scholarly journals On the catalytic mechanism of prokaryotic leader peptidase 1

1992 ◽  
Vol 282 (2) ◽  
pp. 539-543 ◽  
Author(s):  
M T Black ◽  
J G R Munn ◽  
A E Allsop
Keyword(s):  
Catalytic Mechanism ◽  
Serine Proteinase ◽  
Site Directed Mutagenesis ◽  
Cysteine Residues ◽  
Calculated Molecular Mass ◽  
E Coli ◽  
Leader Peptidase ◽  
Mutant Forms ◽  
Thiol Proteinases

The catalytic mechanism of leader peptidase 1 (LP1) of the bacterium Escherichia coli has been investigated by a combination of site-directed mutagenesis, assays of enzyme activity in vivo utilizing a strain of E. coli which has a conditional defect in LP1 activity, and gene cloning. The biological activity of mutant forms of E. coli LP1 demonstrates that this enzyme belongs to a novel class of proteinases. The possibility that LP1 may be an aspartyl proteinase has been excluded on the basis of primary sequence comparison and mutagenesis. Assignment of LP1 to one of the other three recognized classes of proteinases (metalloproteinases, thiol proteinases and the classical serine proteinases) can also be excluded, as it is clearly demonstrated that none of the histidine or cysteine residues within LP1 are required for catalytic activity. The Pseudomonas fluorescens lep gene has been cloned and sequenced and the corresponding amino acid sequence compared with that of E. coli LP1. The E. coli LP1 and P. fluorescens LP1 primary sequences are 50% identical after insertion of gaps. The P. fluorescens LP1 has 39 fewer amino acids, a calculated molecular mass of 31903 Da and functions effectively in vivo in E. coli. None of the cysteine residues and only one of the histidine residues which are present in E. coli LP1 are conserved in sequence position in the P. fluorescens LP1 enzyme. The possibility that LP1 is a novel type of serine proteinase is discussed.

scholarly journals Mu-class glutathione transferase from Xenopus laevis: molecular cloning, expression and site-directed mutagenesis

2002 ◽  
Vol 365 (3) ◽  
pp. 685-691 ◽  
Author(s):  
Antonella De LUCA ◽  
Bartolo FAVALORO ◽  
Stefania ANGELUCCI ◽  
Paolo SACCHETTA ◽  
Carmine Di ILIO
Keyword(s):  
Xenopus Laevis ◽  
Catalytic Mechanism ◽  
Glutathione Transferase ◽  
Structural Instability ◽  
Site Directed Mutagenesis ◽  
Directed Mutagenesis ◽  
Amino Acid Residues ◽  
Calculated Molecular Mass

A cDNA encoding a Mu-class glutathione transferase (XlGSTM1-1) has been isolated from a Xenopus laevis liver library, and its nucleotide sequence has been determined. XlGSTM1-1 is composed of 219 amino acid residues with a calculated molecular mass of 25359Da. Unlike many mammalian Mu-class GSTs, XlGSTM1-1 has a narrow spectrum of substrate specificity and it is also less effective in conjugating 1-chloro-2,4-dinitrobenzene. A notable structural feature of XlGSTM1-1 is the presence of the Cys-139 residue in place of the Glu-139, as well as the absence of the Cys-114 residue, present in other Mu-class GSTs, which is replaced by Ala. Site-directed mutagenesis experiments indicate that Cys-139 is not involved in the catalytic mechanism of XlGSTM1-1 but may be in part responsible for its structural instability, and experiments in vivo confirmed the role of this residue in stability. Evidence indicating that Arg-107 is essential for the 1-chloro-2,4-dinitrobenzene conjugation capacity of XlGSTM1-1 is also presented.

Glyoxalase I – structure, function and a critical role in the enzymatic defence against glycation

2003 ◽  
Vol 31 (6) ◽  
pp. 1343-1348 ◽  
Author(s):  
P.J. Thornalley
Keyword(s):  
Metal Ion ◽  
Catalytic Mechanism ◽  
Critical Role ◽  
Glyoxalase I ◽  
Water Molecules ◽  
Glyoxalase System ◽  
E Coli ◽  
Antimalarial Agents

