Your search keyword '"Byung-Ha Oh"' showing total 22 results

1. Structural basis of inactivation of Ras and Rap1 small GTPases by Ras/Rap1-specific endopeptidase from the sepsis-causing pathogen Vibrio vulnificus

Author

Byung-Ha Oh, Byoung Sik Kim, Eun-Young Lee, Song Yee Jang, Jungwon Hwang, and Myung Hee Kim

Subjects

0301 basic medicine, bacterial pathogenesis, Host–pathogen interaction, Bacterial Toxins, GTPase, Ras/Rap1-specific endopeptidase, virulence factor, Biochemistry, Virulence factor, sepsis, Proto-Oncogene Proteins p21(ras), 03 medical and health sciences, Bacterial Proteins, Protein Domains, Endopeptidases, Humans, toxin, Vibrio vulnificus, Molecular Biology, Innate immune system, Effector, Chemistry, rap1 GTP-Binding Proteins, Cell Biology, Endopeptidase, Cell biology, MARTX toxin, effector, HEK293 Cells, 030104 developmental biology, Cytoplasm, Protein Structure and Folding, Host-Pathogen Interactions, Rap1, host–pathogen interaction

Abstract

Multifunctional autoprocessing repeats-in-toxin (MARTX) toxins are secreted by Gram-negative bacteria and function as primary virulence-promoting macromolecules that deliver multiple cytopathic and cytotoxic effector domains into the host cytoplasm. Among these effectors, Ras/Rap1-specific endopeptidase (RRSP) catalyzes the sequence-specific cleavage of the Switch I region of the cellular substrates Ras and Rap1 that are crucial for host innate immune defenses during infection. To dissect the molecular basis underpinning RRSP-mediated substrate inactivation, we determined the crystal structure of an RRSP from the sepsis-causing bacterial pathogen Vibrio vulnificus (VvRRSP). Structural and biochemical analyses revealed that VvRRSP is a metal-independent TIKI family endopeptidase composed of an N-terminal membrane-localization and substrate-recruitment domain (N lobe) connected via an inter-lobe linker to the C-terminal active site–coordinating core β-sheet–containing domain (C lobe). Structure-based mutagenesis identified the 2His/2Glu catalytic residues in the core catalytic domain that are shared with other TIKI family enzymes and that are essential for Ras processing. In vitro KRas cleavage assays disclosed that deleting the N lobe in VvRRSP causes complete loss of enzymatic activity. Endogenous Ras cleavage assays combined with confocal microscopy analysis of HEK293T cells indicated that the N lobe functions both in membrane localization via the first α-helix and in substrate assimilation by altering the functional conformation of the C lobe to facilitate recruitment of cellular substrates. Collectively, these results indicate that RRSP is a critical virulence factor that robustly inactivates Ras and Rap1 and augments the pathogenicity of invading bacteria via the combined effects of its N and C lobes.

Published

2018

2. Phosphoinositides Differentially Regulate Protrudin Localization through the FYVE Domain

Author

Wei Sun Park, Wonhwa Cho, Eui Kim, Bonsu Ku, Jung Eun Gil, Il Shin Kim, Byung-Ha Oh, Won Do Heo, and Sung Ho Ryu

Subjects

Models, Molecular, Protein Conformation, Endosome, Molecular Sequence Data, Phosphatidylinositol Phosphates, Vesicular Transport Proteins, Endosomes, Biology, Phosphatidylinositols, Models, Biological, Biochemistry, EEA1, Cell membrane, Mice, chemistry.chemical_compound, Membrane Biology, Neurites, medicine, Animals, Amino Acid Sequence, Phosphatidylinositol, Molecular Biology, Cellular localization, Sequence Homology, Amino Acid, Phosphatidylinositol 3-phosphate, Cell Membrane, Cell Biology, Surface Plasmon Resonance, Lipids, Protein Structure, Tertiary, Cell biology, Kinetics, medicine.anatomical_structure, chemistry, Mutation, FYVE domain, NIH 3T3 Cells, Carrier Proteins

Abstract

Protrudin is a FYVE (Fab 1, YOTB, Vac 1, and EEA1) domain-containing protein involved in transport of neuronal cargoes and implicated in the onset of hereditary spastic paraplegia. Our image-based screening of the lipid binding domain library revealed novel plasma membrane localization of the FYVE domain of protrudin unlike canonical FYVE domains that are localized to early endosomes. The membrane binding study by surface plasmon resonance analysis showed that this FYVE domain preferentially binds phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P(2)), phosphatidylinositol 3,4-bisphosphate (PtdIns(3,4)P(2)), and phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P(3)) unlike canonical FYVE domains that specifically bind phosphatidylinositol 3-phosphate (PtdIns(3)P). Furthermore, we found that these phosphoinositides (PtdInsP) differentially regulate shuttling of protrudin between endosomes and plasma membrane via its FYVE domain. Protrudin mutants with reduced PtdInsP-binding affinity failed to promote neurite outgrowth in primary cultured hippocampal neurons. These results suggest that novel PtdInsP selectivity of the protrudin-FYVE domain is critical for its cellular localization and its role in neurite outgrowth.

