scholarly journals Structure and Functional Analysis of a Ribosomal Oxygenase

2014 ◽  
Vol 70 (a1) ◽  
pp. C1408-C1408
Author(s):  
Laura van Staalduinen ◽  
Stefanie Novakowski ◽  
Zongchao Jia
Keyword(s):  
Ribosomal Protein ◽  
Active Site ◽  
Three Dimensional ◽  
Large Family ◽  
Structural Similarity ◽  
Dimensional Structure ◽  
Titration Calorimetry ◽  
Ribosome Assembly ◽  
Oxidation Reactions ◽  
Jmjc Domain

The 2-oxoglutarate/Fe(II)-dependent oxygenases (2OG oxygenases) are a large family of proteins that share a similar overall three-dimensional structure and catalyze a diverse array of oxidation reactions. The Jumonji C (JmjC)-domain containing proteins represent an important subclass of the 2OG oxygenase family that typically catalyze protein hydroxylation; however, recently other reactions have been identified, such as tRNA modification. The E. coli gene, ycfD, was predicted to be a JmjC-domain containing protein of unknown function based on primary sequence. Recently YcfD was determined to act as a ribosomal oxygenase, hydroxylating an arginine residue on the 50S ribosomal protein L-16 (RL-16). We have determined the crystal structure of YcfD at 2.7 Å resolution, revealing that YcfD is structurally similar to known JmjC proteins and possesses the characteristic double stranded β-helix fold or cupin domain. Separate from the cupin domain, an additional globular module termed -helical arm mediates dimerization of YcfD. We further have shown that 2-oxoglutarate binds to YcfD using isothermal titration calorimetry and identified R140 and S116 as key 2OG binding residues using mutagenesis which, together with the iron location and structural similarity with other cupin family members, allowed identification of the active site. Structural homology to ribosomal assembly proteins combined with GST-YcfD pull-down of a ribosomal protein and docking of RL-16 to the YcfD active site support the role of YcfD in regulation of bacterial ribosome assembly. Furthermore, overexpression of YcfD is shown to inhibit cell growth signifying a toxic effect on ribosome assembly.

scholarly journals Structure and Mechanism of Ferulic Acid Decarboxylase (FDC1) from Saccharomyces cerevisiae

2015 ◽  
Vol 81 (12) ◽  
pp. 4216-4223 ◽  
Author(s):  
Mohammad Wadud Bhuiya ◽  
Soon Goo Lee ◽  
Joseph M. Jez ◽  
Oliver Yu
Keyword(s):  
Crystal Structure ◽  
Saccharomyces Cerevisiae ◽  
Ferulic Acid ◽  
Active Site ◽  
Three Dimensional ◽  
Structural Similarity ◽  
Dimensional Structure ◽  
Acid Decarboxylase ◽  
Content Type ◽  
Ferulic Acid Decarboxylase

ABSTRACTThe nonoxidative decarboxylation of aromatic acids occurs in a range of microbes and is of interest for bioprocessing and metabolic engineering. Although phenolic acid decarboxylases provide useful tools for bioindustrial applications, the molecular bases for how these enzymes function are only beginning to be examined. Here we present the 2.35-Å-resolution X-ray crystal structure of the ferulic acid decarboxylase (FDC1; UbiD) fromSaccharomyces cerevisiae. FDC1 shares structural similarity with the UbiD family of enzymes that are involved in ubiquinone biosynthesis. The position of 4-vinylphenol, the product ofp-coumaric acid decarboxylation, in the structure identifies a large hydrophobic cavity as the active site. Differences in the β2e-α5 loop of chains in the crystal structure suggest that the conformational flexibility of this loop allows access to the active site. The structure also implicates Glu285 as the general base in the nonoxidative decarboxylation reaction catalyzed by FDC1. Biochemical analysis showed a loss of enzymatic activity in the E285A mutant. Modeling of 3-methoxy-4-hydroxy-5-decaprenylbenzoate, a partial structure of the physiological UbiD substrate, in the binding site suggests that an ∼30-Å-long pocket adjacent to the catalytic site may accommodate the isoprenoid tail of the substrate needed for ubiquinone biosynthesis in yeast. The three-dimensional structure of yeast FDC1 provides a template for guiding protein engineering studies aimed at optimizing the efficiency of aromatic acid decarboxylation reactions in bioindustrial applications.