Glyoxalase I is part of the glyoxalase system present in the cytosol of cells. The glyoxalase system catalyses the conversion of reactive, acyclic α-oxoaldehydes into the corresponding α-hydroxyacids. Glyoxalase I catalyses the isomerization of the hemithioacetal, formed spontaneously from α-oxoaldehyde and GSH, to S-2-hydroxyacylglutathione derivatives [RCOCH(OH)-SG→RCH(OH)CO-SG], and in so doing decreases the steady-state concentrations of physiological α-oxoaldehydes and associated glycation reactions. Physiological substrates of glyoxalase I are methylglyoxal, glyoxal and other acyclic α-oxoaldehydes. Human glyoxalase I is a dimeric Zn2+ metalloenzyme of molecular mass 42 kDa. Glyoxalase I from Escherichia coli is a Ni2+ metalloenzyme. The crystal structures of human and E. coli glyoxalase I have been determined to 1.7 and 1.5 Å resolution. The Zn2+ site comprises two structurally equivalent residues from each domain – Gln-33A, Glu-99A, His-126B, Glu-172B and two water molecules. The Ni2+ binding site comprises His-5A, Glu-56A, His-74B, Glu-122B and two water molecules. The catalytic reaction involves base-catalysed shielded-proton transfer from C-1 to C-2 of the hemithioacetal to form an ene-diol intermediate and rapid ketonization to the thioester product. R- and S-enantiomers of the hemithioacetal are bound in the active site, displacing the water molecules in the metal ion primary co-ordination shell. It has been proposed that Glu-172 is the catalytic base for the S-substrate enantiomer and Glu-99 the catalytic base for the R-substrate enantiomer; Glu-172 then reprotonates the ene-diol stereospecifically to form the R-2-hydroxyacylglutathione product. By analogy with the human enzyme, Glu-56 and Glu-122 may be the bases involved in the catalytic mechanism of E. coli glyoxalase I. The suppression of α-oxoaldehyde-mediated glycation by glyoxalase I is particularly important in diabetes and uraemia, where α-oxoaldehyde concentrations are increased. Decreased glyoxalase I activity in situ due to the aging process and oxidative stress results in increased glycation and tissue damage. Inhibition of glyoxalase I pharmacologically with specific inhibitors leads to the accumulation of α-oxoaldehydes to cytotoxic levels; cell-permeable glyoxalase I inhibitors are antitumour and antimalarial agents. Glyoxalase I has a critical role in the prevention of glycation reactions mediated by methylglyoxal, glyoxal and other α-oxoaldehydes in vivo.

scholarly journals Pairing properties of bromouracil and repair of bromouracil-containing DNA. Possible utilization of bromodeoxyuridine triphosphate for site-directed mutagenesis

1988 ◽  
Vol 253 (3) ◽  
pp. 637-643 ◽  
Author(s):  
M Muller ◽  
J Martial ◽  
W G Verly
Keyword(s):  
Dna Polymerase ◽  
Site Directed Mutagenesis ◽  
Klenow Fragment ◽  
Single Experiment ◽  
E Coli ◽  
Partial Repair ◽  
Before And After ◽  
Polymerase I

5-Bromo-2′-deoxyuridine triphosphate (Br-dUTP) and dTTP are used interchangeably for DNA synthesis in vitro by the Klenow fragment of Escherichia coli DNA polymerase I. When DNA containing Br-dUMP instead of dTMP at a few preselected sites is transfected into competent bacteria, no mutation occurs, indicating that in vivo E. coli DNA polymerase always places a dAMP residue in front of any unrepaired Br-dUMP residue. On the other hand, in vitro Br-dUTP can also replace dCTP, but only with difficulty: when dCTP is absent, Br-dUMP can be forced in front of a dGMP residue, but the Klenow polymerase pauses before and after addition of Br-dUMP. Transfection into E. coli of the substituted DNA leads to the expected G→A transitions. These mutations can easily be targeted by using a suitable primer and the correctly chosen mix of deoxynucleoside triphosphates containing Br-dUTP. When Br-dUMP has been placed in front of a dGMP residue, the mutation yield is not 100%, showing a partial repair of the transfected DNA before it is replicated. Advantage can be taken of this partial repair to prepare a set of different mutations within a target region in a single experiment.

scholarly journals Lysyl-tRNA Synthetase-generated Lysyl-Adenylate Is a Substrate for Histidine Triad Nucleotide Binding Proteins

2006 ◽  
Vol 282 (7) ◽  
pp. 4719-4727 ◽  
Author(s):  
Tsui-Fen Chou ◽  
Carston R. Wagner
Keyword(s):  
Binding Proteins ◽  
Nucleotide Binding ◽  
Trna Synthetase ◽  
Site Directed Mutagenesis ◽  
Trna Synthetases ◽  
E Coli ◽  
Protein Protein Interaction ◽  
Nucleotide Binding Proteins ◽  
Micromolar Range

