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Naturally-Occurring Fusion Between the Regulatory and Catalytic Components of Type IIP Restriction-Modification SystemsLiang, Jixiao January 2013 (has links)
No description available.
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New Active Site Fold And The Role Of Metal Ions In Structure Function Relationship Of A Promiscuous Endonuclease - R.KpnISaravanan, M 01 1900 (has links)
Bacteria employ survival strategies to protect themselves against foreign invaders, including bacteriophages. The ‘immune system’ of bacteria relies mostly on restriction-modification (R-M) systems. The primary role of R-M systems is to protect the host from invading foreign DNA molecules. Three major types of R–M system are found in bacteria, viz.Types I, II and III. Type II R–M systems comprise a separate restriction endonuclease (REase) and a methyltransferase (MTase) that act independently of each other. Type II REases generally recognize palindromic sequences in DNA and cleave within or near their recognition sequences and produce DNA fragments of defined sizes. They have become indispensable tools in molecular biology and have been widely exploited for studying site-specific protein–DNA interactions. Surprisingly, these enzymes share little or no sequence homology among them, though the three-dimensional structures determined to date reveal a common-core motif (‘PD...D/EXK’ motif) with a central β-sheet that is flanked by α-helices on both sides. In the motif, two acidic residues (D and D/E) are important for the metal ion binding and catalysis.
The work presented in this thesis deals with the determination of active site, elucidation of kinetic mechanism and study of evolution of sequence specificity using the well known, R.KpnI, from Klebsiella pneumoniae. The enzyme is a homodimer, which recognizes a palindromic double stranded DNA sequence, GGTAC↓C, and cleaves as shown. Unlike other REases, R.KpnI shows prolific promiscuous DNA cleavage in presence of Mg2+. Surprisingly, Ca2+ completely suppresses the Mg2+ mediated promiscuous activity and induces high fidelity cleavage at the recognition sequence. These unusual properties of R.KpnI led to the characterization of the active site of the enzyme.
This thesis is divided into five chapters. Chapter 1 is a general introduction of R-M systems and an overview of the literature on active sites of Type II REases. It deals with discovery, nomenclature and classification followed by description of the enzymes diversity and general features of Type II REases. The different active site folds of the REases have been discussed in detail. The features of sequence specificity and the efforts undertaken to engineer the new specificity in the REases have been dealt at the end of the chapter.
Chapter 2 describes identification and characterization of the R.KpnI active site by bioinformatics analyses, homology modeling and mutational studies. Bioinformatics analyses reveal that R.KpnI contains a ββα-Me-finger fold, which is a characteristic of many HNH-superfamily endonucleases. According to the homology model of R.KpnI, the putative active site residues correspond to the conserved residues present in HNH nucleases. Substitutions of these conserved residues in R.KpnI resulted in loss of the DNA cleavage activity, confirming their importance. This study provides the first experimental evidence for a Type IIP REase that is a member of the HNH superfamily and does not belong to the PD...D/EXK superfamily of nucleases.
In Chapter 3 DNA binding and kinetic analysis of R.KpnI is presented. The metal ions which exhibit disparate pattern of DNA cleavage have no role in DNA recognition. The enzyme binds to both canonical and non-canonical DNA with comparable affinity irrespective of the metal ions used. Further, it was shown that Ca2+-imparted exquisite specificity of the enzyme is at the level of DNA cleavage and not at the binding step. The kinetic constants were obtained through steady-state kinetic analysis of R.KpnI in presence of different metal ions. With the canonical oligonucleotides, the cleavage rate of the enzyme was comparable for both Mg2+- and Mn2+-mediated reactions and was about three times slower with Ca2+. The enzyme discriminates non-canonical sequences poorly from the canonical sequence in Mg2+-mediated reactions unlike any other Type II REases, accounting for its promiscuous behavior. These studies suggest that R.KpnI displays properties akin to that of typical Type II REases and also endonucleases with degenerate specificity for DNA recognition and cleavage.
In chapter 4, two uncommon roles for Zn2+ in R.KpnI are described. Examination of the sequence revealed the presence of a zinc finger (CCCH) motif rarely found in proteins of prokaryotic origin. Biophysical experiments and subsequent mutational analysis showed that the zinc binding motif tightly coordinates zinc to provide a rigid structural framework for the enzyme needed for its function. In addition to this structural scaffold, another atom of zinc binds to the active site to induce high fidelity cleavage and suppress the Mg2+- and Mn2+-mediated promiscuous behavior of the enzyme. This is the first demonstration of distinct structural and catalytic roles for zinc in a REase.
