Dramatic structural and thermodynamic consequences of repacking a protein's hydrophobic core

BACKGROUND: Rop is an RNA binding, dimeric, four-helix bundle protein with a well-defined, regular hydrophobic core ideally suited for redesign studies. A family of Rop variants in which the hydrophobic core was systematically redesigned has previously been created and characterized. RESULTS: We present a structural and thermodynamic analysis of Ala2Ile2-6, a variant of Rop with an extensively redesigned hydrophobic core. The structure of Ala2Ile2-6 reveals a completely new fold formed by a conformational "flip" of the two protomers around the dimeric interface. The free-energy profile of Ala2Ile2-6 is also very different from that of wild-type Rop. Ala2Ile2-6 has a higher melting temperature than Rop, but undergoes a slightly smaller free-energy change on unfolding. CONCLUSIONS: The structure of Ala2Ile2-6, along with molecular modeling results, demonstrate the importance of tight packing of core residues and the adoption of favorable core side chain rotamer values in determining helix-helix interactions in the four-helix bundle fold. Structural disorder at the N and C termini of Ala2Ile2-6 provides a basis for the large differences in the enthalpy and entropy of Ala2Ile2-6 folding compared with wildtype Rop.     

Role of the simian virus 5 fusion protein N-terminal coiled-coil domain in folding and promotion of membrane fusion

Formation of a six-helix bundle comprised of three C-terminal heptad repeat regions in antiparallel orientation in the grooves of an N-terminal coiled-coil is critical for promotion of membrane fusion by paramyxovirus fusion (F) proteins. We have examined the effect of mutations in four residues of the N-terminal heptad repeat in the simian virus 5 (SV5) F protein on protein folding, transport, and fusogenic activity. The residues chosen have previously been shown from study of isolated peptides to have differing effects on stability of the N-terminal coiled-coil and six-helix bundle (R. E. Dutch, G. P. Leser, and R. A. Lamb, Virology 254:147-159, 1999). The mutant V154M showed reduced proteolytic cleavage and surface expression, indicating a defect in intracellular transport, though this mutation had no effect when studied in isolated peptides. The mutation I137M, previously shown to lower thermostability of the six-helix bundle, resulted in an F protein which was properly processed and transported to the cell surface but which had reduced fusogenic activity. Finally, mutations at L140M and L161M, previously shown to disrupt alpha-helix formation of isolated N-1 peptides but not to affect six-helix bundle formation, resulted in F proteins that were properly processed. Interestingly, the L161M mutant showed increased syncytium formation and promoted fusion at lower temperatures than the wild-type F protein. These results indicate that interactions separate from formation of an N-terminal coiled-coil or six-helix bundle are important in the initial folding and transport of the SV5 F protein and that mutations that destabilize the N-terminal coiled-coil can result in stimulation of membrane fusion.     

Cysteine‐free rop: A four‐helix bundle core mutant has wild‐type stability and structure but dramatically different unfolding kinetics

Cysteine residues can complicate the folding and storage of proteins due to improper formation of disulfide bonds or oxidation of residues that are natively reduced. Wild‐type Rop is a homodimeric four‐helix bundle protein and an important model for protein design in the understanding of protein stability, structure and folding kinetics. In the native state, Rop has two buried, reduced cysteine residues in its core, but these are prone to oxidation in destabilized variants, particularly upon extended storage. To circumvent this problem, we designed and characterized a Cys‐free variant of Rop, including solving the 2.3 Å X‐ray crystal structure. We show that the C38A C52V variant has similar structure, stability and in vivo activity to wild‐type Rop, but that it has dramatically faster unfolding kinetics like virtually every other mutant of Rop that has been characterized. This cysteine‐free Rop has already proven useful for studies on solution topology and on the relationship of core mutations to stability. It also suggests a general strategy for removal of pairs of Cys residues in proteins, both to make them more experimentally tractable and to improve their storage properties for therapeutic or industrial purposes.     

Deletion of lactose repressor carboxyl-terminal domain affects tetramer formation.