scholarly journals Crystal structure of the catalytic core domain of the family 6 cellobiohydrolase II, Cel6A, from Humicola insolens, at 1.92 Å resolution

1999 ◽  
Vol 337 (2) ◽  
pp. 297-304 ◽  
Author(s):  
Annabelle VARROT ◽  
Sven HASTRUP ◽  
Martin SCHÜLEIN ◽  
Gideon J. DAVIES
Keyword(s):  
Active Site ◽  
Three Dimensional ◽  
Structural Similarity ◽  
Data Bank ◽  
Dimensional Structure ◽  
Active Site Residues ◽  
Catalytic Core ◽  
Humicola Insolens ◽  
The Family ◽  
Cellobiohydrolase Ii

The three-dimensional structure of the catalytic core of the family 6 cellobiohydrolase II, Cel6A (CBH II), from Humicola insolens has been determined by X-ray crystallography at a resolution of 1.92 Å. The structure was solved by molecular replacement using the homologous Trichoderma reesei CBH II as a search model. The H. insolens enzyme displays a high degree of structural similarity with its T. reeseiequivalent. The structure features both O- (α-linked mannose) and N-linked glycosylation and a hexa-co-ordinate Mg2+ ion. The active-site residues are located within the enclosed tunnel that is typical for cellobiohydrolase enzymes and which may permit a processive hydrolysis of the cellulose substrate. The close structural similarity between the two enzymes implies that kinetics and chain-end specificity experiments performed on the H. insolens enzyme are likely to be applicable to the homologous T. reesei enzyme. These cast doubt on the description of cellobiohydrolases as exo-enzymes since they demonstrated that Cel6A (CBH II) shows no requirement for non-reducing chain-ends, as had been presumed. There is no crystallographic evidence in the present structure to support a mechanism involving loop opening, yet preliminary modelling experiments suggest that the active-site tunnel of Cel6A (CBH II) is too narrow to permit entry of a fluorescenyl-derivatized substrate, known to be a viable substrate for this enzyme. Co-ordinates for the structure described in this paper have been deposited with the Brookhaven Protein Data Bank with accession code 1BVW.PDB.

scholarly journals Relationship between sequence conservation and three-dimensional structure in a large family of esterases, lipases, and related proteins

1993 ◽  
Vol 2 (3) ◽  
pp. 366-382 ◽  
Author(s):  
Miroslaw Cygler ◽  
Joseph D. Schrag ◽  
Joel L. Sussman ◽  
Michal Harel ◽  
Israel Silman ◽  
...  
Keyword(s):  
Three Dimensional ◽  
Large Family ◽  
Sequence Conservation ◽  
Dimensional Structure ◽  
Three Dimensional Structure ◽  
Related Proteins

Ribosomal protein S17: Characterization of the three-dimensional structure by proton and nitrogen-15 NMR

Biochemistry ◽  
1993 ◽  
Vol 32 (47) ◽  
pp. 12812-12820 ◽  
Author(s):  
Barbara L. Golden ◽  
David W. Hoffman ◽  
V. Ramakrishnan ◽  
Stephen W. White
Keyword(s):  
Ribosomal Protein ◽  
Three Dimensional ◽  
Dimensional Structure ◽  
Three Dimensional Structure

scholarly journals Structural Features of a Bacteroidetes-Affiliated Cellulase Linked with a Polysaccharide Utilization Locus

2015 ◽  
Vol 5 (1) ◽  
Author(s):  
A.E. Naas ◽  
A.K. MacKenzie ◽  
B. Dalhus ◽  
V.G.H. Eijsink ◽  
P.B. Pope
Keyword(s):  
Active Site ◽  
Three Dimensional ◽  
Structural Features ◽  
Structure And Function ◽  
Dimensional Structure ◽  
Active Site Cleft ◽  
Polysaccharide Utilization Locus ◽  
And Function ◽  
Rumen Metagenome