Chapter 5 describes generation of highly sequence specific R.KpnI. Towards this end, site-directed mutants were generated at the putative secondary metal binding site. The DNA binding and cleavage analyses of the mutants at putative secondary metal binding site revealed that the secondary site is not important for primary catalysis and have a role in sequence specificity. A single amino acid change at the D163 position abolished the promiscuous activity of the wt enzyme in the presence of Mg2+ and Mn2+. Thus, a single point mutation converts the promiscuous endonuclease to a high fidelity REase.
In conclusion, the work described in the thesis reveals new information on the REases in general and R.KpnI in particular. Many of the properties of R.KpnI elucidated in this thesis represent hitherto unknown features amongst REases. The presence of an HNH catalytic motif in the enzyme indicates the diversity of active site fold in REases and their distinct origin. Similarly, the high degree of promiscuity exhibited by the enzyme may hint at the evolutionary link between non-specific and highly sequence specific nucleases. The present studies also provide an example for the role of mutations in the evolution of sequence specificity. The utilization of different metal ions for DNA cleavage and the architectural role for Zn2+ in maintaining the structural integrity are other unusual properties of the enzyme.
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Epigenetische DNS-Modifikation von Campylobacter coli / Epigenetic DNA modification of Campylobacter coliGoldschmidt, Anne-Marie 20 March 2018 (has links)
No description available.
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Characterization Of HP1369-HP1370 From Helicobacter Pylori : A Novel ε Type N6 –Adenine MethyltransferaseChaudhary, Awanish Kumar 07 1900 (has links) (PDF)
Helicobacter pylori is one of the most genetically diverse bacterial species that successfully colonizes at least 50% of the world population. It has been associated with humans for thousands of years and most probably evolved from ancestral gastric Helicobacter species in early mammals. One of the important characteristics of this pathogen is the degree of allelic diversity and genetic variability which helps it to adapt and colonize. Phase variation is one of the mechanisms used by H. pylori to generate variation. The presence of homopolymeric nucleotide or dinucleotide repeats in an ORF make it prone to frequent length changes as a consequence of slipped strand mispairing mediated mutagenesis.
Interestingly, R-M genes comprise a significant percentage of H. pylori strain-specific genes and are more prevalent in H. pylori than in other bacterial species whose genomes have been fully sequenced. R-M systems in H. pylori have been identified on the basis of sequence similarity to known restriction endonucleases and methyltransferases, genetic organization, and specific enzyme isolation and characterization. Analysis of genome sequences of H. pylori strains 26695, J99, HPAGI and 26 others has revealed the presence of more than 20 R-M systems in each stain, which are far more than detected in any other bacterial genome sequence till date.
hp1369 and hp1370 are two ORFs in stain 26695 coding for hypothetical proteins. hp 1369 has a stretch of poly-G repeats, thus making hp1369-hp1370, a candidate of phase variation. hpag1_1313 is homolog of hp1369-hp1370 which got up-regulated, in a person suffering from acute gastritis, thus making these genes an interesting subject of investigation.
This study was therefore initiated with the following objectives:
1. Cloning, over-expression and purification of Type III MTase (ORF- hp1369- hp1370) and its cognate restriction enzyme (hp1371).
2. Biochemical characterization of MTase (HP1369-HP1370): Determination of oligomeric status, kinetic properties, binding affinities for AdoMet and DNA.
Sequence analysis shows the presence of a poly-G track (10 Gs) at 3’-end of hp1369 which is a signature sequence for phase variation. Addition of a single nucleotide can place both hp1369 and hp1370 in-frame, which could code for a single polypeptide. hp1369 and hp1370 in H. pylori strain 26695 alone do not code for any functional protein but with the fusion of hp1369 and hp1370 can code for a protein with all the nine motifs of a DNA MTase. Interestingly, on the basis of arrangement of Motifs, it is probably the first example of ε type of methyltransferase. By site-directed mutagenesis a single G nucleotide was inserted in the poly-G track and both the ORFs (hp1369 and hp1370 ) became in-frame, coding for fully functional HP1369-HP1370 MTase. Kinetic parameters for functional HP1369-HP1370 MTase were determined, and has shown that there was substrate inhibition in methylation reaction at higher concentrations of AdoMets. When preincubation studies were done, enzyme-DNA complex was found to be more competent than enzyme-AdoMet complex. HP1369-HP1370 MTase exists as dimer in solution, having affinity for duplex DNA and does not bind to single-stranded DNA. Binding affinity for ligand (AdoMet) was determined by Isothermal Titration Calorimetry method.
H. pylori has evolving restriction-modification systems. It is capable of taking new R-M systems from the environment in the form of DNA released from other bacteria or other Helicobacter strains. H. pylori genome is dynamic with high mutation rates. Random mutations in R-M genes can result in a non-functional R-M systems or R-M systems with new properties. The dynamics of R-M system plays a vital role in shaping up the genome.
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