Global ETD Search

31	The Biochemical Reactions Of Dry State Dna Marrone, April 01 January 2009 (has links) The biochemistry of dry state DNA is of interest to the fields of forensics, ancient DNA, and DNA storage. The exact chemical nature of the degradation of the DNA molecule in the dry state has not been studied prior. If determined what chemical changes the DNA molecule undergoes, to what degree and in what time frame then protocols can be implemented to bypass the impact of this damage or to repair it when necessary. It is suspected that similar reactions occur to the dry state DNA molecule as does to the hydrated molecule. It cannot be assumed, however that these types of chemical processes occur to the same extent and at the same rates. In general the generic process of hydrolysis encompasses two important reactions, that of deamination and of base loss from the 2’-deoxyribose backbone. Base loss is believed to ultimately lead to chain scission. It is also suspect that reactive oxygen species (ROS) have an important role in the chemistry associated with DNA. Species such as hydroxyl radicals (OH•) and singlet oxygen (1O2) can lead to strand scissions and chemically modified bases. Throughout this project various techniques were used to determine damage to DNA and its molecular constituents under conditions leading to hydrolytic and oxidative damage. Novel techniques used in this study include ionpairing chromatography and denaturing HPLC (DHPLC) to measure glycosidic bond cleavage and strand breaks. The extent to which the macromolecule haemoglobin (Hb) can lead to oxidative damage of DNA in dried blood stains by acting as a Fenton chemistry catalyst was evaluated. Additionally the enzymatic activity of the extracellular nuclease from Alteromonas espejiana, BAL 31 was studied as it pertains to the degradation of single-stranded short homopolymeric oligonucleotides. This study serves as the basis for future, more in depth experimentation into the more specific nature of dry state DNA biochemistry. It was found that to a large extent the same degradation reactions (base hydrolysis, base modifications, and strand breaks) do occur in the dry state as in the hydrated state when heat and UV radiation are used as energy sources. Reaction rates indicate that base hydrolysis and deamination occur much more slowly, yet have the same energies of activation in both states. Single strand breaks of dry state duplex DNA occur with a half life of 24 ± 2 days and appears to occur in a mechanistic manner which could be of interest when attempting to repair such damage. In addition, base loss alone does not correlate with the extent of single strand breaks detected. Thermodynamic data can lead to the conclusion that DNA degradation in both dry and hydrated states is not a spontaneous process. It is also concluded that though the Hb molecule undergoes oxidative changes over time, these changes do not impact its ability to become a more aggressive Fenton reagent. However, the presence of Hb in the vicinity of DNA does create the opportunity for OH•induced damage to the deoxyribose sugar, and most likely the DNA bases themselves. This study also reveals that the general purpose BAL 31 nuclease commonly used in molecular genetics exhibits a hithertofore non-characterized degree of substrate specificity with respect to single-stranded DNA oligomers. Specifically, BAL 31 nuclease activity was found to be affected by the presence of guanine in ssDNA oligomers. hydrolysis of DNA depurination dry state DNA BAL 31 nuclease hemeglobin oxidation Chemistry
32	RNA interference by single- and double-stranded siRNA with a DNA extension containing a 3' nuclease-resistant mini-hairpin structure Allison, Simon J., Milner, J. 06 November 2013 (has links) Yes / Selective gene silencing by RNA interference (RNAi) involves double-stranded small interfering RNA (ds siRNA) composed of single-stranded (ss) guide and passenger RNAs. siRNA is recognized and processed by Ago2 and C3PO, endonucleases of the RNA-induced silencing complex (RISC). RISC cleaves passenger RNA, exposing the guide RNA for base-pairing with its homologous mRNA target. Remarkably, the 3′ end of passenger RNA can accommodate a DNA extension of 19-nucleotides without loss of RNAi function. This construct is termed passenger-3′-DNA/ds siRNA and includes a 3′-nuclease-resistant mini-hairpin structure. To test this novel modification further, we have now compared the following constructs: (I) guide-3′-DNA/ds siRNA, (II) passenger-3′-DNA/ds siRNA, (III) guide-3′-DNA/ss siRNA, and (IV) passenger-3′-DNA/ss siRNA. The RNAi target was SIRT1, a cancer-specific survival factor. Constructs I–III each induced selective knock-down of SIRT1 mRNA and protein in both noncancer and cancer cells, accompanied by apoptotic cell death in the cancer cells. Construct IV, which lacks the SIRT1 guide strand, had no effect. Importantly, the 3′-DNA mini-hairpin conferred nuclease resistance to constructs I and II. Resistance required the double-stranded RNA structure since single-stranded guide-3′-DNA/ss siRNA (construct III) was susceptible to serum nucleases with associated loss of RNAi activity. The potential applications of 3′-DNA/siRNA constructs are discussed.
