Evolutionary Design Of Active Site Plasticity In R.KpnI For Promiscuity In Metal Ion Utilization And Substrate Recognition

Kommireddy, Vasu

07 1900

Restriction modification (R-M) systems are important components of the prokaryotic arsenal against invading genomes. R-M systems directly target the foreign DNA and are often considered as primitive immune systems in bacteria. The defense system comprises of two contrasting enzymatic activities – a restriction endonuclease (REase) and a methyltransferase (MTase). Functionally, REases cleave a specific DNA sequence endonucleolytically at the phosphodiester bonds generating 5' or 3' overhangs or blunt ends. MTases catalyze the transfer of a methyl group from S-adenosyl-Lmethionine to adenine or cytosine. Four types of R–M systems are found in bacteria, viz., Types I, II, III and IV. Type II R-M systems, comprising of a separate REase and MTase, are the most abundant and well-studied enzymes. Type II REases recognize and cleave DNA within or near their recognition sequences. Surprisingly, these enzymes share little or no sequence homology amongst them. All the enzymes identified so far can be grouped into conventional PD-(D/E)XK, ββα-Me, GIY-YIG, phospholipase-derived and half-pipe endonucleases according to their folds and active site structures. Owing to their high specificity and defined cleavage pattern, they have become indispensable tools in molecular biology and have been widely exploited for studying protein–DNA interactions. The work presented in this thesis deals with R.KpnI, which belongs to the HNH superfamily of nucleases and is characterized by the presence of a ββα-Me finger motif. The REase isolated from Klebsiella pneumoniae recognizes the palindromic DNA sequence GGTAC/C and cleaves DNA as indicated. The enzyme is unique in exhibiting promiscuous DNA cleavage in the presence of Mg2+, a natural co-factor for a vast majority of REases. Surprisingly, Ca2+ and Zn2+ completely suppress the Mg2+ mediated promiscuous activity and induce high fidelity cleavage. These unusual features of R.KpnI led to the functional characterization of the ββα-Me finger active site motif. In addition, the studies were aimed at understanding the mechanism and the biological significance of substrate and co-factor promiscuity exhibited by the enzyme. The salient aspects of the thesis are summarized below. A general introduction and overview of the literature on structure-function studies, mechanism of recognition and catalysis by REases with special emphasis on Type II enzymes is presented in the Chapter 1. An account of co-factor specificity in REases, role of metal ions in DNA binding as well as in phosphodiester bond hydrolysis is provided. The various aspects of R-M systems that target the invading DNA elements and counter strategies employed by the foreign genomes to evade the restriction are also covered. The new developments that provide insights in understanding the diversity of R-M systems and additional biological roles that could increase the fitness of the host organism harboring them are described. The features of substrate and metal ion specificity in REases and the efforts undertaken to alter the specificity have been dealt at the end of the chapter. From the structures of the several ββα-Me finger nucleases, the α-helix has been implicated in providing a structural scaffold for the correct juxtapositioning of the catalytic residues. However, no mutagenesis data exists to delineate its role. Homology modeling studies of R.KpnI suggested a crossover structure for the α-helix of the ββαMe finger active site motif, which could possibly form dimeric interface and/or structural scaffold for the active site. Chapter 2 describes the computational modeling and mutational analysis performed to understand the role of the residues present in this α-helix in intersubunit interactions and/or stabilization of the active site. Mutation of the residues present in the α-helix lead to the loss of the enzyme activity, but not dimerization ability. Subsequent biophysical experiments showed that the α-helix of the ββα-Me finger of R.KpnI plays an important role for the stability of the protein–DNA complex needed for its function. In Chapter 3, unusual co-factor flexibility for R.KpnI is shown by using a battery of divalent metal co-factors differing in ionic radii and coordination geometries. A number of alkaline earth and transition group metal ions function as co-factors for DNA cleavage. The metal ions replaced each other readily from the enzyme’s active site revealing the active site plasticity. Mutation of the invariant His residue of the HNH motif caused abolition of the enzyme activity with all the co-factors indicating that the enzyme follows single metal ion mechanism for DNA cleavage. The indispensability of the invariant His in nucleophile activation together with the broad co-factor tolerance of the enzyme indicated the role of metal ions in electrostatic stabilization during catalysis. At higher concentrations, Mg2+, Mn2+ or Co2+ stimulate promiscuous cleavage while Cd2+, Ni2+ or Zn2+ inhibit phosphodiester bond hydrolysis. The underlying molecular mechanisms for the modulation of the enzyme activity by the metal ion binding to the second site are presented. Regulation of the endonuclease activity and fidelity by a second metal ion binding is a unique feature of R.KpnI among REases and HNH nucleases. The identification of additional metal ion binding residues would help in engineering REase variants with enhanced activity and/or specificity. Chapter 4 describes the generation of an R.KpnI variant with altered co-factor specificity by exploiting the active site plasticity of the enzyme. The mutant enzyme is a Mn2+ -dependent endonuclease defective in DNA cleavage with Mg2+ and other divalent metal ions. In the engineered mutant, only Mn2+ is selectively bound at the active site, imparting in vitro activity while being dormant in vivo. In addition to the Mn2+ selectivity, the mutant is impaired in concerted double-stranded DNA cleavage leading to the accumulation of nicked intermediates. The nicking activity of the mutant enzyme is further enhanced by altering the reaction conditions. Thus, a single point mutation in the active site of R.KpnI generates a Mn2+ -dependent REase and a sequence specific nicking endonuclease. The potential applications of such enzymes engineered for selective metal ion dependent activities have been discussed. R.KpnI is peculiar in retaining robust promiscuous cleavage despite being a typical Type II REase in all other characteristics. Chapter 5 presents results of the growth properties and phage titer analysis carried out with R.KpnI and its high fidelity variant to understand the biological significance of promiscuous activity. The enzyme isolated from the K. pneumoniae exhibited biochemical properties similar to that of R.KpnI overexpressed in E.coli. It was observed that the wild type but not the high fidelity variant could effectively restrict bacteriophages methylated at GGTACC. These results show that the REase exhibits promiscuous activity in vivo, which would be advantageous for the organism to better target the incoming foreign DNA. The promiscuous behavior of the R.KpnI could be one of the counter strategies employed by the bacteria against the constantly evolving phages in the co-evolutionary arms race. In conclusion, the work described in this thesis provides new insights about structure, function and biology of REases in general and R.KpnI in particular. The co-factor and substrate promiscuity of R.KpnI may indicate its evolutionarily intermediate form that is yet to attain a high degree of specificity. Alternatively, it is possible that this unique feature is retained during the evolution of the HNH REases serving some unknown function(s) in the cell, in addition to having an edge in countering the phage infections.