Published

2012

3. Association of Novel Domain in Active Site of Archaic Hyperthermophilic Maltogenic Amylase from Staphylothermus marinus

Author

Phuong Lan Tran, Byung-Ha Oh, Kwan-Hwa Park, Sung Goo Park, Dan Li, Jong-Tae Park, Eui-Jeon Woo, Se-Mi Yoon, Tae-Yang Jung, and Štefan Janeček

Subjects

Binding Sites, Bacteria, Glycoside Hydrolases, Desulfurococcaceae, Archaeal Proteins, Hydrolysis, Thermophile, Oligosaccharides, Active site, Cell Biology, Biology, biology.organism_classification, Biochemistry, Hyperthermophile, Structure-Activity Relationship, Bacterial Proteins, Protein Structure and Folding, Hydrolase, biology.protein, Pyrococcus furiosus, Glycoside hydrolase, Amylase, Molecular Biology

Abstract

Staphylothermus marinus maltogenic amylase (SMMA) is a novel extreme thermophile maltogenic amylase with an optimal temperature of 100 °C, which hydrolyzes α-(1-4)-glycosyl linkages in cyclodextrins and in linear malto-oligosaccharides. This enzyme has a long N-terminal extension that is conserved among archaic hyperthermophilic amylases but is not found in other hydrolyzing enzymes from the glycoside hydrolase 13 family. The SMMA crystal structure revealed that the N-terminal extension forms an N' domain that is similar to carbohydrate-binding module 48, with the strand-loop-strand region forming a part of the substrate binding pocket with several aromatic residues, including Phe-95, Phe-96, and Tyr-99. A structural comparison with conventional cyclodextrin-hydrolyzing enzymes revealed a striking resemblance between the SMMA N' domain position and the dimeric N domain position in bacterial enzymes. This result suggests that extremophilic archaea that live at high temperatures may have adopted a novel domain arrangement that combines all of the substrate binding components within a monomeric subunit. The SMMA structure provides a molecular basis for the functional properties that are unique to hyperthermophile maltogenic amylases from archaea and that distinguish SMMA from moderate thermophilic or mesophilic bacterial enzymes.

Published

2012

4. Arg-158 Is Critical in Both Binding the Substrate and Stabilizing the Transition-state Oxyanion for the Enzymatic Reaction of Malonamidase E2

Author

Kwan Yong Choi, Sejeong Shin, Byung-Ha Oh, Wook Lee, and Young Sung Yun

Subjects

Anions, Stereochemistry, Molecular Sequence Data, Oxyanion, Arginine, Crystallography, X-Ray, Biochemistry, Catalysis, Amidohydrolases, Substrate Specificity, chemistry.chemical_compound, Bacterial Proteins, Enzyme Stability, Catalytic triad, Amino Acid Sequence, Bradyrhizobium, Carboxylate, Molecular Biology, chemistry.chemical_classification, Binding Sites, biology, Chemistry, Wild type, Active site, Substrate (chemistry), Cell Biology, Enzyme, Malonate, Mutagenesis, Site-Directed, biology.protein, Protein Binding

Abstract

Malonamidase E2 (MAE2) from Bradyrhizobium japonicum is an enzyme that hydrolyzes malonamate to malonate and has a Ser-cis-Ser-Lys catalytic triad at the active site. The crystal structures of wild type and mutant MAE2 exhibited that the guanido group of Arg-158 could be involved in the binding of malonamate in which the negative charge of the carboxyl group could destabilize a negatively charged transition-state oxyanion in the enzymatic reaction. In an attempt to elucidate the specific roles of Arg-158, site-directed mutants, R158Q, R158E, and R158K, were prepared (see Table 1). The crystal structure of R158Q determined at 2.2 Angstrom resolution showed that the guanido group of Arg-158 was important for the substrate binding with the marginal structural change upon the mutation. The k(cat) value of R158Q significantly decreased by over 1500-fold and the catalytic activity of R158E could not be detected. The k(cat) value of R158K was similar to that of the wild type with the K(m) value drastically increased by 100-fold, suggesting that Lys-158 of R158K can stabilize the negative charge of the carboxylate in the substrate to some extent and contribute to the stabilization of the transition-state oxyanion, but a single amine group of Lys-158 in R158K could not precisely anchor the carboxyl group of malonamate compared with the guanido group of Arg-158. Our kinetic and structural evidences demonstrate that Arg-158 in MAE2 should be critical to both binding the substrate and stabilizing the transition-state oxyanion for the catalytic reaction of MAE2.

Published

2006

5. Crystal Structures of RbsD Leading to the Identification of Cytoplasmic Sugar-binding Proteins with a Novel Folding Architecture

Author

Min Sung Kim, Weontae Lee, Byung-Ha Oh, Joon Shin, and Heung-Soo Lee

Subjects

Glycerol, Models, Molecular, Cytoplasm, Protein Folding, Magnetic Resonance Spectroscopy, Monosaccharide Transport Proteins, Operon, Ribose, Molecular Sequence Data, Bacillus subtilis, Calorimetry, Crystallography, X-Ray, Polymerase Chain Reaction, Biochemistry, Protein Structure, Secondary, chemistry.chemical_compound, Escherichia coli, Amino Acid Sequence, Molecular Biology, Gene, Fucose, Binding Sites, Sequence Homology, Amino Acid, biology, Cell Biology, biology.organism_classification, Folding (chemistry), Regulon, chemistry, Function (biology), Protein Binding

Abstract

RbsD is the only protein whose biochemical function is unknown among the six gene products of the rbs operon involved in the active transport of ribose. FucU, a paralogue of RbsD conserved from bacteria to human, is also the only protein whose function is unknown among the seven gene products of the l-fucose regulon. Here we report the crystal structures of Bacillus subtilis RbsD, which reveals a novel decameric toroidal assembly of the protein. Nuclear magnetic resonance and other studies on RbsD reveal that the intersubunit cleft of the protein binds specific forms of d-ribose, but it does not have an enzyme activity toward the sugar. Likewise, FucU binds l-fucose but lacks an enzyme activity toward this sugar. We conclude that RbsD and FucU are cytoplasmic sugar-binding proteins, a novel class of proteins whose functional role may lie in helping influx of the sugar substrates.