Abstract Previous gene-centric analysis of a cow rumen metagenome revealed the first potentially cellulolytic polysaccharide utilization locus, of which the main catalytic enzyme (AC2aCel5A) was identified as a glycoside hydrolase (GH) family 5 endo-cellulase. Here we present the 1.8 Å three-dimensional structure of AC2aCel5A and characterization of its enzymatic activities. The enzyme possesses the archetypical (β/α)8-barrel found throughout the GH5 family and contains the two strictly conserved catalytic glutamates located at the C-terminal ends of β-strands 4 and 7. The enzyme is active on insoluble cellulose and acts exclusively on linear β-(1,4)-linked glucans. Co-crystallization of a catalytically inactive mutant with substrate yielded a 2.4 Å structure showing cellotriose bound in the −3 to −1 subsites. Additional electron density was observed between Trp178 and Trp254, two residues that form a hydrophobic “clamp”, potentially interacting with sugars at the +1 and +2 subsites. The enzyme’s active-site cleft was narrower compared to the closest structural relatives, which in contrast to AC2aCel5A, are also active on xylans, mannans and/or xyloglucans. Interestingly, the structure and function of this enzyme seem adapted to less-substituted substrates such as cellulose, presumably due to the insufficient space to accommodate the side-chains of branched glucans in the active-site cleft.

PREDICTION OF THE THREE-DIMENSIONAL STRUCTURE OF THE ENZYMATIC PART OF T-PA

1987 ◽  
Author(s):  
A Heckel ◽  
K M Hasselbach
Keyword(s):  
Amino Acids ◽  
Amino Acid ◽  
Active Site ◽  
Serine Proteases ◽  
Three Dimensional ◽  
Amino Acid Sequences ◽  
Dimensional Structure ◽  
Salt Bridges ◽  
Three Dimensional Structure ◽  
Insertions And Deletions

Up to now the three-dimensional structure of t-PA or parts of this enzyme is unknown. Using computer graphical methods the spatial structure of the enzymatic part of t-PA is predicted on the hypothesis, the three-dimensional backbone structure of t-PA being similar to that of other serine proteases. The t-PA model was built up in three steps:1) Alignment of the t-PA sequence with other serine proteases. Comparison of enzyme structures available from Brookhaven Protein Data Bank proved elastase as a basis for modeling.2) Exchange of amino acids of elastase differing from the t-PA sequence. The replacement of amino acids was performed such that backbone atoms overlapp completely and side chains superpose as far as possible.3) Modeling of insertions and deletions. To determine the spatial arrangement of insertions and deletions parts of related enzymes such as chymotrypsin or trypsin were used whenever possible. Otherwise additional amino acid sequences were folded to a B-turn at the surface of the proteine, where all insertions or deletions are located. Finally the side chain torsion angles of amino acids were optimised to prevent close contacts of neigh bouring atoms and to improve hydrogen bonds and salt bridges.The resulting model was used to explain binding of arginine 560 of plasminogen to the active site of t-PA. Arginine 560 interacts with Asp 189, Gly 19 3, Ser 19 5 and Ser 214 of t-PA (chymotrypsin numbering). Furthermore interaction of chromo-genic substrate S 2288 with the active site of t-PA was studied. The need for D-configuration of the hydrophobic amino acid at the N-terminus of this tripeptide derivative could be easily explained.

scholarly journals The three-dimensional structure of a class-Pi glutathione S-transferase complexed with glutathione: the active-site hydration provides insights into the reaction mechanism

1998 ◽  
Vol 333 (3) ◽  
pp. 811-816 ◽  
Author(s):  
Antonio PÁRRAGA ◽  
Isabel GARCÍA-SÁEZ ◽  
Sinead B. WALSH ◽  
Timothy J. MANTLE ◽  
Miquel COLL
Keyword(s):  
Conformational Changes ◽  
Active Site ◽  
Three Dimensional ◽  
Dimensional Structure ◽  
Water Molecules ◽  
X Ray Diffraction ◽  
Glutathione S Transferase ◽  
X Ray ◽  
The Right

The structure of mouse liver glutathione S-transferase P1-1 complexed with its substrate glutathione (GSH) has been determined by X-ray diffraction analysis. No conformational changes in the glutathione moiety or in the protein, other than small adjustments of some side chains, are observed when compared with glutathione adduct complexes. Our structure confirms that the role of Tyr-7 is to stabilize the thiolate by hydrogen bonding and to position it in the right orientation. A comparison of the enzyme–GSH structure reported here with previously described structures reveals rearrangements in a well-defined network of water molecules in the active site. One of these water molecules (W0), identified in the unliganded enzyme (carboxymethylated at Cys-47), is displaced by the binding of GSH, and a further water molecule (W4) is displaced following the binding of the electrophilic substrate and the formation of the glutathione conjugate. The possibility that one of these water molecules participates in the proton abstraction from the glutathione thiol is discussed.