Histidine triad nucleotide binding proteins (Hints) are the most ancient members of the histidine triad protein superfamily of nucleotidyltransferases and hydrolyases. Protein-protein interaction studies have found that complexes of the transcription factors MITF or USF2 and lysyl-tRNA synthetase (LysRS) are associated with human Hint1. Therefore, we hypothesized that lysyl-AMP or the LysRS·lysyl-AMP may be a native substrate for Hints. To explore the biochemical relationship between Hint1 and LysRS, a series of catalytic radiolabeling, mutagenesis, and kinetic experiments was conducted with purified LysRSs and Hints from human and Escherichia coli. After incubation of the E. coli or human LysRS with Hints and [α-32P]ATP, but not [α-32P]GTP, 32P-labeled Hints were observed. By varying time and the concentrations of lysine, Mg2+, or LysRS, the adenylation of Hint was found to be dependent on the formation of lysyl-AMP. Site-directed mutagenesis studies of the active site histidine triad revealed that Hint labeling could be abolished by substitution of either His-101 of E. coli hinT or His-112 of human Hint1 by either alanine or glycine. Ap4A, believed to be synthesized by LysRS in vivo, and Zn2+ were shown to inhibit the formation of Hint-AMP with an IC50 value in the low micromolar range. Consistent with pyrophosphate being an inhibitor for aminoacyl-tRNA synthetase, incubations in the presence of pyrophosphatase resulted in enhanced formation of Hint-AMP. These results demonstrate that the lysyl-AMP intermediate formed by LysRS is a natural substrate for Hints and suggests a potential highly conserved regulatory role for Hints on LysRS and possibly other aminoacyl-tRNA synthetases.

scholarly journals DNA Gap Repair-Mediated Site-Directed Mutagenesis is Different from Mandecki and Recombineering Approaches

2018 ◽  
Author(s):  
George T. Lyozin ◽  
Luca Brunelli
Keyword(s):  
Dna Sequence ◽  
Dna Sequences ◽  
Site Directed Mutagenesis ◽  
Directed Mutagenesis ◽  
Gene Products ◽  
E Coli ◽  
Health And Disease ◽  
First Time ◽  
Disease Understanding

AbstractSite-directed mutagenesis allows the generation of mutant DNA sequences for downstream functional analysis of genetic variants involved in human health and disease. Understanding the mechanisms of different mutagenesis methods can help select the best approach for specific needs. We compared three different approaches for in vivo site-directed DNA mutagenesis that utilize a mutant single-stranded DNA oligonucleotide (ssODN) to target a wild type DNA sequence in the host Escherichia coli (E. coli). The first method, Mandecki, uses restriction nucleases to introduce a double stranded break (DSB) into a DNA sequence which needs to be denatured prior to co-transformation. The second method, recombineering (recombination-mediated genetic engineering), requires lambda red gene products and a mutant ssODN with homology arms of at least 20 nucleotides. In a third method described here for the first time, DNA gap repair, a mutant ssODN targets a DNA sequence containing a gap introduced by PCR. Unlike recombineering, both DNA gap repair and Mandecki can utilize homology arms as short as 10 nucleotides. DNA gap repair requires neither red gene products as recombineering nor DNA denaturation or nucleases as Mandecki, and unlike other methods is background-free. We conclude that Mandecki, recombineering, and DNA gap repair have at least partly different mechanisms, and that DNA gap repair provides a new, straightforward approach for effective site-directed mutagenesis.

scholarly journals Molecular cloning, expression and site-directed mutagenesis of glutathione S-transferase from Ochrobactrum anthropi

1998 ◽  
Vol 335 (3) ◽  
pp. 573-579 ◽  
Author(s):  
Bartolo FAVALORO ◽  
Antonio TAMBURRO ◽  
Stefania ANGELUCCI ◽  
Antonella DE LUCA ◽  
Sonia MELINO ◽  
...  
Keyword(s):  
Amino Acid ◽  
Cumene Hydroperoxide ◽  
Data Bank ◽  
Site Directed Mutagenesis ◽  
Ochrobactrum Anthropi ◽  
Serine Residue ◽  
Glutathione S Transferase ◽  
Calculated Molecular Mass ◽  
Gst Activity

The gene coding for a novel glutathione S-transferase (GST) has been isolated from the bacterium Ochrobactrum anthropi. A PCR fragment of 230 bp was obtained using oligonucleotide primers deduced from N-terminal and ‘internal ’ sequences of the purified enzyme. The gene was obtained by screening of a genomic DNA partial library from O. anthropi constructed in pBluescript with a PCR fragment probe. The gene encodes a protein (OaGST) of 201 amino acids with a calculated molecular mass of 21738 Da. The product of the gene was expressed and characterized; it showed GST activity with substrates 1-chloro-2,4-dinitrobenzene (CDNB), p-nitrobenzyl chloride and 4-nitroquinoline 1-oxide, and glutathione-dependent peroxidase activity towards cumene hydroperoxide. The overexpressed product of the gene was also confirmed to have in vivo GST activity towards CDNB. The interaction of the recombinant GST with several antibiotics indicated that the enzyme is involved in the binding of rifamycin and tetracycline. The OaGST amino acid sequence showed the greatest identity (45%) with a GST from Pseudomonas sp. strain LB400. A serine residue in the N-terminal region is conserved in almost all known bacterial GSTs, and it appears to be the counterpart of the catalytic serine residue present in Theta-class GSTs. Substitution of the Ser-11 residue resulted in a mutant OaGST protein lacking CDNB-conjugating activity; moreover the mutant enzyme was not able to bind Sepharose–GSH affinity matrices. The amino acid and nucleotide sequences reported in this paper have been submitted to the EMBL Data Bank with the accession number Y17279.