33	A Novel RNA Virus Detection System Based on Duplex Specific Nuclease RAVI, RANJANI January 2014 (has links) No description available. Virology norovirus duplex specific nuclease isothermal RT-PCR RNA virus cost effective
34	Functional studies of the interstrand cross-link repair protein, SNM1A and its beta-CASP domain Buzon, Beverlee D. 10 1900 (has links) <p>Interstrand cross-linking (ICL) damage to DNA is cytotoxic as it blocks replication and transcription. This cytotoxicity is exploited in anti-cancer therapies, but increased ICL repair limits the efficacy of these chemotherapies. SNM1A (sensitive to nitrogen mustard 1A), of the beta-CASP family of nucleases, has been shown to participate in the initiation of one of the ICL repair processes. Biochemical studies of SNM1A have been limited due to insolubility and instability of SNM1A in bacteria and insect cell lines and toxicity in human cell lines. Work reported in this thesis describes a novel and efficient method of generating active protein from inclusion body expression of the beta-CASP domain of SNM1A. This refolded beta-CASP domain shows 5’ exonuclease activity on single stranded and double stranded DNA in vitro. Nevertheless, this domain alone is unable to complement <em>pso2</em> null ICL repair defects in<em> S. cerevisiae</em> after exposure to ICL agents. These functional studies of the beta-CASP domain of SNM1A will be helpful in directing future research on its role in ICL repair. Additionally, this will aid future structural and inhibitor studies of this essential interstrand cross-link repair protein, SNM1A.</p> / Master of Science (MSc) SNM1A interstrand crosslink repair beta-CASP inclusion body protein refolding nuclease cisplatin Biochemistry Biochemistry
35	Biochemical properties and substrate reactivities of Aquifex Aeolicus Ribonuclease III Shi, Zhongjie January 2012 (has links) Ribonuclease III is a highly-conserved bacterial enzyme that cleaves double-stranded (ds) RNA structures, and participates in diverse RNA maturation and decay pathways. Essential insight on the RNase III mechanism of dsRNA cleavage has been provided by crystallographic studies of the enzyme from the hyperthermophilic bacterium, Aquifex aeolicus. However, those crystals involved complexes containing either cleaved RNA, or a mutant RNase III that is catalytically inactive. In addition, neither the biochemical properties of A. aeolicus (Aa)-RNase III, nor the reactivity epitopes of its cognate substrates are known. The goal of this project is to use Aa-RNase III, for which there is atomic-level structural information, to determine how RNase III recognizes its substrates and selects the target site. I first purified recombinant Aa-RNase III and defined the conditions that support its optimal in vitro catalytic activity. The catalytic activity of purified recombinant Aa-RNase III exhibits a temperature optimum of 70-85°C, a pH optimum of 8.0, and with either Mg2+ or Mn2+ supports efficient catalysis. Cognate substrates for Aa-RNase III were identified and their reactivity epitopes were characterized, including the specific bp sequence elements that determine processing reactivity and selectivity. Small RNA hairpins, based on the double-stranded structures associated with the Aquifex 16S and 23S rRNA precursors, are cleaved in vitro at sites that are consistent with production of the immediate precursors to the mature rRNAs. Third, the role of the dsRBD in scissile bond selection was examined by a mutational analysis of the conserved interactions of RNA binding motif 1 (RBM1) with the substrate proximal box (pb). The individual contributions towards substrate recognition were determined for conserved amino acid side chains in the RBM1. It also was shown that the dsRBD plays key dual roles in both binding energy and selectivity, through RBM1 responsiveness to proximal box bp sequence. The dsRBD is specifically responsive to an antideterminant (AD) bp in pb position 2. The relative structural rigidity of both dsRNA and dsRBD rationalizes the strong effect of an inhibitory bp at pb position 2: disruption of one RBM1 side chain interaction can effectively disrupt the other RBM1 side chain interactions. Finally, a cis-acting model was developed for subunit involvement in substrate recognition by RNase III. Structurally asymmetric mutant heterodimers of Escherichia coli (Ec)-RNase III were constructed, and asymmetric substrates were employed to reveal how RNase III can bind and deliver hairpin substrates to the active site cleft in a pathway that requires specific binding configurations of both enzyme and substrate. / Chemistry Biochemistry Aquifex Aeolicus Dsrna-binding Domain Nuclease Domain Proximal Box Ribonuclease Iii Rna Binding Motif