The carboxyl-terminal sequence of the lac repressor protein contains heptad repeats of leucines at positions 342, 349, and 356 that are required for tetramer assembly, as substitution of these leucine residues yields solely dimeric species (Chakerian, A. E., Tesmer, V. M., Manly, S. P., Brackett, J. K., Lynch, M. J., Hoh, J. T., and Matthews, K. S. (1991) J. Biol. Chem. 266, 1371-1374; Alberti, S., Oehler, S., von Wilcken-Bergmann, B., Kr?mer, H., and Müller-Hill, B. (1991) New Biol. 3, 57-62). To further investigate this region, which may form a leucine zipper motif, a family of lac repressor carboxyl-terminal deletion mutants eliminating the last 4, 5, 11, 18, and 32 amino acids (aa) has been constructed. The -4 aa mutant, in which all of the leucines in the presumed leucine zipper are intact, is tetrameric and displays operator and inducer binding properties similar to wild-type repressor. The -5 aa, -11 aa, -18 aa, and -32 aa deletion mutants, depleted of 1, 2, or all 3 of the leucines in the heptad repeats, are all dimeric, as demonstrated by gel filtration chromatography. Circular dichroism spectra and protease digestion studies indicate similar secondary/tertiary structures for the mutant and wild-type proteins. Differences in reaction with a monoclonal antibody specific for a subunit interface are observed for the dimeric versus tetrameric proteins, indicative of exposure of the target epitope as a consequence of deletion. Inducer binding properties of the deletion mutants are similar to wild-type tetrameric repressor at neutral pH. Only small differences in affinity and cooperativity from wild-type are evident at elevated pH; thus, the cooperative unit within the tetramer appears to be the dimer. "Apparent" operator binding affinity for the dimeric proteins is diminished, although minimal change in operator dissociation rate constants was observed. The diminution in apparent operator affinity may therefore derive from either 1) dissociation of the dimeric mutants to monomer generating a linked equilibrium or 2) alterations in intrinsic operator affinity of the dimers; the former explanation is favored. This detailed characterization of the purified mutant proteins confirms that the carboxyl-terminal region is involved in the dimer-dimer interface and demonstrates that cooperativity for inducer binding is contained within the dimer unit of the tetramer structure.     

In vivo Rac/Rop localization as well as interaction with RhoGAP and RhoGDI in tobacco pollen tubes: analysis by low‐level expression of fluorescent fusion proteins and bimolecular fluorescence complementation

Polarized Rac/Rop GTPase signaling plays a key role in polar cell growth, which is essential for plant morphogenesis. The molecular and cellular mechanisms responsible for the polarization of Rac/Rop signaling during polar cell growth are only partially understood. Mutant variants of Rac/Rop GTPases lacking specific functions are important tools to investigate these mechanisms, and have been employed to develop a model suggesting that RhoGAP (GTPase activating protein) and RhoGDI (Guanine Nucleotide Dissociation Inhibitor) mediated recycling of Rac/Rop GTPases maintains apical polarization of Rac/Rop activity in pollen tubes, which elongate by ‘tip growth’ (an extreme form of polar cell growth). Despite the importance of these mutant variants for Rac/Rop functional characterization, their distinct intracellular distributions have not been thoroughly comparatively and quantitatively analyzed. Furthermore, support for the proposed RhoGAP and RhoGDI functions in apical polarization of Rac/Rop activity based on the analysis of in vivo interactions between these proteins and Rac/Rop GTPases has been missing. Here, extensive fluorescent protein tagging and bimolecular fluorescence complementation (BiFC) analyses are described of the intracellular distributions of wild type and mutant variants of the tobacco pollen tube Rac/Rop GTPase Nt‐Rac5, as well as of interactions of these Nt‐Rac5 variants with RhoGAP and RhoGDI proteins, in normally growing transiently transformed pollen tubes. Presented results substantially enhance our understanding of apical dynamics of pollen tube Rac/Rop signaling proteins, confirm previously proposed RhoGAP and RhoGDI functions in Rac/Rop polarization and provide important technical insights facilitating future in vivo protein localization and BiFC experiments in pollen tubes.     

Alphavirus nucleocapsid protein contains a putative coiled coil alpha-helix important for core assembly

The alphavirus nucleocapsid core is formed through the energetic contributions of multiple noncovalent interactions mediated by the capsid protein. This protein consists of a poorly conserved N-terminal region of unknown function and a C-terminal conserved autoprotease domain with a major role in virion formation. In this study, an 18-amino-acid conserved region, predicted to fold into an alpha-helix (helix I) and embedded in a low-complexity sequence enriched with basic and Pro residues, has been identified in the N-terminal region of the alphavirus capsid proteins. In Sindbis virus, helix I spans residues 38 to 55 and contains three conserved leucine residues, L38, L45, and L52, conforming to the heptad amino acid organization evident in leucine zipper proteins. Helix I consists of an N-terminally truncated heptad and two complete heptad repeats with beta-branched residues and conserved leucine residues occupying the a and d positions of the helix, respectively. Complete or partial deletion of helix I, or single-site substitutions at the conserved leucine residues (L45 and L52), caused a significant decrease in virus replication. The mutant viruses were more sensitive to elevated temperature than wild-type virus. These mutant viruses also failed to accumulate cores in the cytoplasm of infected cells, although they did not have defects in protein translation or processing. Analysis of these mutants using an in vitro assembly system indicated that the majority were defective in core particle assembly. Furthermore, mutant proteins showed a trans-dominant negative phenotype in in vitro assembly reactions involving mutant and wild-type proteins. We propose that helix I plays a central role in the assembly of nucleocapsid cores through coiled coil interactions. These interactions may stabilize subviral intermediates formed through the interactions of the C-terminal domain of the capsid protein and the genomic RNA and contribute to the stability of the virion.     

