, indicating that the carboxyl terminus supports the function of the protopore. All carboxyl-terminal-truncated mutant channels fused to yellow fluorescent protein were translated and the majority inserted into the plasma membrane as revealed by confocal microscopy. Fusion proteins of cyan fluorescent protein linked to various fragments of the carboxyl terminus formed soluble proteins that could be redistributed to the surface membrane through binding to certain truncated channel subunits. Stable binding only occurs between carboxyl-terminal fragments of a single subunit, not between carboxyl termini of different subunits and not between carboxyl-terminal and transmembrane domains. However, an interaction with transmembrane domains can modify the binding properties of particular carboxyl-terminal proteins. Our results demonstrate that the carboxyl terminus of ClC-1 is not necessary for intracellular trafficking but is critical for channel function. Carboxyl termini fold independently and modify individual protopores of the double-barreled channel.