36	Optimizing the large-scale production of Saw1 and the Saw1-Rad1-Rad10 nuclease complex for structural studies Rashev, Margarita January 2017 (has links) Yeast Rad1-Rad10 is a structure specific nuclease that processes branched double-strand break (DSB) repair intermediates; the persistence of which can impede normal DNA metabolism. The single strand annealing (SSA) mechanism of DSB repair acts when homologous repeats flank both sides of the DSB. End resection from the 5′ ends of the break exposes complementary sequences at the flanking repeats, which are annealed to form 3′ non-homologous flap structures. Saw1 recruits Rad1-Rad10 recruits to these 3′ non-homologous flaps, where Rad1-Rad10 incises the DNA and removes the flap. Saw1 has affinity towards branched DNA structures and forms a stable complex with Rad1-Rad10. The mechanism of both structure specific recruitment and nucleolytic activity of the Saw1-Rad1-Rad10 complex is currently unknown. To study this nuclease complex, we need to produce large quantities of pure, stable, and active recombinant protein. Using dynamic light scattering (DLS) and differential scanning fluorimetry (DSF)-based high throughput thermal stability assays, we have developed a method for large-scale production of recombinant Saw1. This optimized method has increased the stability and yield of protein, thereby allowing for future biochemical investigation of Saw1. Similarly, we have optimized the large-scale production of the higher molecular-weight complex (Saw1-Rad1-Rad10) and improved the homogeneity of the recombinant complex. We have also biochemically characterized the minimal branched DNA substrates for both Saw1 and Saw1-Rad1-Rad10. This work allows for biochemical investigation into the molecular mechanism of eukaryotic 3′ non-homologous flap removal during SSA. / Thesis / Master of Science (MSc) DNA repair Single strand annealing structure selective nuclease
37	Engineered genetic sterility of pest insects Bilski, Michal Mamert January 2012 (has links) In the light of increasing pesticides resistance in agricultural pests and in insect vectors of human diseases, leading to the rise in occurrence of mosquito-borne diseases, new, efficient and environmentally friendly methods of pest control are needed. Sterile Insect Technique (SIT), relying on mass releases of radiation sterilised males to reduce reproductive potential of target pest populations, although not new, offers an alternative to the use of pesticides and is an environmentally non-polluting method of insect control. Many insect species, however, are not very amenable to classical SIT, due to detrimental side-effects of radiation treatment. We propose a new method, a genetically engineered modification of classical SIT, replacing radiation with genetically induced sterility. Based on conditional expression of male-germline targeted nucleases which introduce double strand breaks into the male germline DNA to render males sterile, this method emulates SIT mechanism, at the same time eliminating radiation and associated detrimental side-effects. Different variants of such a system were investigated in this project, eventually leading to the creation of functional conditional male-sterility systems in two model organisms – the Yellow fever mosquito, Aedes aegypti and the Mediterranean fruit fly, Ceratitis capitata. Both systems utilise chimeric nuclease composed of protamine and FokI cleavage domain fusion. The sperm-specificity and the conditionality of the sterile phenotype have been achieved through the use of tetracycline repressible expression system driven by the β2-tubulin promoter in Ceratitis capitata and by the Topi promoter in Aedes aegypti. 595.7
38	Anti-Cytomegalovirus Activity of Atanyl Blue PRL, an Anthraquinone Derivative Alam, Zohaib 29 July 2013 (has links) Cytomegalovirus (CMV) is a significant cause of mortality and morbidity in immunocompromised patients and an important cause of birth defects if acquired in utero. The licensed CMV antivirals, ganciclovir, cidofovir and foscarnet, all target the viral DNA polymerase. For each drug prolonged use is associated with significant toxicities and development of drug resistance. None are approved for use during pregnancy. Therefore, development of new anti-CMV drugs that target different pathways would be beneficial. All herpesviruses encode an alkaline nuclease. That genetic disruption of the CMV alkaline nuclease, UL98, reduces CMV replication by 1,000-fold suggests that UL98 may be a useful target