Published

2003

6. Characterization of a Novel Ser-cisSer-Lys Catalytic Triad in Comparison with the Classical Ser-His-Asp Triad

Author

Byung-Ha Oh, Young Sung Yun, Hyun Min Koo, Yu Sam Kim, Kwan Yong Choi, and Sejeong Shin

Subjects

Stereochemistry, Molecular Sequence Data, Biochemistry, Amidohydrolases, Substrate Specificity, Amidase, Structure-Activity Relationship, Residue (chemistry), Bacterial Proteins, Catalytic Domain, Catalytic triad, Animals, Humans, Peptide bond, Amino Acid Sequence, Molecular Biology, Histidine, Alanine, biology, Chemistry, Active site, Cell Biology, Mutation, Mutagenesis, Site-Directed, biology.protein, Sequence Alignment, Cysteine

Abstract

Amidase signature family enzymes, which are widespread in nature, contain a newly identified Ser-cisSer-Lys catalytic triad in which the peptide bond between Ser131 and the preceding residue Gly130 is in a cis configuration. In order to characterize the property of the novel triad, we have determined the structures of five mutant malonamidase E2 enzymes that contain a Cys-cisSer-Lys, Ser-cisAla-Lys, or Ser-cisSer-Ala triad or a substitution of Gly130 with alanine. Cysteine cannot replace the role of Ser155 due to a hyper-reactivity of the residue, which results in the modification of the cysteine to cysteinyl sulfinic acid, most likely inside the expression host cells. The lysine residue plays a structural as well as a catalytic role, since the substitution of the residue with alanine disrupts the active site structure completely. The two observations are in sharp contrast with the consequences of the corresponding substitutions in the classical Ser-His-Asp triad. Structural data on the mutant containing the Ser-cisAla-Lys triad convincingly suggest that Ser131 plays an analogous catalytic role as the histidine of the Ser-His-Asp triad. The unusual cis configuration of Ser131 appears essential for the precise contacts of this residue with the other triad residues, as indicated by the near invariance of the preceding glycine residue (Gly130), structural data on the G130A mutant, and by a modeling experiment. The data provide a deep understanding of the role of each residue of the new triad at the atomic level and demonstrate that the new triad is a catalytic device distinctively different from the classical triad or its variants.

Published

2003

7. Crystal Structure of SEDL and Its Implications for a Genetic Disease Spondyloepiphyseal Dysplasia Tarda

Author

Se Bok Jang, Kyung-Hwa Kim, Pann-Ghill Suh, Yeon-Gil Kim, Yong-Soon Cho, and Byung-Ha Oh

Subjects

Models, Molecular, X Chromosome, Genetic Linkage, Molecular Sequence Data, Mutation, Missense, Golgi Apparatus, Crystallography, X-Ray, Osteochondrodysplasias, medicine.disease_cause, Biochemistry, Protein Structure, Secondary, R-SNARE Proteins, Mice, Skeletal disorder, Escherichia coli, medicine, Animals, Humans, Point Mutation, Missense mutation, Amino Acid Sequence, Molecular Biology, Gene, Genetics, Mutation, Sequence Homology, Amino Acid, biology, Point mutation, Endoplasmic reticulum, Membrane Proteins, Membrane Transport Proteins, Cell Biology, Protein Structure, Tertiary, Vesicular transport protein, TRAPP complex, biology.protein, Carrier Proteins, Gene Deletion, Protein Binding, Transcription Factors

Abstract

SEDL is an evolutionarily highly conserved protein in eukaryotic organisms. Deletions or point mutations in the SEDL gene are responsible for the genetic disease spondyloepiphyseal dysplasia tarda (SEDT), an X-linked skeletal disorder. SEDL has been identified as a component of the transport protein particle (TRAPP), critically involved in endoplasmic reticulum-to-Golgi vesicle transport. Herein, we report the 2.4 A resolution structure of SEDL, which reveals an unexpected similarity to the structures of the N-terminal regulatory domain of two SNAREs, Ykt6p and Sec22b, despite no sequence homology to these proteins. The similarity and the presence of unusually many solvent-exposed apolar residues of SEDL suggest that it serves regulatory and/or adaptor functions through multiple protein-protein interactions. Of the four known missense mutations responsible for SEDT, three mutations (S73L, F83S, V130D) map to the protein interior, where the mutations would disrupt the structure, and the fourth (D47Y) on a surface at which the mutation may abrogate functional interactions with a partner protein.

Published

2002

8. Cyclomaltodextrinase, Neopullulanase, and Maltogenic Amylase Are Nearly Indistinguishable from Each Other

Author

Tae Jip Kim, Heung-Soo Lee, Byung-Ha Oh, Min Sung Kim, Hee Seob Lee, Hyun Soo Cho, Jihye Choi, Cheon-Seok Park, Kwan Hwa Park, and Jung In Kim

Subjects

Models, Molecular, Time Factors, Glycoside Hydrolases, Protein Conformation, Stereochemistry, Phenylalanine, Molecular Sequence Data, Bacillus, Biology, Crystallography, X-Ray, Biochemistry, Catalysis, Substrate Specificity, Protein structure, Cyclomaltodextrinase, Dextrins, Hydrolase, Glycoside hydrolase, Amino Acid Sequence, Cloning, Molecular, Thermus, Molecular Biology, Peptide sequence, chemistry.chemical_classification, Binding Sites, Tryptophan, Cell Biology, Hydrogen-Ion Concentration, biology.organism_classification, Protein Structure, Tertiary, Kinetics, Enzyme, chemistry, Mutation, Dimerization, Protein Binding