Intracellular, periodic structures in the gliding bacterium Myxococcus xanthus.

Electron microscopic observations of thin sections of Myxococcus xanthus vegetative cells revealed the presence of cytoplasmic bundles of 4- to 5-nm-diameter filaments running longtitudinally below the cell membrane and terminating in association with the envelope near one pole. Part of each bundle demonstrated a herringbone-like periodicity (approximately 12-nm spacing). This structure was observed in cells from shake cultures and in gliding cells fixed by several methods. It is proposed that the structure may be attached to the envelope near both poles in gliding cells and that the motive force for motility may be provided by its contraction and relaxation. In one of four nongliding mutants examined, the periodicity was indistinct or lacking. In this mutant another structure, comprised of linearly arrayed beads, was observed in association with the filamentous bundle. Another structure, characterized by major, transverse bands (approximately 34 nm apart), occurred in patches that may traverse the diameter of the wild-type cells in which the structure was observed.     

新城疫病毒囊膜糖蛋白七肽重复区的融合作用

在新城疫病毒（Newcastle diseasevirus,NDV）膜融合的过程中融合糖蛋白（Fusion protein,F）的两段七肽重复区（Heptad repeat,HR）发挥着重要作用。这两段七肽重复区能够形成反相平行的六螺旋束结构,这被认为是融合蛋白融合后构象的核心结构。对融合作用的深入系统研究将有助于膜融合病毒的防控。     

Redesigning the hydrophobic core of a four-helix-bundle protein.

Rationally redesigned variants of the 4-helix-bundle protein Rop are described. The novel proteins have simplified, repacked, hydrophobic cores and yet reproduce the structure and native-like physical properties of the wild-type protein. The repacked proteins have been characterized thermodynamically and their equilibrium and kinetic thermal and chemical unfolding properties are compared with those of wild-type Rop. The equilibrium stability of the repacked proteins to thermal denaturation is enhanced relative to that of the wild-type protein. The rate of chemically induced folding and unfolding of wild-type Rop is extremely slow when compared with other small proteins. Interestingly, although the repacked proteins are more thermally stable than the wild type, their rates of chemically induced folding and unfolding are greatly increased in comparison to wild type. Perhaps as a consequence of this, their equilibrium stabilities to chemical denaturants are slightly reduced in comparison to the wild type.     

Insights into dimerization and four-helix bundle formation found by dissection of the dimer interface of the GrpE protein from Escherichia coli

The GrpE heat shock protein from Escherichia coli has a homodimeric structure. The dimer interface encompasses two long alpha-helices at the NH(2)-terminal end from each monomer (forming a "tail"), which lead into a small four-helix bundle from which each monomer contributes two short sequential alpha-helices in an antiparallel topological arrangement. We have created a number of different deletion mutants of GrpE that have portions of the dimer interface to investigate requirements for dimerization and to study four-helix bundle formation. Using chemical crosslinking and analytical ultracentrifugation techniques to probe for multimeric states, we find that a mutant containing only the long alpha-helical tail portion (GrpE1-88) is unable to form a dimer, most likely due to a decrease in alpha-helical content as determined by circular dichroism spectroscopy, thus one reason for a dimeric structure for the GrpE protein is to support the tail region. Mutants containing both of the short alpha-helices (GrpE1-138 and GrpE88-197) are able to form a dimer and presumably the four-helix bundle at the dimer interface. These two mutants have equilibrium constants for the monomer-dimer equilibrium that are very similar to the full-length protein suggesting that the tail region does not contribute significantly to the stability of the dimer. Interestingly, one mutant that contains just one of the short alpha-helices (GrpE1-112) exists as a tetrameric species, which presumably is forming a four-helix bundle structure. A proposed model is discussed for this mutant and its relevance for factors influencing four-helix bundle formation.     

