Your search keyword '"Stanley C. Kwok"' showing total 10 results

1. Cysteine usage in Sulfolobus spindle-shaped virus 1 and extension to hyperthermophilic viruses in general

Author

Brian Bothner, G. Judson Corn, Paul Kraft, Eric Gillitzer, C. Martin Lawrence, Stanley C. Kwok, Walid S. Maaty, Smita K. Menon, Mark J. Young, and Brian J. Eilers

Subjects

Models, Molecular, Proteome, Fuselloviridae, Genome, Viral, Genome, Hot Springs, B129, Sulfolobus, Disulfide, Open Reading Frames, Viral Proteins, chemistry.chemical_compound, Protein structure, F93, Virology, Cysteine, Disulfides, Gene, Thermostable, Helix-Turn-Helix Motifs, Sulfolobus spindle-shaped virus, Genetics, biology, F112, SSV, Crenarchaea, biology.organism_classification, B116, Archaea, Protein tertiary structure, Crenarchaeal virus, chemistry, Biochemistry, Intramolecular disulfide, Intracellular disulfide, Thermostability, SSV1, Water Microbiology, Sulfolobales, DNA

Abstract

Fuselloviridae are ubiquitous crenarchaeal viruses found in high-temperature acidic hot springs worldwide. The type virus, Sulfolobus spindle-shaped virus 1 (SSV1), has a double-stranded DNA genome that contains 34 open reading frames (ORFs). Fuselloviral genomes show little similarity to other organisms, generally precluding functional predictions. However, tertiary protein structure can provide insight into protein function. We have thus undertaken a systematic investigation of the SSV1 proteome and report here on the F112 gene product. Biochemical, proteomic and structural studies reveal a monomeric intracellular protein that adopts a winged helix DNA binding fold. Notably, the structure contains an intrachain disulfide bond, prompting analysis of cysteine usage in this and other hyperthermophilic viral genomes. The analysis supports a general abundance of disulfide bonds in the intracellular proteins of hyperthermophilic viruses, and reveals decreased cysteine content in the membrane proteins of hyperthermophilic viruses infecting Sulfolobales. The evolutionary implications of the SSV1 distribution are discussed.

Published

2008

2. Core Residue Replacements Cause Coiled-Coil Orientation Switching in Vitro and in Vivo: Structure−Function Correlations for Osmosensory Transporter ProP

Author

Elisabeth Becker, Robert A. B. Keates, Janet M. Wood, Michelle N. Smith, Stanley C. Kwok, Chad Gill, Yonit Tsatskis, and Robert S. Hodges

Subjects

Models, Molecular, Circular dichroism, Stereochemistry, Blotting, Western, Molecular Sequence Data, Plasma protein binding, Antiparallel (biochemistry), Models, Biological, Biochemistry, Protein Structure, Secondary, Structure-Activity Relationship, Protein structure, Osmotic pressure, Amino Acid Sequence, Peptide sequence, chemistry.chemical_classification, Coiled coil, Sequence Homology, Amino Acid, Symporters, Circular Dichroism, Escherichia coli Proteins, Osmolar Concentration, Protein Structure, Tertiary, Amino acid, chemistry, Agrobacterium tumefaciens, Mutation, Mutagenesis, Site-Directed, Mutant Proteins, Peptides, Dimerization, Hydrophobic and Hydrophilic Interactions, Protein Binding