R.KpnI Enzyme

Plasticity

Metal-ion Base

REases

Restriction Endonuclease

R.KpnI

DNA Cleavage

Restriction Modification System

R-M Systems

Cell Biology

Vývoj testovací metody pro identifikaci inhibitorů chřipkové polymerasy / Development of high-throughput screening assay for the identification of inhibitors targeting influenza A polymerase

Karlukova, Elena

January 2018

Influenza virus A circulates in birds and mammals and causes severe infectious disease that affects from 3 to 5 million people each year. There are two classes of anti-influenza drugs currently available: neuraminidase and M2 channel inhibitors. However, increasing resistance against these two types of inhibitors along with the potential emergence of new viral strains and unpredictability of pandemic outbreaks emphasize an unmet need for new types of inhibitors. RNA-dependent influenza polymerase serves as a novel promising target for the development of anti-influenza medications. The aim of this master thesis is to develop in vitro high-throughput assays for screening of compounds targeting influenza RNA polymerase, particularly, its cap binding and endonuclease domains. For cap-binding domain the screening is based on DIANA (DNA-linked Inhibitor ANtibody Assay) method that was recently developed in our laboratory; for endonuclease domain, the method is based on AlphaScreen technology. For the purposes of the methods development, recombinant cap binding domain of PB2 subunit and N-terminal endonuclease domain of PA subunit of influenza polymerase were expressed with appropriate fusion tags and purified using affinity and gel permeation chromatography. The probes for the screening assays were...

DEVELOPMENT OF AN ASSAY TO IDENTIFY AND QUANTIFY ENDONUCLEASE ACTIVITY

Michael A Mechikoff (8088809)