Fusogenic variants of a noncytopathic paramyxovirus

SER virus is a type 5 parainfluenza virus that does not exhibit syncytium formation, in contrast to most other paramyxoviruses. This property has been attributed, at least in part, to the presence of an extension of the cytoplasmic tail (CT) of the SER F protein, as truncations or mutations of this region resulted in enhanced fusion. In this study we used repeated passage to select for mutant SER viruses, which were found to be fusogenic. The mutant viruses replicated at levels comparable to or higher than the wild-type SER virus and caused plaque formation, in contrast to the wild-type virus which does not form plaques. The mutants differed strikingly in their plaque sizes. The F genes of mutant viruses were cloned and sequenced and shared some mutations, including a proline-to-leucine change at position 22 and an isoleucine-to-leucine substitution at position 191; other changes that were specific to each mutant were also found. The HN proteins of mutant viruses also showed mutations spanning the length of the protein whereas the M protein showed a consistent mutation, threonine to isoleucine, at position 129. The structure of the F protein was used to identify residues involved in the mutant phenotypes in terms of their location and proximity to heptad repeat domains.     

Biophysical analysis of the endoplasmic reticulum-resident chaperone/heat shock protein gp96/GRP94 and its complex with peptide antigen

Animals vaccinated with heat shock protein (HSP)--peptide complexes develop specific protective immunity against cancers from which the HSPs were originally isolated. This autologous specific immunity has been demonstrated using a number of HSP--peptide antigen complexes. A prototypical HSP-based cancer vaccine is the gp96--peptide antigen complex, which is currently undergoing human clinical trials. Here, we analyzed the structure of a recombinant wild-type and a mutant gp96 protein and their peptide complexes using a number of biophysical techniques. Gel filtration chromatography, dynamic light scattering, and equilibrium analytical ultracentrifugation demonstrated that both a wild-type gp96 and a gp96 mutant lacking a dimerization domain formed higher order structures. More detailed analysis using scanning transmission electron microscopy indicated that both the wild-type and dimerization deletion mutant gp96 protein were organized, unexpectedly, into large aggregates. Size distributions ranged from dimers to octamers and higher. Circular dichroism and intrinsic Trp fluorescence suggested that the gp96 dimerization domain deletion mutant protein was more compact than the wild-type gp96. A fluorescent peptide antigen was synthesized, and the peptide-binding properties of wild-type and the dimerization domain deletion mutant gp96 were studied. Fluorescence lifetime and anisotropy decay showed that the bound antigenic peptide was located in a hydrophobic pocket, with considerable free space for the rotation of the probe. Deletion of the dimerization domain affected the peptide-binding microenvironment, although peptide-binding affinity was reduced by only a small extent. Peptide--gp96 complexes were extremely stable, persisting for many days in the cold. The extraordinary stability of peptide--gp96 complexes and the plasticity of the peptide-binding pocket support the proposed relay of diverse peptides to MHC and/or other molecules via molecular recognition.     

Relationships between sequence and structure for the four-alpha-helix bundle tertiary motif in proteins.

The sequences of four-alpha-helical bundle proteins are characterized by a pattern of hydrophilic and hydrophobic amino acids which is repeated every seven residues. At each position of the heptad repeat there are specific constraints on the amino acid properties which result from the topology of the tertiary motif. These constraints give rise to patterns of amino acid distribution which are distinct from those of other proteins. The distributions in each of the heptad positions have been determined by a statistical analysis of structural and sequence data derived from seven families of aligned protein sequences. The constitution of each position is dominated by a very small number of different amino acids, with the core positions consisting overwhelmingly of Leu and Ala. The positional preferences of the individual amino acids can be generally interpreted in terms of residue properties and topological constraints. The potential for four-alpha-helix bundle folding is reflected primarily in the pattern of residue occurrence in the heptad and not in the overall amino acid composition of the protein. Possible applications of this analysis in structure predictions, sequence alignments and in the rational design and engineering of four-alpha-helical bundle proteins are discussed.     