Abstract

Protein ProP acts as an osmosensory transporter in diverse bacteria. C-Terminal residues 468-497 of Escherichia coli ProP (ProPEc) form a four-heptad homodimeric alpha-helical coiled coil. Arg 488, at a core heptad a position, causes it to assume an antiparallel orientation. Arg in the hydrophobic core of coiled coils is destabilizing, but Arg 488 forms stabilizing interstrand salt bridges with Asp 475 and Asp 478. Mutation R488I destabilizes the coiled coil and elevates the osmotic pressure at which ProPEc activates. It may switch the coiled-coil orientation to parallel by eliminating the salt bridges and increasing the hydrophobicity of the core. In this study, mutations D475A and D478A, which disrupt the salt bridges without increasing the hydrophobicity of the coiled-coil core, had the expected modest impacts on the osmotic activation of ProPEc. The five-heptad coiled coil of Agrobacterium tumefaciens ProP (ProPAt) has K498 and R505 at a positions. Mutation K498I had little effect on the osmotic activation of ProPAt, and ProPAt-R505I was activated only at high osmotic pressure; on the other hand, the double mutant was refractory to osmotic activation. Both a synthetic peptide corresponding to ProPAt residues 478-516 and its K498I variant maintained the antiparallel orientation. The single R505I substitution created an unstable coiled coil with little orientation preference. Double mutation K498I/R505I switched the alignment, creating a stable parallel coiled coil. In vivo cross-linking showed that the C-termini of ProPAt and ProPAt-K498I/R505I were antiparallel and parallel, respectively. Thus, the antiparallel orientation of the ProP coiled coil is contingent on Arg in the hydrophobic core and interchain salt bridges. Two key amino acid replacements can convert it to a stable parallel structure, in vitro and in vivo. An intermolecular antiparallel coiled coil, present on only some orthologues, lowers the osmotic pressure required to activate ProP. Formation of a parallel coiled coil renders ProP inactive.

Published

2007

3. Stabilizing and Destabilizing Clusters in the Hydrophobic Core of Long Two-stranded α-Helical Coiled-coils

Author

Stanley C. Kwok and Robert S. Hodges

Subjects

Models, Molecular, Circular dichroism, Stereochemistry, Chemistry, Circular Dichroism, Molecular Sequence Data, Kinetics, Proteins, Sequence (biology), Tropomyosin, Cell Biology, Myosins, Biochemistry, Protein Structure, Secondary, Core (optical fiber), Protein structure, Drug Stability, Cluster (physics), Thermodynamics, Amino Acid Sequence, Peptides, Molecular Biology, Peptide sequence

Abstract

Detailed sequence analyses of the hydrophobic core residues of two long two-stranded alpha-helical coiled-coils that differ dramatically in sequence, function, and length were performed (tropomyosin of 284 residues and the coiled-coil domain of the myosin rod of 1086 residues). Three types of regions were present in the hydrophobic core of both proteins: stabilizing clusters and destabilizing clusters, defined as three or more consecutive core residues of either stabilizing (Leu, Ile, Val, Met, Phe, and Tyr) or destabilizing (Gly, Ala, Cys, Ser, Thr, Asn, Gln, Asp, Glu, His, Arg, Lys, and Trp) residues, and intervening regions that consist of both stabilizing and destabilizing residues in the hydrophobic core but no clusters. Subsequently, we designed a series of two-stranded coiled-coils to determine what defines a destabilizing cluster and varied the length of the destabilizing cluster from 3 to 7 residues to determine the length effect of the destabilizing cluster on protein stability. The results showed a dramatic destabilization, caused by a single Leu to Ala substitution, on formation of a 3-residue destabilizing cluster (DeltaT(m) of 17-21 degrees C) regardless of the stability of the coiled-coil. Any further substitution of Leu to Ala that increased the size of the destabilizing cluster to 5 or 7 hydrophobic core residues in length had little effect on stability (DeltaT(m) of 1.4-2.8 degrees C). These results suggested that the contribution of Leu to protein stability is context-dependent on whether the hydrophobe is in a stabilizing cluster or its proximity to neighboring destabilizing and stabilizing clusters.

Published

2004

4. Structural cassette mutagenesis in a de novo designed protein: Proof of a novel concept for examining protein folding and stability

Author

Pierre Lavigne, Jeff H. Man, Mundeep S. Chana, Stanley C. Kwok, Colin T. Mant, Robert S. Hodges, and Brian Tripet

Subjects

Coiled coil, chemistry.chemical_classification, Stereochemistry, Organic Chemistry, Biophysics, General Medicine, Immunoglobulin domain, Biochemistry, Cassette mutagenesis, Amino acid, Biomaterials, chemistry, Denaturation (biochemistry), Protein folding, Protein secondary structure, Peptide sequence