06 December 2019

<p>Synthetic biology reprograms organisms to perform non-native functions for beneficial reasons. An important practice in synthetic biology is the ability to edit DNA to change a base pair, disrupt a gene, or insert a new DNA sequence. DNA edits are commonly made with the help of homologous recombination, which inserts new DNA flanked by sequences homologous to the target region. To increase homologous recombination efficiency, a double stranded break is needed in the middle of the target sequence. Common methods to induce double stranded breaks use nucleases, enzymes that cleave ribonucleotides (DNA and RNA). The most common nucleases are restriction enzymes, which recognize a short, fixed, palindromic DNA sequence (4-8 base pairs). Because of the short and fixed nature of the recognition sites, restriction enzymes do not make good candidates to edit large chromosomal DNA. Alternatively, scientists have turned to programmable endonucleases which recognize user-defined DNA sequences, often times much larger than the recognition sites of restriction enzymes (15-25 base pairs). Programmable endonucleases such as CRISPR-based systems and prokaryotic Argonautes are found throughout the prokaryotic kingdom and may differ significantly in activity and specificity. To compare activity levels among endonuclease enzymes, activity assays are needed. These assays must clearly delineate dynamic activity levels of different endonucleases and work with a wide variety of enzymes. Ideally, the activity assay will also function as a positive selection screen, allowing modifications to the enzymes via directed evolution. Here, we develop an <i>in vivo</i> assay for programmable endonuclease activity that can also serve as a positive selection screen using two plasmids, a lethal plasmid to cause cell death and a rescue plasmid to rescue cell growth. The lethal plasmid houses the homing endonuclease, I-SceI, which causes a deadly double-stranded break at an 18 base pair sequence inserted into an engineered <i>E. coli</i> genome. The rescue plasmid encodes for a chosen endonuclease designed to target and cleave the lethal plasmid, thereby preventing cell death. With this, cell growth is directly linked to programmable endonuclease activity. Three endonucleases were tested, SpCas9, eSpCas9, and xCas9, displaying recovered growth of 49.3%, 26.1%, and 16.4% respectively. These values translate to kinetic enzymatic activity and are congruent with current literature findings as reported values find WT-SpCas9 to have the fastest kinetics cleaving around 95% of substrate within 15 seconds, followed closely by eSpCas9 cleaving 75% of substrate within 15 seconds and finally trailed by xCas9 cleaving 20% of substrate in about 30 seconds. The differences between each endonuclease’s activity is exacerbated in our <i>in vivo</i> system when compared to similar <i>in vitro</i> methods with much lower resolution. Therefore, slight differences in activity between endonucleases within the first few minutes in an <i>in vitro</i> assay may be a few percentages different whereas in our <i>in vivo</i> assay, these differences in activity result in a more amplified signal. With the ability to display the dynamic response of enzymes, this assay can be used to compare activity levels between endonucleases, give insight into their kinetics, and serve as a positive selection screen for use in directed evolution applications. </p>

Genetic Engineering

Endonuclease

genetics

positive selection screen

selection system

directed evolution

engineering

biology

synthetic biology

DNA

assay

activity

Fast photochemical oxidation of proteins coupled to mass spectrometry reveals conformational states of apurinic/apyrimidic endonuclease 1

Hernandez Quiñones, Denisse Berenice

08 July 2015

Indiana University-Purdue University Indianapolis (IUPUI) / Fast photochemical oxidation of proteins (FPOP) is an emerging footprinting method that utilizes hydroxyl radicals. The use of hydroxyl radicals create stable labeled products that can be analyzed with mass spectrometry. The advantage of FPOP over other methods is the fast acquisition of results and the small amount of sample required for analysis. Protein structure and protein- ligand interactions have been studied with FPOP. Here we evaluated (1) the reproducibility of FPOP, (2) the effect of hydrogen peroxide concentration on oxidation and (3) the use of FPOP to evaluate protein- nucleic acid interaction with Apurinic/Apurinic endonuclease 1 (APE1) protein. APE1 is a pleotropic protein that has been crystallized and studied widely. The 35641.5 Da protein has two major functional activities: DNA repair and redox function. An intact protein study of APE1 showed consistent global labeling by FPOP and a correlation between oxidation and hydrogen peroxide concentration. Furthermore, analysis of APE1 with DNA was done in hopes of probing the DNA binding site. Although the oxidation observed was not sufficient to define the complex pocket, a dramatic effect was seen in residue oxidation when DNA was added. Interestingly, the internal residues were labeled collectively in all APE1 experiments which indicates partial unfolding of the protein as previously suggested in the literature. Hence, these findings establish the use of FPOP to capture protein dynamics and provide evidence of the existence breathing dynamics of APE1.

Fast photochemical oxidation

APE1

Apurinic/apyrimidic endonuclease 1

Hydroxyl group

Radicals (Chemistry)

Mass spectrometry

Chemistry, Analytic

Proteins -- Oxidation

Proteins

Local chromosome context is a major determinant of crossover pathway biochemistry during budding yeast meiosis

Medhi, D., Goldman, Alastair S.H., Lichten, M.