Functional characterization of the placental fusogenic membrane protein syncytin

Syncytin is an envelope protein of the human endogenous retrovirus family W (HERV-W). Syncytin is specifically expressed in the human placenta and mediates trophoblast cell fusion into the multinucleated syncytiotrophoblast layer. It is a polypeptide of 538 amino acids and is predicted to be posttranslationally cleaved into a surface (SU) subunit and a transmembrane (TM) subunit. Functional characterization of syncytin protein can aid understanding of the molecular mechanism underlying syncytin-mediated cell fusion. In this report, we studied the structure-function relationship of syncytin in 293T and HeLa cells transiently expressing wild-type syncytin or syncytin mutants generated by linker scanning and deletion mutagenesis. Of the 22 linker-inserted mutants, mutants InS51, InV139, InE156, InS493, InA506, and InL529 were fusogenic, suggesting that regions around amino acids S51, V139, and E156 in the SU subunit and S493, A506, and L529 in the cytoplasmic domain (CTM) of syncytin are flexible in conformation. Of the 17 deletion mutants, nine mutants with deletions in the region from amino acids 479 to 538 were fusogenic. The deletion mutant DelI480, containing only the first four amino acid residues in the cytoplasmic domain, had enhanced fusogenic activity in comparison with the wild-type. In addition, two heptad repeat regions (HRA and B) were defined in the TM subunit of syncytin. A peptide inhibitor derived from the C-terminal heptad repeat region (HRB) was shown to potently inhibit syncytin-mediated cell fusion. Our results suggest that the cytoplasmic domain of syncytin is not essential for syncytin-mediated fusion but may play a regulatory role, and an intramolecular interaction between HRA and B is involved in the fusion process.     

Molecular dynamics as a tool to detect protein foldability. A mutant of domain B1 of protein G with non-native secondary structure propensities

The usefulness of molecular dynamics to assess the structural integrity of mutants containing several mutations has been investigated. Our goal was to determine whether molecular dynamics would be able to discriminate mutants of a protein having a close-to-wild-type fold, from those that are not folded under the same conditions. We used as a model the B1 domain of protein G in which we replaced the unique central alpha-helix by the sequence of the second beta-hairpin, which has a strong intrinsic propensity to form this secondary structure in solution. In the resulting protein, one-third of the secondary structure has been replaced by a non-native one. Models of the mutants were built based on the three-dimensional structure of the wild-type GB1 domain. During 2 ns of molecular dynamics simulations on these models, mutants containing up to 10 mutations in the helix retained the native fold, while another mutant with an additional mutation unfolded. This result is in agreement with our circular dichroism and NMR experiments, which indicated that the former mutants fold into a structure similar to the wild-type, as opposed to the latter mutant which is partly unfolded. Additionally, a mutant containing six mutations scattered through the surface of the domain, and which is unfolded, was also detected by the simulation. This study suggests that molecular dynamics calculations could be performed on molecular models of mutants of a protein to evaluate their foldability, prior to a mutagenesis experiment.     

Intrinsic versus mutation dependent instability/flexibility: a comparative analysis of the structure and dynamics of wild-type transthyretin and its pathogenic variants

Transthyretin (TTR) is one of the about 20 known human proteins associated with amyloidosis which is characterized by the accumulation of amyloid fibrils in tissues or extracellular matrix surrounding vital organs. Unlike Alzheimer's fibrils that comprise a fragment of a large precursor protein, TTR amyloid fibrils are composed of both full-length protein and fragments of the molecule. The native state of TTR is a homotetramer with eight beta-strands organized into a beta-sandwich in each monomer. To elucidate the structural reorganization mechanisms preceding amyloid formation, it is important to characterize the dynamic features of the wild-type native state as well as to reveal the influence of disease-associated mutations on the structure and dynamics. Molecular dynamics (MD) simulations complement X-ray crystallography and D-H exchange to capture the intrinsically unstable/flexible sites of the wild-type as well as the mutation dependent unstable sites of the pathogenic variants. Our results of MD simulations have shown that the Leu55-->Pro (L55P) mutation occurs in an intrinsically unstable site, leading to substantial local and global structural changes. This observation supports the early speculation that the C-strand-loop-D-strand rearrangement leads to the formation of amyloidogenic intermediates. In addition to the D strand, the alpha-helical region and the strands at the monomer-monomer interface are also intrinsically unstable. The central channel of L55P-TTR undergoes opening and closing fluctuations, which may provide an explanation for the fact that while the mutation is far from the channel, the mutant shows a substantial low binding affinity of thyroxine.     

Genetic and structural analysis of the ColE1 Rop (Rom) protein.

Repressor of primer (Rop) is a small dimeric protein that participates in the mechanism that controls the copy number of plasmid of the ColE1 family by increasing the affinity between two complementary RNAs. The Rop dimer is a bundle of four tightly packed alpha-helices that are held together by hydrophobic interactions. We have systematically altered, by site directed mutagenesis, most of the solvent exposed amino acids of the Rop bundle and we have identified the alterations that cause a decrease of the activity of the regulatory molecule. We conclude that Rop folding is rather insensitive to amino acid substitutions and to other mutations as drastic as deletions and insertions. Looking along the 2-fold symmetry axis the amino acid side chains whose alterations affect the function of Rop are all located on one side of the molecule. Furthermore they are clustered at the extremities of the alpha-helix bundle, the only exception being the aromatic ring of Phe-14.