Abstract

The solution to the protein folding problem lies in defining the relative energetic contributions of short-range and long-range interactions. In other words, the tendency of a stretch of amino acids to adopt a final secondary structural fold is context dependent. Our approach to this problem is to address whether an amino acid sequence, a “cassette,” with a defined secondary structure in the three-dimensional structure of a native protein, can adopt a different conformation when placed into a different protein environment. Thus, we designed de novo a disulfide-bridged two-stranded α-helical parallel coiled coil, where each polypeptide chain consisted of 39 residues, as a “cassette holder.” The 11-residue cassette would be inserted into the center of each polypeptide chain between the two nucleating α-helices to replace the control sequence. This Structural Cassette Mutagenesis model permits the analysis of short-range interactions within the inserted cassette as well as long-range interactions between the nucleating helices and the cassette region. The cassette holder, with a control sequence as the cassette, had a GdnHCl transition midpoint during denaturation of 5.6M. To demonstrate the feasibility of our model, an 11-residue β-strand cassette from an immunoglobulin fold was inserted. The cassette was fully induced into the α-helical conformation with a [GdnHCl]1/2 value of 3.2M. To demonstrate the importance of short-range interactions (β-sheet/α-helical propensities of amino acid side chains) in modulating structure and stability, a series of 1–5 threonine residues (highest β-sheet propensity) were substituted into the solvent-exposed portions of the cassette in the α-helical conformation. Each successive substitution systematically decreased the stability of the coiled coil with peptide T4b (4 Thr residues) having a [GdnHCl]1/2 value of 2.2M. The single substitution of Ile in the hydrophobic core of the cassette with Ala or Thr had the most dramatic effect on protein stability (peptide I20T, [GdnHCl]1/2 value of 1.4M). Though these substitutions were able to modulate stability, they were not able to disrupt the α-helical conformation of the cassette, showing the importance of the nucleating α-helices on either side of the cassette in controlling conformation of the cassette. We have demonstrated the feasibility of our model protein to accept a β-strand cassette. The effect of cassettes containing other β-strands, β-turns, loops, regions of undefined structure, and helical segments on conformation and stability of our model protein will also be determined. © 1998 John Wiley & Sons, Inc. Biopoly 47: 101–123, 1998

Published

1998

5. Identification of a Unique Stability Propagation Site that Controls Protein Stability of α-Tropomyosin: a Two-Stranded α-Helical Coiled-coil

Author

Stanley C. Kwok, Lawrence B. Smillie, Robert S. Hodges, and Janine B. Mills

Subjects

Coiled coil, Electrostatic attraction, Protein stability, Chemistry, α helical, Myosin, Biophysics, Native protein, α tropomyosin, Electrostatic interaction

Published

2010

6. High Concentration Formulations of Recombinant Human Interleukin-1 Receptor Antagonist: I. Physical Characterization

Author

Stanley C. Kwok, Jennifer N. Roberts, John F. Carpenter, Deborah S. Wuttke, Brent S. Kendrick, Theodore W. Randolph, and John R. Alford

Subjects

Light, Chemistry, Osmolar Concentration, Analytical chemistry, Pharmaceutical Science, Isothermal titration calorimetry, Calorimetry, Hydrogen-Ion Concentration, Article, Recombinant Proteins, Dissociation constant, Interleukin 1 Receptor Antagonist Protein, Virial coefficient, Osmometer, Ionic strength, Sedimentation equilibrium, Humans, Scattering, Radiation, Osmotic coefficient, Static light scattering, Nuclear Magnetic Resonance, Biomolecular

Abstract

At relatively high protein concentrations (i.e., up to 100 mg/mL), recombinant human interleukin-1 receptor antagonist (rhIL-1ra) was found to exist in a monomer-dimer equilibrium controlled by solution ionic strength. Sedimentation equilibrium at 25 degrees C was used to measure the increase in the dimer dissociation constant (K(d)) as a function of ionic strength. K(d) increased from 2.0 to 12.6 mM as the solution ionic strength was increased from 0.011 to 0.184 molal. These K(d) values were used with both static light scattering and membrane osmometry data collected over a protein concentration range of 1-100 mg/mL to determine second osmotic virial coefficients. Expanding the second osmotic virial coefficient model to account for separate monomer-monomer (B(22)), monomer-dimer (B(23)), and dimer-dimer (B(33)) interactions reveals net monomer-dimer interactions are attractive, whereas the others are repulsive. Lastly, isothermal titration calorimetry dilution experiments showed that rhIL-1ra dimerization is enthalpically driven (DeltaH(dimerization) << 0), which is consistent with intermolecular cation-pi interactions previously proposed as the monomer-monomer contact sites in dimers.