Abstract

Over 20 enzymes denoted as cyclomaltodextrinase, maltogenic amylase, or neopullulanase that share 40-86% sequence identity with each other are found in public data bases. These enzymes are distinguished from typical alpha-amylases by containing a novel N-terminal domain and exhibiting preferential substrate specificities for cyclomaltodextrins (CDs) over starch. In this research field, a great deal of confusion exists regarding the features distinguishing the three groups of enzymes from one another. Although a different enzyme code has been assigned to each of the three different enzyme names, even a single differentiating enzymatic property has not been documented in the literature. On the other hand, an outstanding question related to this issue concerns the structural basis for the preference of these enzymes for CDs. To clarify the confusion and to address this question, we have determined the structures of two enzymes, one from alkalophilic Bacillus sp. I-5 and named cyclomaltodextrinase and the other from a Thermus species and named maltogenic amylase. The structure of the Bacillus enzyme reveals a dodecameric assembly composed of six copies of the dimer, which is the structural and functional unit of the Thermus enzyme and an enzyme named neopullulanase. The structure of the Thermus enzyme in complex with beta-CD led to the conclusion that Trp47, a well conserved N-terminal domain residue, contributes greatly to the preference for beta-CD. The common dimer formation through the novel N-terminal domain, which contributes to the preference for CDs by lining the active-site cavity, convincingly indicates that the three groups of enzymes are not different enough to preserve the different names and enzyme codes.

Published

2002

9. Crystal Structure of Δ5-3-Ketosteroid Isomerase from Pseudomonas testosteroni in Complex with Equilenin Settles the Correct Hydrogen Bonding Scheme for Transition State Stabilization

Author

Kwan Yong Choi, Gildon Choi, Donghan Lee, Kwang S. Kim, Hyun Kim, Kyung Seok Oh, Byung-Ha Oh, Weon Tae Lee, Nam-Chul Ha, and Hyun Soo Cho

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Stereochemistry, Low-barrier hydrogen bond, Steroid Isomerases, Isomerase, Reaction intermediate, Crystallography, X-Ray, Biochemistry, Enzyme catalysis, medicine, Comamonas testosteroni, Molecular Biology, Equilenin, Binding Sites, Molecular Structure, biology, Pseudomonas putida, Hydrogen bond, Chemistry, Active site, Hydrogen Bonding, Cell Biology, Mutation, biology.protein, Dimerization, Isomerization, Protein Binding, medicine.drug

Abstract

Delta(5)-3-Ketosteroid isomerase from Pseudomonas testosteroni has been intensively studied as a prototype to understand an enzyme-catalyzed allylic isomerization. Asp(38) (pK(a) approximately 4.7) was identified as the general base abstracting the steroid C4beta proton (pK(a) approximately 12.7) to form a dienolate intermediate. A key and common enigmatic issue involved in the proton abstraction is the question of how the energy required for the unfavorable proton transfer can be provided at the active site of the enzyme and/or how the thermodynamic barrier can be drastically reduced. Answering this question has been hindered by the existence of two differently proposed enzyme reaction mechanisms. The 2.26 A crystal structure of the enzyme in complex with a reaction intermediate analogue equilenin reveals clearly that both the Tyr(14) OH and Asp(99) COOH provide direct hydrogen bonds to the oxyanion of equilenin. The result negates the catalytic dyad mechanism in which Asp(99) donates the hydrogen bond to Tyr(14), which in turn is hydrogen bonded to the steroid. A theoretical calculation also favors the doubly hydrogen-bonded system over the dyad system. Proton nuclear magnetic resonance analyses of several mutant enzymes indicate that the Tyr(14) OH forms a low barrier hydrogen bond with the dienolic oxyanion of the intermediate.

Published

1999

10. Crystal Structure of RNA Helicase from Genotype 1b Hepatitis C Virus

Author

Byung-Ha Oh, Sung Hoon Back, Nam-Chul Ha, Sung Key Jang, Hyun Soo Cho, Kyung Min Chung, and Lin-Woo Kang

Subjects

Multiple isomorphous replacement, RNA, Helicase, Cell Biology, Biology, Biochemistry, RNA Helicase A, Crystallography, chemistry.chemical_compound, chemistry, Biophysics, biology.protein, Directionality, Molecular Biology, DNA, Single-Stranded RNA, Binding domain

Abstract

Crystal structure of RNA helicase domain from genotype 1b hepatitis C virus has been determined at 2.3 A resolution by the multiple isomorphous replacement method. The structure consists of three domains that form a Y-shaped molecule. One is a NTPase domain containing two highly conserved NTP binding motifs. Another is an RNA binding domain containing a conserved RNA binding motif. The third is a helical domain that contains no β-strand. The RNA binding domain of the molecule is distinctively separated from the other two domains forming an interdomain cleft into which single stranded RNA can be modeled. A channel is found between a pair of symmetry-related molecules which exhibit the most extensive crystal packing interactions. A stretch of single stranded RNA can be modeled with electrostatic complementarity into the interdomain cleft and continuously through the channel. These observations suggest that some form of this dimer is likely to be the functional form that unwinds double stranded RNA processively by passing one strand of RNA through the channel and passing the other strand outside of the dimer. A “descending molecular see-saw” model is proposed that is consistent with directionality of unwinding and other physicochemical properties of RNA helicases.