Structure of the Calcium Pump from Sarcoplasmic Reticulum at 8 Å Resolution: Architecture of the Transmembrane Helices and Localization of the Binding Site for Thapsigargin

1998 ◽  
Vol 4 (S2) ◽  
pp. 462-463
Author(s):  
P. Zhang ◽  
C. Toyoshima ◽  
K. Yonekura ◽  
G. Inesi ◽  
M. Green ◽  
...  
Keyword(s):  
Sarcoplasmic Reticulum ◽  
Transmembrane Domain ◽  
Three Dimensional ◽  
Specific Inhibitor ◽  
Large Family ◽  
Calcium Pump ◽  
Dimensional Structure ◽  
Transmembrane Helices ◽  
Site Mutagenesis ◽  
P Type

The calcium pump (Ca2+-ATPase) from sarcoplasmic reticulum (SR) is a prominent member of the large family of ATP-dependent cation pumps, which include Na+ /K+-ATPase, H+/K+-ATPase from the stomach, H+-ATPase from yeast and Neurospora, and various detoxifying pumps for Cd+, Cu+ and other metals. In muscle, calcium is stored inside the SR and contraction is initiated by regulated release through specific calcium channels; Ca2+ -ATPase is responsible for relaxation by pumping calcium back into the SR lumen. Many techniques (chemical modification, site mutagenesis, reaction kinetics) have been used to correlate Ca2+-ATPase sequence with function, but no high resolution three-dimensional structure of Ca2+-ATPase, or any P-type pump, has yet been determined. In the current work, we have determined the structure from helical crystals at 8 A resolution and thus revealed the alpha-helical architecture of the transmembrane domain. In addition, a specific inhibitor of Ca2+-ATPase, thapsigargin, was used to promote crystallization and we have characterized the structural consequences of its inhibition.

A murrel cysteine protease, cathepsin L: bioinformatics characterization, gene expression and proteolytic activity

Biologia ◽  
2014 ◽  
Vol 69 (3) ◽  
Author(s):  
Venkatesh Kumaresan ◽  
Prasanth Bhatt ◽  
Rajesh Palanisamy ◽  
Annie Gnanam ◽  
Mukesh Pasupuleti ◽  
...  
Keyword(s):  
Gene Expression ◽  
Bacterial Infections ◽  
Cathepsin L ◽  
Three Dimensional ◽  
Structural Similarity ◽  
Data Bank ◽  
Minimum Free Energy ◽  
Dimensional Structure ◽  
Peptide Bonds ◽  
Gene Expression Studies

AbstractCathepsin L, a lysosomal endopeptidase, is a member of the peptidase C1 family (papain-like family) of cysteine proteinases that cleave peptide bonds of lysosomal proteins. In this study, we report a cathepsin L sequence identified from the constructed cDNA library of striped murrel Channa striatus (designated as CsCath L) using genome sequencing FLXTM technology. The full-length CsCath L contains three eukaryotic thiol protease domains at positions 134-145, 278-288 and 299-318. Phylogenetic analysis revealed that the CsCath L was clustered together with other cathepsin L from teleosts. The three-dimensional structure of CsCath L modelled by the I-Tasser program was compared with structures deposited in the Protein Data Bank to find out the structural similarity of CsCath L with experimentally identified structures. The results showed that the CsCath L exhibits maximum structural identity with pro-cathepsin L from human. The RNA fold structure of CsCath L was predicted along with its minimum free energy (−471.93 kcal/mol). The highest CsCath L gene expression was observed in liver, which was also significantly higher (P < 0.05) than that detected in other tissues taken for analysis. In order to investigate the mRNA transcription profile of CsCath L during infection, C. striatus were injected with fungus (Aphanomyces invadans) and bacteria (Aeromonas hydrophila) and its expression was up-regulated in liver at various time points. Similar to gene expression studies, the highest CsCath L enzyme activity was also observed in liver and its activity was up-regulated by fungal and bacterial infections.

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