Published

2008

7. Quantitation of the Nearest-neighbour Effects of Amino Acid Side-Chains that Restrict Conformational Freedom of the Polypeptide Chain using Reversed-Phase Liquid Chromatography of Synthetic Model Peptides with L- and D-amino Acid Substitutions

Author

Stanley C. Kwok, Robert S. Hodges, David Osguthorpe, Colin T. Mant, and James M. Kovacs

Subjects

chemistry.chemical_classification, Models, Molecular, Chromatography, Molecular model, Stereochemistry, Protein Conformation, Circular Dichroism, Organic Chemistry, Peptide, Stereoisomerism, General Medicine, Biochemistry, Article, Analytical Chemistry, Amino acid, Residue (chemistry), Protein structure, chemistry, Side chain, Protein folding, Amino Acids, Peptide sequence, Hydrophobic and Hydrophilic Interactions, Oligopeptides, Chromatography, High Pressure Liquid

Abstract

Side-chain backbone interactions (or “effects”) between nearest neighbours may severely restrict the conformations accessible to a polypeptide chain and thus represent the first step in protein folding. We have quantified nearest-neighbour effects (i to i + 1) in peptides through reversed-phase liquid chromatography (RP-HPLC) of model synthetic peptides, where L- and D- amino acids were substituted at the N-terminal end of the peptide sequence, adjacent to a L-Leu residue. These nearest-neighbour effects (expressed as the difference in retention times of L- and D- peptide diastereomers at pH 2 and pH 7) were frequently dramatic, depending on the type of side-chain adjacent to the L-Leu residue, albeit such effects were independent of mobile phase conditions. No nearest-neighbour effects were observed when residue i is adjacent to a Gly residue. Calculation of minimum energy conformations of selected peptides supported the view that, whether a L- or D- amino acid is substituted adjacent to L-Leu, its orientation relative to this bulky Leu side-chain represents the most energetically favourable configuration. We believe that such energetically favourable, and different, configurations of L- and D- peptide diastereomers affect their respective interactions with a hydrophobic stationary phase, which are thus quantified by different RP-HPLC retention times. Side-chain hydrophilicity/hydrophobicity coefficients were generated in the presence of these nearest-neighbour effects and, despite the relative difference in such coefficients generated from peptides substituted with L- or D- amino acids, the relative difference in hydrophilicity/hydrophobicity between different amino acids in the L- or D- series is maintained. Overall, our results demonstrate that such nearest-neighbour effects can clearly restrict conformational space of an amino acid side-chain in a polypeptide chain.

Published

2006

8. Importance of secondary structure specificity determinants in protein folding and stability

Author

Colin T. Mant, Stanley C. Kwok, and Robert S. Hodges

Subjects

chemistry.chemical_classification, Fold (higher-order function), Chemistry, Stereochemistry, Sequence (biology), Protein folding, Context (language use), Immunoglobulin domain, Protein secondary structure, Host protein, Amino acid

Abstract

Short stretches of amino acids, the building blocks of secondary structure, have been shown to fold differently when placed in different protein environments because of competing shortand long-range interactions [1,2]. Interchanging two residues in a short secondary structural element can cause a conformational shift from to [3]. Therefore, the solution to the protein folding problem lies in defining the relative energetic contributions of shortand long-range interactions. In other words, the tendency of a stretch of amino acids to adopt a final secondary structure is context dependent. The question arises whether there are "secondary structure specificity (SSS) determinants" that prevent a certain sequence from adopting an alternate secondary structure. We have previously shown that an 11-residue segment (a cassette) of an immunoglobulin fold can be converted to an structure when inserted into a coiled-coil host protein (cassette holder) (Fig. 1) [4]. This study involves the insertion of a cassette, which prevents the host protein from adopting the coiled-coil structure. By rational elimination of the SSS determinants in th cassette through amino acid substitutions, we were able to convert the essentially unfolded structure back to an helical coiled-coil. In addition, we were able to leave one SSS determinant in the cassette sequence and override its effect by increasing the overall propensity of the segment and the hydrophobicity of the protein core.