Published

1998

11. High Resolution Crystal Structure of a Human Tumor Necrosis Factor-α Mutant with Low Systemic Toxicity

Author

Woojin Jeong, Jong Boon Hahn, Jeong-Sun Kim, Nam Kyu Shin, Hang Cheol Shin, Hyun Soo Cho, Yeoun Jin Kim, Byung-Ha Oh, and Sun Shin Cha

Subjects

Models, Molecular, Conformational change, Hot Temperature, Cell Survival, Protein Conformation, Proteolysis, Mutant, Crystallography, X-Ray, medicine.disease_cause, Biochemistry, Mice, L Cells, In vivo, Tumor Cells, Cultured, medicine, Animals, Humans, Computer Simulation, Receptor, Molecular Biology, chemistry.chemical_classification, Mutation, medicine.diagnostic_test, Tumor Necrosis Factor-alpha, Chemistry, Cell Biology, Hydrogen-Ion Concentration, Trypsin, Amino acid, Mutagenesis, Dactinomycin, Biophysics, Half-Life, medicine.drug

Abstract

A human tumor necrosis factor-alpha (TNF-alpha) mutant (M3S) with low systemic toxicity in vivo was designed, and its structures in two different crystal packings were determined crystallographically at 1.8 and 2.15-A resolution, respectively, to explain altered biological activities of the mutant. M3S contains four changes: a hydrophilic substitution of L29S, two hydrophobic substitutions of S52I and Y56F, and a deletion of the N-terminal seven amino acids that is disordered in the structure of wild-type TNF-alpha. Compared with wild-type TNF-alpha, it exhibits 11- and 71-fold lower binding affinities for the human TNF-R55 and TNF-R75 receptors, respectively, and in vitro cytotoxic effect and in vivo systemic toxicity of M3S are 20 and 10 times lower, respectively. However, in a transplanted solid tumor mouse model, M3S suppresses tumor growth more efficiently than wild-type TNF-alpha. M3S is highly resistant to proteolysis by trypsin, and it exhibits increased thermal stability and a prolonged half-life in vivo. The L29S mutation causes substantial restructuring of the loop containing residues 29-36 into a rigid segment as a consequence of induced formation of intra- and intersubunit interactions, explaining the altered receptor binding affinity and thermal stability. A mass spectrometric analysis identified major proteolytic cleavage sites located on this loop, and thus the increased resistance of M3S to the proteolysis is consistent with the increased rigidity of the loop. The S52I and Y56F mutations do not induce a noticeable conformational change. The side chain of Phe56 projects into a hydrophobic cavity, while Ile52 is exposed to the bulk solvent. Ile52 should be involved in hydrophobic interactions with the receptors, since a mutant containing the same mutations as in M3S except for the L29S mutation exhibits an increased receptor binding affinity. The low systemic toxicity of M3S appears to be the effect of the reduced and selective binding affinities for the TNF receptors, and the superior tumor-suppression of M3S appears to be the effect of its weak but longer antitumoral activity in vivo compared with wild-type TNF-alpha. It is also expected that the 1.8-A resolution structure will serve as an accurate model for explaining the structure-function relationship of wild-type TNF-alpha and many TNF-alpha mutants reported previously and for the design of new TNF-alpha mutants.

Published

1998

12. Structure/Function Analysis of the Periplasmic Histidine-binding Protein

Author

Hendrik De Bondt, Anil K. Joshi, Giovanna Ferro-Luzzi Ames, Amnon Wolf, Byung-Ha Oh, and Eudean W. Shaw

Subjects

Conformational change, Chemistry, Permease, Stereochemistry, Mutant, Cell Biology, Periplasmic space, Receptor, Ligand (biochemistry), Molecular Biology, Biochemistry, Histidine, Transmembrane protein

Abstract

The periplasmic histidine-binding protein, HisJ, is a receptor for the histidine permease of Salmonella typhimurium. Receptors of this type are composed of two lobes that are far apart in the unliganded structure (open conformation) and drawn close together in the liganded structure (closed conformation). The binding of the ligand, in a cleft between the lobes, stabilizes the closed conformation. Such receptors have several functions in transport: interaction with the membrane-bound complex, transmission of a transmembrane signal to hydrolyze ATP, and receiving a signal to open the lobes and release the ligand. In this study the mechanism of action of HisJ was further investigated using mutant proteins defective in ligand binding activity and closed form-specific monoclonal antibodies (Wolf, A., Shaw, E. W., Nikaido, K., and Ames G. F.-L.(1994) J. Biol. Chem. 269, 23051-23058). Y14H is defective in stabilization of the closed form, does not assume the closed empty form, and assumes an altered closed liganded form. T121A and G119R are similar to Y14H, but assume a normal closed liganded form. S72P binds the ligand to the open form, but does not assume a recognizable closed form. S92F is defective in the ability to undergo conformational change and to stabilize the closed form. All other mutant proteins appear to fall within one of these four categories. The biochemical characterization of these mutant proteins agrees with the structural analysis of the protein. We suggest that mutant proteins that do not assume the normal closed form, in addition to their defect in ligand binding, fail to interact with the membrane-bound complex and/or to transmit transmembrane signals.

Published

1995

13. Structural basis for multiple ligand specificity of the periplasmic lysine-, arginine-, ornithine-binding protein

Author

Byung-Ha Oh, Sung-HouK Kim, and Giovanna Ferro-Luzzi Ames

Subjects

Arginine, Chemistry, Ligand, Stereochemistry, Binding protein, Lysine, Side chain, Cell Biology, Periplasmic space, Binding site, Molecular Biology, Biochemistry, Histidine

Abstract

The substrate-binding site of a protein with multiple specificity should satisfy geometric and energetic complementarity for several different substrates. The structural basis of the multiple ligand specificity of the periplasmic lysine-, arginine-, ornithine-binding protein (LAO) was investigated by determining and analyzing the structures of the protein unliganded and liganded with each of the three high-affinity ligands (L-lysine, L-arginine, and L-ornithine) and with one low-affinity ligand (L-histidine). The geometric complementarity is achieved primarily by virtue of the large size of the ligand-binding site which can accommodate the maximum common volume of the four ligands plus three water molecules. The optimization of energetic complementarity is achieved by the relocation of protein-bound water molecules and by the movement of the Asp-11 side chain. The structure of the LAO-histidine complex indicates that the 30-fold reduced affinity of the protein for histidine is primarily due to unavailability of one ionic interaction of the histidine side chain with the protein which is present in the other three complexes.