for development of novel anti-CMV drugs. Moreover, using herpes simplex virus type 1 Hsiang and Ho found that the anthraquinone emodin inhibits activity of the viral alkaline nuclease, blocks viral replication in cell culture, and reduces viral pathogeneses in a mouse model (Brit. J. of Pharm., 2008). Earlier studies also showed that anthraquinone derivatives including emodin have anti-CMV activity (Barnard et al., Antiviral Research 1992 & 1995), although the mechanism of CMV inhibition has not been further studied. We therefore sought to confirm the anti-CMV activities of emodin and related anthraquinone derivatives, to characterize their mechanisms of action, and to determine specifically if they act through inhibition of UL98. Using a luciferase-based CMV yield reduction assay emodin inhibited CMV replication (IC50 = 4.9 μM); however, that the TD50 for cytotoxicity (determined using an luciferase-based cell viability assay) was only 2-fold higher suggested that emodin may act non-specifically. Two additional anthraquinone derivatives (acid blue 40 and alizarin violet R) inhibited CMV only at high concentrations (IC50 = 238; 265 μM) that were also cytotoxic. Atanyl blue PRL, however, exhibited anti-CMV activity (IC50 = 6.3 μM) with low cytotoxicity (TD50 = 216 μM). Thus, characterization of atanyl blue PRL (impact on gene expression, GFP expression, viral spread, infectivity, time of addition studies, and inhibition of UL98 nuclease activity) should be informative. Atanyl blue PRL appears to block immediate-early gene expression and reduce early and late gene expression. Atanyl blue PRL also blocked GFP expression, reduced viral spread, and also lowered the infectivity of CMV. Finally, atanyl blue PRL inhibits UL98 alkaline nuclease activity at an IC50 of 5.7 μM. This suggests that atanyl blue PRL may inhibit CMV through inhibition of UL98. Thus, atanyl blue PRL represents a novel class of anti-herpesvirals and provides a lead structure for structure based drug discovery. acid blue 129 atanyl blue PRL CMV cytomegalovirus UL98 alkaline nuclease anthraquinone congenital infection HCMV UL54 UL97 Medicine and Health Sciences
39	Mechanisms and regulation of dsDNA break repair in the Sulfolobus genus of thermophilic archaea Bray, Sian Marian January 2019 (has links) DNA is constantly subjected to chemical and mechanical damage. The ability to repair the lesions sustained is essential for all life. Double stranded DNA (dsDNA) breaks are especially toxic as both antiparallel strands of DNA are severed. The most high fidelity mechanism available to repair this damage is homologous recombination, a mechanism that uses homology from the sister chromatid to replace any lost information. Key proteins involved in maintaining genomic stability this way are conserved in all domains of life. One such component is the Mre11/Rad50 complex that is involved in the initial recognition of damage and recruitment of subsequent repair factors. Understanding the function of this DNA repair complex and any associated proteins has implications for human cancers and aging. The proteins of thermophilic archaea present an excellent opportunity to study these systems in a robust, tractable and eukaryote-like system. Archaea are in many ways biochemically unique, for example they are the only domain capable of methanogenesis. However archaea share a high level of homology with eukaryotes in many essential cellular processes such as DNA replication, homologous recombination and protein degradation. In thermophilic archaea the mre11/rad50 genes are clustered in an operon with the herA/nurA genes that form a helicase/nuclease complex. This has lead to speculation that the four proteins work together during homologous recombination to produce the 3' overhangs required by RadA to identify homology. As part of this investigation I have performed extensive bioinformatic searches of a variety of archaeal/bacterial systems. These analyses have revealed operonic linkages to other known recombinational helicase/nucleases, such as AddAB and RecBCD. These genomic linkages are especially prevalent in thermophilic organisms suggesting their functional relevance is particularly acute in organisms exposed to a high amount of genomic stress. Comparison of the evolutionary trees, constructed for each protein, makes a single genomic linkage event the most likely scenario, but cannot definitively exclude other possibilities. Exhaustive attempts were made to demonstrate an interaction between Mre11/Rad50 and HerA/NurA. Despite analysis by nickel/cobalt pulldown, immunoprecipitation, analytical gel filtration, ITC and OCTET