01 October 2019

Yes / Abstract The budding yeast genome contains regions where meiotic recombination initiates more frequently than in others. This pattern parallels enrichment for the meiotic chromosome axis proteins Hop1 and Red1. These proteins are important for Spo11-catalyzed double strand break formation; their contribution to crossover recombination remains undefined. Using the sequence-specific VMA1-derived endonuclease (VDE) to initiate recombination in meiosis, we show that chromosome structure influences the choice of proteins that resolve recombination intermediates to form crossovers. At a Hop1-enriched locus, most VDE-initiated crossovers, like most Spo11-initiated crossovers, required the meiosis-specific MutLγ resolvase. In contrast, at a locus with lower Hop1 occupancy, most VDE-initiated crossovers were MutLγ-independent. In pch2 mutants, the two loci displayed similar Hop1 occupancy levels, and VDE-induced crossovers were similarly MutLγ-dependent. We suggest that meiotic and mitotic recombination pathways coexist within meiotic cells, and that features of meiotic chromosome structure determine whether one or the other predominates in different regions.

Holliday junction resolvase

S. cerevisiae

VMA1-derived endonuclease

Chromosome structure

Chromosomes

Genes

Homologous recombination mechanisms

Meiotic chromosome axis

Characterization and inhibition of interstrand crosslink repair nuclease SNM1A

Buzon, Beverly Diana

January 2018

Interstrand cross-links (ICLs) are a type of DNA damage that prevents strand separation required for basic cellular processes. ICL-based anti-cancer therapies exploit the cytotoxic consequences of replication and transcription inhibition, however, they are limited by the ability of the cell to repair DNA crosslinks. The challenge of ICL repair involves coordinating multiple DNA repair pathways to remove damage occurring on both strands of DNA. Participation of factors that are both exclusive and essential to crosslink repair suggests a pathway requirement to process unique structures and/or intermediates arising only in ICL repair. SNM1A is a nuclease required for survival of human cells in response to ICL exposure, but the specific function and role of SNM1A remain unclear. Here we show that, in addition to known 5’-3’exonuclease activity, SNM1A possesses single-strand specific endonuclease activity. Furthermore, SNM1A exhibits translesion nuclease activity on crosslinks which deform the helical backbone, but not non-distorting stable ICLs. We report the identification and characterization of nine small molecules inhibitors of SNM1A, isolated from an in vitro high-throughput screen of nearly 4,000 bioactive compounds. Finally, we demonstrate that inhibitors of SNM1A potentiate the cytotoxicity of ICL-inducing agent cisplatin in HeLa cells. The work in this thesis expands the possible roles of SNM1A in ICL repair and lays the groundwork for SNM1A inhibition in ICL sensitization efforts. / Thesis / Doctor of Philosophy (PhD)

SNM1A

beta-CASP nuclease

small molecule inhibitors

translesion nuclease

chemoresistance

structure-specific endonuclease

interstrand crosslinking repair

high throughput screening

The role of ubiquitylation in regulating apurinic/apyrimidinic endonuclease 1

Meisenberg, Cornelia

January 2012

Apurinic/apyrimidinic endonuclease 1 (APE1) is a key DNA repair factor involved in the DNA base excision repair (BER) pathway that is required for the maintenance of genome stability. In this pathway, APE1 cleaves DNA at an abasic site to generate a DNA single strand break, allowing for repair completion by a DNA polymerase and a DNA ligase. High levels of APE1 have been observed in multiple cancer types however it is not understood if this contributes to cancer onset and development. What is known is that these cancers tend to display increased resistance to DNA damaging treatments and APE1 is therefore considered a key target for inhibition in the treatment of APE1-overexpressing cancers. Considering the relevance of modulating APE1 levels in disease and cancer treatment, very little is known about how cellular APE1 levels are regulated. Our lab has previously shown that the levels of the BER factors Pol β, XRCC1 and DNA Lig IIIα are regulated by ubiquitylation-mediated proteasomal degradation. The aim of this doctoral thesis was therefore to determine if ubiquitylation also regulates APE1 stability in cells. I present evidence that APE1 is ubiquitylated in cells and have identified the UBR3 E3 ligase that is responsible for this activity. Using mouse embryonic fibroblasts generated from Ubr3 knockout mice, I demonstrate that UBR3 regulates APE1 cellular levels. I furthermore show that a loss of cellular UBR3 leads to the formation of DNA double strand breaks and genome instability.