Published

1994

14. The bacterial periplasmic histidine-binding protein. structure/function analysis of the ligand-binding site and comparison with related proteins

Author

Giovanna Ferro-Luzzi Ames, Sung-Hou Kim, H.L. De Bondt, ChulHee Kang, A. K. Joshi, Byung-Ha Oh, and Kishiko Nikaido

Subjects

Protein structure, Chemistry, Stereochemistry, Binding protein, Periplasmic Binding Proteins, Molecular replacement, Cell Biology, Binding site, Ligand (biochemistry), Arginine binding, Molecular Biology, Biochemistry, Histidine

Abstract

Bacterial periplasmic binding proteins are initial receptors in the process of active transport across cell membranes and/or chemotaxis. Among them, the histidine-binding protein (HisJ) has been extensively studied from the biochemical, physiological, and genetic points of view. The three-dimensional crystal structure of the histidine-binding protein complexed with histidine has been determined at 2.5-A resolution by the molecular replacement method using a probe structure the previously solved lysine-liganded structure of the lysine-, arginine-, ornithine-binding protein (LAO), which shares 70% sequence identity with HisJ. The structure is bi-lobate; the two lobes, one bigger than the other, are connected by two short strands and are in contact with each other (closed) enclosing the histidine. Charged, polar, and non-polar side chains, as well as the peptide backbone, are involved in tight binding of the histidine. The bound histidine is involved in eight direct hydrogen bonds, six with the bigger lobe and two with the smaller lobe, in one potential water-mediated hydrogen bond with the bigger lobe, as well as in ionic interactions. The HisJ residues surrounding the ligand are the same as the LAO residues interacting with lysine, except for residue 52 which is leucine in HisJ and phenylalanine in LAO. The Leu-52 in HisJ makes a hydrophobic interaction with the imidazole ring of histidine. Of seven mutations affecting the ligand-binding site, five are located in the ligand-binding site, one in a connecting strand, and one at the domains interface. Based on comparisons among related binding proteins, the specific interactions between the ligands and the respective binding protein residues are predicted for the glutamine-binding protein and the opines-binding protein.

Published

1994

15. Three-dimensional structures of the periplasmic lysine/arginine/ornithine-binding protein with and without a ligand

Author

Sung-Hou Kim, Byung-Ha Oh, Kishiko Nikaido, Sabiha Gokcen, ChulHee Kang, Giovanna Ferro-Luzzi Ames, and Jayvardhan Pandit

Subjects

chemistry.chemical_classification, Conformational change, Stereochemistry, Binding protein, Lysine, Cell Biology, Periplasmic space, Ligand (biochemistry), Biochemistry, Amino acid, Protein structure, chemistry, Periplasmic Binding Proteins, Molecular Biology

Abstract

Many proteins exhibit a large-scale movement of rigid globular domains. Among these, bacterial periplasmic binding proteins involved in substrate transport, or transport and chemotaxis, can be used as prototypes for understanding the mechanism of the movement. Such movements have been found to be associated with specific functions, such as substrate binding, catalysis, and recognition by other biomolecules. We have determined the three-dimensional structures of the lysine/arginine/ornithine-binding protein (LAO) from Salmonella typhimurium with and without lysine by x-ray crystallographic methods at 1.8- and 1.9-A resolution, respectively. The structures are composed of two lobes held together by two short connecting strands. The two lobes are far apart in the unliganded structure, but in contact with each other in the lysine-liganded structure. The large movement of the lobes is a consequence of a 52 degrees rotation of a single backbone torsion angle in the first connecting strand and of distributed smaller changes of three backbone torsion angles of the second connecting strand. The absence of contact between the lysine and the connecting strands suggests that the ligand does not induce the conformational change directly. We instead propose that the unliganded protein undergoes a dynamic change between an "open" and a "closed" conformation and that the role of the ligand is to stabilize the closed conformation. We discuss the nature of a surface area which might be recognized by the membrane-bound complex of these amino acids transport systems.

Published

1993

16. Structural basis of inactivation of Ras and Rap1 small GTPases by Ras/Rap1-specific endopeptidase from the sepsis-causing pathogen Vibrio vulnificus.