scholarly journals Site-directed mutagenesis reveals a novel catalytic mechanism of Mycobacterium tuberculosis alkylhydroperoxidase C

2002 ◽  
Vol 367 (1) ◽  
pp. 255-261 ◽  
Author(s):  
Radha CHAUHAN ◽  
Shekhar C. MANDE
Keyword(s):  
Mycobacterium Tuberculosis ◽  
Reaction Mechanism ◽  
Kinetic Parameters ◽  
Active Site ◽  
Double Mutant ◽  
Catalytic Mechanism ◽  
Site Directed Mutagenesis ◽  
Cysteine Residues ◽  
Directed Mutagenesis ◽  
Resistant Strains

Mycobacterium tuberculosis alkylhydroperoxidase C (AhpC) belongs to the peroxiredoxin family, but unusually contains three cysteine residues in its active site. It is overexpressed in isoniazid-resistant strains of M. tuberculosis. We demonstrate that AhpC is capable of acting as a general antioxidant by protecting a range of substrates including supercoiled DNA. Active-site Cys to Ala mutants show that all three cysteine residues are important for activity. Cys-61 plays a central role in activity and Cys-174 also appears to be crucial. Interestingly, the C174A mutant is inactive, but double mutant C174/176A shows significant revertant activity. Kinetic parameters indicate that the C176A mutant is active, although much less efficient. We suggest that M. tuberculosis AhpC therefore belongs to a novel peroxiredoxin family and might follow a unique disulphide-relay reaction mechanism.

scholarly journals Chitin, Chitin Oligosaccharide, and Chitin Disaccharide Metabolism of Escherichia coli Revisited: Reassignment of the Roles of ChiA, ChbR, ChbF, and ChbG

2021 ◽  
pp. 1-17
Author(s):  
Axel Walter ◽  
Simon Friz ◽  
Christoph Mayer
Keyword(s):  
Escherichia Coli ◽  
Catalytic Mechanism ◽  
Phosphotransferase System ◽  
E Coli ◽  
The Family ◽  
Acetyl Group ◽  
Bona Fide ◽  
Modeling Data

<i>Escherichia coli</i> is unable to grow on polymeric and oligomeric chitin, but grows on chitin disaccharide (GlcNAc-GlcNAc; <i>N,N</i>′-diacetylchitobiose) and chitin trisaccharide (GlcNAc-GlcNAc-GlcNAc; <i>N,N</i>′<i>,N</i>′′-triacetylchitotriose) via expression of the <i>chb</i> operon (<i>chbBCARFG</i>). The phosphotransferase system (PTS) transporter ChbBCA facilitates transport of both saccharides across the inner membrane and their concomitant phosphorylation at the non-reducing end, intracellularly yielding GlcNAc 6-phosphate-GlcNAc (GlcNAc6P-GlcNAc) and GlcNAc6P-GlcNAc-GlcNAc, respectively. We revisited the intracellular catabolism of the PTS products, thereby correcting the reported functions of the 6-phospho-glycosidase ChbF, the monodeacetylase ChbG, and the transcriptional regulator ChbR. Intracellular accumulation of glucosamine 6P-GlcNAc (GlcN6P-GlcNAc) and GlcN6P-GlcNAc-GlcNAc in a <i>chbF</i> mutant unraveled a role for ChbG as a monodeacetylase that removes the <i>N-</i>acetyl group at the non-reducing end. Consequently, GlcN6P- but not GlcNAc6P-containing saccharides likely function as coactivators of ChbR. Furthermore, ChbF removed the GlcN6P from the non-reducing terminus of the former saccharides, thereby degrading the inducers of the <i>chb</i> operon and facilitating growth on the saccharides. Consequently, ChbF was unable to hydrolyze GlcNAc6P-residues from the non-reducing end, contrary to previous assumptions but in agreement with structural modeling data and with the unusual catalytic mechanism of the family 4 of glycosidases, to which ChbF belongs. We also refuted the assumption that ChiA is a bifunctional endochitinase/lysozyme ChiA, and show that it is unable to degrade peptidoglycans but acts as a bona fide chitinase in vitro and in vivo, enabling growth of <i>E. coli</i> on chitin oligosaccharides when ectopically expressed. Overall, this study revises our understanding of the chitin, chitin oligosaccharide, and chitin disaccharide metabolism of <i>E. coli</i>.

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