Published

2006

9. Effect of chain length on coiled-coil stability: decreasing stability with increasing chain length

Author

Stanley C. Kwok and Robert S. Hodges

Subjects

Thermal denaturation, Coiled coil, Circular dichroism, Protein Denaturation, Chemistry, Organic Chemistry, Biophysics, Temperature, Ionic bonding, Proteins, General Medicine, Biochemistry, Protein Structure, Secondary, Biomaterials, Crystallography, Chain length, Heptad repeat, Protein structure, Urea, Protein folding, Peptides

Abstract

The de novo design and biophysical characterization of three series of two-stranded alpha-helical coiled coils with different chain lengths are described. Our goal was to examine how increasing chain length would affect protein folding and stability when one or more heptad repeat(s) of K-A-E-A-L-E-G (gabcdef) was inserted into the central region of different coiled-coil host proteins. This heptad was designed to maintain the continuous 3-4 hydrophobic repeat of the coiled-coil host and introduce an Ala and Leu residue in the hydrophobic core at the a and d position, respectively, and a pair of stabilizing interchain ionic i to i' + 5 (g to e') interactions per heptad inserted. The secondary structures of the three series of disulfide-bridged polypeptides were studied by CD spectroscopy and their stabilities determined by chemical and thermal denaturation. The results showed that successive insertions of this heptad systematically decreased the stability of all the coiled coils studied regardless of the overall initial stability of the host coiled coil. These observations are in contrast to the generally accepted implication that the folding and stability of coiled coils are enhanced with increasing chain length. Our results imply that, in these examples where an Ala and Leu hydrophobic residue were introduced into the coiled-coil core per inserted heptad, there was still insufficient stability to overcome unfavorable entropy associated with chain length extension, even though the inserted heptad contained the most stabilizing hydrophobic residue (Leu) at position d and stabilizing ionic attractions.

Published

2004

10. Clustering of large hydrophobes in the hydrophobic core of two-stranded alpha-helical coiled-coils controls protein folding and stability

Author

Stanley C. Kwok and Robert S. Hodges

Subjects

Circular dichroism, Protein Folding, Calorimetry, Differential Scanning, Chemistry, Enthalpy, Molecular Sequence Data, Proteins, Cell Biology, Calorimetry, Biochemistry, Protein Structure, Secondary, Crystallography, Chaotropic agent, Differential scanning calorimetry, Drug Stability, Lattice protein, Thermodynamics, Protein folding, Amino Acid Sequence, Disulfides, Hydrophobic collapse, Peptides, Molecular Biology

Abstract

The de novo design and biophysical characterization of two 60-residue peptides that dimerize to fold as parallel coiled-coils with different hydrophobic core clustering is described. Our goal was to investigate whether designing coiled-coils with identical hydrophobicity but with different hydrophobic clustering of non-polar core residues (each contained 6 Leu, 3 Ile, and 7 Ala residues in the hydrophobic core) would affect helical content and protein stability. The disulfide-bridged P3 and P2 differed dramatically in alpha-helical structure in benign conditions. P3 with three hydrophobic clusters was 98% alpha-helical, whereas P2 was only 65% alpha-helical. The stability profiles of these two analogs were compared, and the enthalpy and heat capacity changes upon denaturation were determined by measuring the temperature dependence by circular dichroism spectroscopy and confirmed by differential scanning calorimetry. The results showed that P3 assembled into a stable alpha-helical two-stranded coiled-coil and exhibited a native protein-like cooperative two-state transition in thermal melting, chemical denaturation, and calorimetry experiments. Although both peptides have identical inherent hydrophobicity (the hydrophobic burial of identical non-polar residues in equivalent heptad coiled-coil positions), we found that the context dependence of an additional hydrophobic cluster dramatically increased stability of P3 (Delta Tm approximately equal to 18 degrees C and Delta[urea](1/2) approximately equal to 1.5 M) as compared with P2. These results suggested that hydrophobic clustering significantly stabilized the coiled-coil structure and may explain how long fibrous proteins like tropomyosin maintain chain integrity while accommodating polar or charged residues in regions of the protein hydrophobic core.

Published

2003