Author

Song Yee Jang, Jungwon Hwang, Byoung Sik Kim, Eun-Young Lee, Byung-Ha Oh, and Myung Hee Kim

Subjects

*ENDOPEPTIDASES, *VIRUS-induced enzymes, *VIBRIO vulnificus, *RAS oncogenes, *GRAM-negative bacteria, *MACROMOLECULES, *PROTEIN structure, *GUANOSINE triphosphatase

Abstract

Multifunctional autoprocessing repeats-in-toxin (MARTX) toxins are secreted by Gram-negative bacteria and function as primary virulence-promoting macromolecules that deliver multiple cytopathic and cytotoxic effector domains into the host cytoplasm. Among these effectors, Ras/Rap1-specific endopeptidase (RRSP) catalyzes the sequence-specific cleavage of the Switch I region of the cellular substrates Ras and Rap1 that are crucial for host innate immune defenses during infection. To dissect the molecular basis underpinning RRSP-mediated substrate inactivation, we determined the crystal structure of an RRSP from the sepsis-causing bacterial pathogen Vibrio vulnificus (VvRRSP). Structural and biochemical analyses revealed that VvRRSP is a metal-independent TIKI family endopeptidase composed of an N-terminal membrane-localization and substrate- recruitment domain (N lobe) connected via an inter-lobe linker to the C-terminal active site--coordinating core β-sheet--containing domain (C lobe). Structure-based mutagenesis identified the 2His/2Glu catalytic residues in the core catalytic domain that are shared with other TIKI family enzymes and that are essential for Ras processing. In vitro KRas cleavage assays disclosed that deleting the N lobe in VvRRSP causes complete loss of enzymatic activity. Endogenous Ras cleavage assays combined with confocal microscopy analysis of HEK293T cells indicated that the N lobe functions both in membrane localization via the first α-helix and in substrate assimilation by altering the functional conformation of the C lobe to facilitate recruitment of cellular substrates. Collectively, these results indicate that RRSP is a critical virulence factor that robustly inactivates Ras and Rap1 and augments the pathogenicity of invading bacteria via the combined effects of its N and C lobes. [ABSTRACT FROM AUTHOR]

Published

2018

17. Crystal Structure of the Gtr1pGTP-Gtr2pGDP Protein Complex Reveals Large Structural Rearrangements Triggered by GTP-to-GDP Conversion.

Author

Jae-Hee Jeong, Kwang-Hoon Lee, Young-Mi Kim, Do-Hyung Kim, Byung-Ha Oh, and Yeon-Gil Kim

Subjects

*PROTEIN structure, *CRYSTAL structure, *RAPAMYCIN, *GUANOSINE triphosphatase, *AMINO acids, *GENETIC transcription

Abstract

The heterodimeric Rag GTPases consisting of RagA (or RagB) and RagC (or RagD) are the key regulator activating the target of rapamycin complex 1 (TORC1) in response to the level of amino acids. The heterodimer between GTP-loaded RagA/B and GDPloaded RagC/D is the most active form that binds Raptor and leads to the activation of TORC1. Here, we present the crystal structure of Gtr1pGTP-Gtr2pGDP, the active yeast Rag GTPase heterodimer. The structure reveals that GTP-to-GDP conversion on Gtr2p results in a large conformational transition of this subunit, including a large scale rearrangement of a long segment whose corresponding region in RagA is involved in binding to Raptor. In addition, the two GTPase domains of the heterodimer are brought to contact with each other, but without causing any conformational change of the Gtr1p subunit. These features explain how the nucleotide-bound statuses of the two GTPases subunits switch the Raptor binding affinity on and off. [ABSTRACT FROM AUTHOR]

Published

2012

18. Association of Novel Domain in Active Site of Archaic Hyperthermophilic Maltogenic Amylase from Staphylothermus marinus.

Author

Tae-Yang Jung, Dan Li, Jong-Tae Park, Se-Mi Yoon, Phuong Lan Tran, Byung-Ha Oh, Štefan Janeček, Sung Goo Park, Eui-Jeon Woo, and Kwan-Hwa Park

Subjects

*CYCLODEXTRINS, *OLIGOSACCHARIDES, *ENZYMES, *HIGH temperatures, *ARCHAEBACTERIA, *AMYLASES

Abstract

Staphylothermus marinus maltogenic amylase (SMMA) is a novel extreme thermophile maltogenic amylase with an optimal temperature of 100 °C, which hydrolyzes α-(1-4)-glycosyl linkages in cyclodextrins and in linear malto-oligosaccharides. This enzyme has a long N-terminal extension that is conserved among archaic hyperthermophilic amylases but is not found in other hydrolyzing enzymes from the glycoside hydrolase 13 family. The SMMA crystal structure revealed that the N-terminal extension forms an Nα domain that is similar to carbohydrate-binding module 48, with the strand-loopstrand region forming a part of the substrate binding pocket with several aromatic residues, including Phe-95, Phe-96, and Tyr-99. A structural comparison with conventional cyclodextrin-hydrolyzing enzymes revealed a striking resemblance between the SMMA Nα domain position and the dimeric N domain position in bacterial enzymes. This result suggests that extremophilic archaea that live at high temperatures may have adopted a novel domain arrangement thatcombinesallofthesubstratebindingcomponentswithinamonomeric subunit. The SMMA structure provides a molecular basis for the functional properties that are unique to hyperthermophile maltogenic amylases from archaea and that distinguishSMMAfrom moderate thermophilic or mesophilic bacterial enzymes. [ABSTRACT FROM AUTHOR]

Published

2012

19. Arg-158 Is Critical in Both Binding the Substrate and Stabilizing the Transition-state Oxyanion for the Enzymatic Reaction of Malonamidase E2.