an interaction could not be confirmed or definitively dismissed. However in the process an interesting Rad50 tetrameric assembly was identified and attempts were made to crystalize it. Hexameric helicases and translocases are key to the replication and DNA packaging of all cellular life and multiple viruses. The hexameric translocase HerA is a robust model for investigating the common features of multimeric ATPases as it is extremely stable and experimentally tractable. Here it is revealed that HerA exists in a dynamic equilibrium fluctuating between hexameric and heptameric forms with rapidly interchanging subunits. This equilibrium can be shifted to heptamer by buffering conditions or towards the hexamer by the physical interaction with the partnering nuclease NurA, raising the possibility that these alternate states may play a role in translocase assembly or function. A novel C-terminal brace, (revealed by a collaborative crystallographic structure) is investigated; as well as stabilizing the assembly, this brace reaches over the ATPase active site of its neighbouring subunit. It is seemingly involved in the conversion of energy generated by ATP hydrolysis into physical movement in the central channel of the hexamer. The regulation of homologous recombination is extremely important to prevent aberrant activity, resulting in mutations and genome reorganization. In eukaryotic organisms, it is well established that post-translational modifications and protein turnover at the proteosome play important roles in this control. In particular, there is significant interest currently in the ubiquination-proteasome destruction pathway as a mechanism for extracting DNA repair components from chromatin at the termination of the DNA repair process. To date no Ubiquitin proteins have been identified in the Archaea, however related proteins URMs/SAMPs (Ubiquitin Related Modifier/Small Archaeal Modifier Protein) have previously been identified. URMs are thought to have evolved from a common antecedent to eukaryotic ubiquitin and likely represent an evolutionary 'missing link' in the adaption of sulphur transfer proteins for covalent modifications. There has been speculation that Urm1 may play a similar role to ubiquitin in the proteasome degradation pathway and we have recently provided evidence to corroborate this. Here the potential for modification of Mre11/Rad50/HerA/NurA by Urm1 was investigated. Indeed Rad50 shows evidence of clear urmylation both in vivo and in vitro. Western blotting and mass spec analysis confirmed the covalent attachment of Urm1 to Rad50. Furthermore I present preliminary evidence that this urmylation can lead to the destruction of Rad50 via a direct physical interaction with the proteasome. This is the first evidence of such a regulatory system for Rad50. Investigating the urmylation and destruction of Rad50 was closely linked to investigating the archaeal proteasome, a close homologue of the eukaryotic proteasome. To date the majority of archaeal core proteasomes examined were believed to consist of only two subunits; alpha and beta. The subunits are arranged into heptameric rings, which then form an alpha/beta/beta/alpha stack with a single channel running through the centre of all four rings. Here we reveal that in Sulfolobus species the inner catalytic chambers are made up of mixed beta rings composed of two subunits. The first plays a crucial structural role but appears catalytically inert, while the second conveys catalytic activity. Here we investigate an inactive complex, containing only the structural beta subunit, and an active complex, containing both beta subunits. First, electron microscopy was performed on both complexes revealing the expected four-layered toroidal stack. Both complexes were subsequently investigated crystallographically. A 3.8 Å structure was determined for the inactive complex. As well as being one of the few archaeal core proteasome structures, this is also an important first step towards structurally investigating the novel three-subunit proteasome. The discovery of active and inactive beta subunits in the archaea brings them even closer to eukaryotic proteasomal systems, making the archaea even more valuable as model systems.
40	New Active Site Fold And The Role Of Metal Ions In Structure Function Relationship Of A Promiscuous Endonuclease - R.KpnI Saravanan, 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. Trace Elements Promiscuous Endonuclease Restriction-Modification Systems Restriction Endonuclease R.KpnI Restriction Endonuclease R.Kpnl - Kinetic Analysis HNH Nuclease Superfamily Molecular Biology

Search results