Author

Young Sung Yun, Wook Lee, Sejeong Shin, Byung-Ha Oh, and Kwan Yong Choi

Subjects

*ENZYMES, *HYDROLASES, *BINDING sites, *BIOCHEMISTRY, *PROTEINS, *ORGANIC compounds

Abstract

Malonamidase E2 (MAE2) from Bradyrhizobium japonicum is an enzyme that hydrolyzes malonamate to malonate and has a Ser-cis-Ser-Lys catalytic triad at the active site. The crystal structures of wild type and mutant MAE2 exhibited that the guanido group of Arg-158 could be involved in the binding of malonamate in which the negative charge of the carboxyl group could destabilize a negatively charged transition-state oxyanion in the enzymatic reaction. In an attempt to elucidate the specific roles of Arg-158, site-directed mutants, R158Q, R158E, and R158K, were prepared (see Table 1). The crystal structure of R158Q determined at 2.2 Å resolution showed that the guanido group of Arg-158 was important for the substrate binding with the marginal structural change upon the mutation. The kcat value of R158Q significantly decreased by over 1500-fold and the catalytic activity of R158E could not be detected. The kcat value of R158K was similar to that of the wild type with the Km value drastically increased by 100-fold, suggesting that Lys-158 of R158K can stabilize the negative charge of the carboxylate in the substrate to some extent and contribute to the stabilization of the transition-state oxyanion, but a single amine group of Lys-158 in R158K could not precisely anchor the carboxyl group of malonamate compared with the guanido group of Arg-158. Our kinetic and structural evidences demonstrate that Arg-158 in MAE2 should be critical to both binding the substrate and stabilizing the transition-state oxyanion for the catalytic reaction of MAE2. [ABSTRACT FROM AUTHOR]

Published

2006

20. Structural Basis for Preferential Recognition of Diaminopimelic Acid-type Peptidoglycan by a Subset of Peptidoglycan Recognition Proteins.

Author

Jae-Hong Lim, Min-Sung Kim, Han-Eol Kim, Yano, Tamaki, Oshima, Yoshiteru, Aggarwal, Kamna, Goldman, William E., Silverman, Neal, Kurata, Shoichiro, and Byung-Ha Oh

Subjects

*PEPTIDOGLYCANS, *PROTEINS, *BACTERIA, *LYSINE, *DROSOPHILA, *LIGANDS (Biochemistry)

Abstract

Drosophila peptidoglycan recognition protein (PGRP)-LCx and -LCa are receptors that preferentially recognize meso-diaminopimelic acid (DAP)-type peptidoglycan (PGN) present in Gram-negative bacteria over lysine-type PGN of Gram-positive bacteria and initiate the IMD signaling pathway, whereas PGRP-LE plays a synergistic role in this process of innate immune defense. How these receptors can distinguish the two types of PGN remains unclear. Here the structure of the PGRP domain of Drosophila PGRP-LE in complex with tracheal cytotoxin (TCT), the monomeric DAP-type PGN, reveals a buried ionic interaction between the unique carboxyl group of DAP and a previously unrecognized arginine residue. This arginine is conserved in the known DAP-type PGN-interacting PGRPs and contributes significantly to the affinity of the protein for the ligand. Unexpectedly, TCT induces infinite head-to-tail dimerization of PGRP-LE, in which the disaccharide moiety, but not the peptide stem, of TCT is positioned at the dimer interface. A sequence comparison suggests that TCT induces heterodimerization of the ectodomains of PGRP-LCx and -LCa in a closely analogous manner to prime the IMD signaling pathway, except that the heterodimer formation is nonperpetuating. [ABSTRACT FROM AUTHOR]

Published

2006

21. Origin of the Different pH Activity Profile in Two Homologous Ketosteroid Isomerases.

Author

Young Sung Yun, Tae-Hee Lee, Gyu Hyun Nam, Do Soo Jang, Sejeong Shin, Byung-Ha Oh, and Kwan Yong Choi

Subjects

*ISOMERASES, *PSEUDOMONAS, *ISOENZYMES, *BIOCHEMISTRY

Abstract

Two homologous Δ[sup 5]-3-ketosteroid isomerases from Comamonas testosteroni (TI-WT) and Pseudomonas putida biotype B (PI-WT) exhibit different pH activity profiles. TI-WT loses activity below pH 5.0 due to the protonation of the conserved catalytic base, Asp-38, while PI-WT does not. Based on the structural analysis of PI-WT, the critical catalytic base, Asp-38, was found to form a hydrogen bond with the indole ring NH of Trp-116, which is homologously replaced with Phe-116 in TI-WT. To investigate the role of Trp-116, we prepared the F116W mutant of TI-WT (TI-F116W) and the W116F mutant of PI-WT (PI-W116F) and compared kinetic parameters of those mutants at different pH levels. PI-W116F exhibited significantly decreased catalytic activity at acidic pH like TI-WT, whereas TI-F116W maintained catalytic activity at acidic pH like PI-WT and increased the k[sub cat]/K[sub m] value by 2.5- to 4.7-fold compared with TI-WT at pH 3.8. The crystal structure of TI-F116W clearly showed that the indole ring NH of Trp-116 could form a hydrogen bond with the carboxyl oxygen of Asp-38 like that of PI-WT. The present results demonstrate that the activities of both PI-WT and TI-F116W at low pH were maintained by a tryptophan, which was able not only to lower the pK[sub a] value of the catalytic base but also to increase the substrate affinity. This is one example of the strategy nature can adopt to evolve the diversity of the catalytic function in the enzymes. Our results provide insight into deciphering the molecular evolution of the enzyme and creating novel enzymes by protein engineering. [ABSTRACT FROM AUTHOR]

Published

2003

22. Characterization of a Novel Ser-cisSer-Lys Catalytic Triad in Comparison with the Classical Ser-His-Asp Triad.

Author

Sejeong Shin, Young Sung Yun, Hyun Min Koo, Yu Sam Kim, Kwan Yong Choi, and Byung-Ha Oh

Subjects

*AMIDASES, *CATALYSIS, *SERINE

Abstract

Characterizes the Ser-cisSer-Lys catalytic triad. Comparison with Ser-His-Asp triad; Catalytic roles of Ser; Catalytic role of Lys in stabilizing Ser alkoxide; Effect of site-directed mutagenesis on the catalyst efficiency.

Published

2003