572.8

Mycobacterium Leprae RecA Intein : A LAGLIDADG Homing Endonuclease, Displays A Unique Mode Of DNA Binding And Catalysis Compared To A Canonical LAGLIDADG Homing Enzyme

Singh, Pawan

12 1900

Mobile genetic elements are DNA sequences that move around to different positions within one genome or between different genomes. Mobile DNA elements were initially considered as selfish DNA sequences parasitizing the organism’s genome. However, this view has changed with the discovery of several mobile genetic elements which play important evolutionary and functional roles. Such understanding has led to a new connotation for these genetic elements such as drivers or natural molecular tools of genome evolution. Extensive research over the past several years has also led to the identification of several new mobile genetic elements including transposons, segregation distorters, heritable organisms, introns and inteins. Homing endonucleases (HEnases) are a group of rare cutting site-specific doublestranded DNA endonucleases encoded by open reading frames within introns, inteins or free standing genes in all the three forms of life including viruses. These enzymes confer mobility to themselves and their encoding sequences by a gene conversion event termed “homing”. During the homing process, the endonuclease inflicts a double-strand break at or near the homing site of the intein-/intron-less allele, which is subsequently repaired by the host DNA repair machinery resulting in the inheritance of intein/intron. The first homing endonuclease identified was the Saccharomyces cerevisiae mitochondrial genetic marker ‘ω’, which affects the polarity of recombination. This genetic marker, which was later shown to be a mobile group I intron, was present in the mitochondrial 21S rRNA gene and encodes a homing endonuclease. HEnases are distinguished for being able to recognise long DNA sequences (14-40 bp), and display disparate cleavage mechanisms. Unlike restriction endonucleases, these enzymes tolerate sequence polymorphism in their recognition region which provides a mechanism for increasing their genetic diversity. Substantial efforts are underway to explore the possibility of utilizing HEnases as tools for genome mapping, cloning of megabase DNA fragments and gene targeting. HEnases are divided into five sub-families on the basis of their conserved sequence and structural motifs: LAGLIDADG, GIY-YIG, H-N-H, His-Cys box and PD-(D/E)-XK families. Among these, LAGLIDADG family is the largest, most prevalent and well-studied class of HEnases. Homing enzymes that contain a single copy of LAGLIDADG motif per polypeptide chain, such as ICreI, I-MsoI and I-CeuI function as homodimers and recognize and cleave palindromic and pseudo-palindromic DNA sequences. On the other hand, HEnases that harbour two copies of LAGLIDADG motifs including I-AniI, PI-SceI and I-SceI act as monomers and recognize and cleave their DNA target sites with considerable asymmetry. Eubacterial RecA proteins are important for a number of cellular processes such as homologous recombination, DNA repair, restoration of stalled replication forks and SOS response. RecA protein and the process of homologous recombination, which is the main mechanism of genetic exchange, are evolutionarily conserved among a range of organisms. However, few mycobacterial species such as Mycobacterium tuberculosis and Mycobacterium leprae were found to be an exception as they harboured in-frame insertion of an intein-coding sequence in their recA genes. In these organisms, RecA is synthesized as a large precursor, which undergoes protein splicing resulting in the formation of an intein and functionally active RecA protein. The milieu in which RecA precursor undergoes splicing differs substantially between M. tuberculosis and M. leprae. M. leprae RecA precursor (79 kDa) undergoes splicing only in mycobacterial species, whereas M. tuberculosis RecA precursor (85 kDa) is spliced efficiently in Escherichia coli as well. Intriguingly, M. tuberculosis and M. leprae RecA inteins differ greatly in their size, primary sequence and location within the recA gene, thereby suggesting two independent origins during evolution. The occurrence of inteins in the obligate mycobacterial pathogens M. tuberculosis, M. leprae and M. microti, initially suggested that RecA inteins might play a role in pathogenesis or virulence, however this was found to be not the case due to the subsequent identification of these intervening sequences in several non pathogenic mycobacterial strains. Sequence comparison of RecA inteins suggested that they belong to the LAGLIDADG class of homing endonucleases. Accordingly, we have shown earlier that M. tuberculosis RecA intein (PI-MtuI), is a novel LAGLIDADG homing endonuclease, which displays dual target specificity in the presence of alternative cofactors in an ATP-dependent manner. The genome of M. leprae, a gram positive bacillus reveals that in contrast to the genomes of other mycobacterial species, it has undergone extensive deletions and decay and thereby represents an extreme case of reductive evolution. In such a scenario of massive gene decay and function loss in the leprosy bacillus, and dissimilarities in size and primary structures among mycobacterial RecA inteins, it was of interest to examine whether M. leprae recA intervening sequence can encode a catalytically active homing endonuclease. To this end, the intervening sequence corresponding to M. leprae recA intein was PCR amplified, cloned, overexpressed and purified to homogeneity using IMPACT protocol. The identity of the purified RecA intein was ascertained by sequencing 9 amino acid residues at the N-terminal end and Western blot analysis using anti-PI-MleI antibodies. Purified enzyme was found to be devoid of any contaminating exonuclease. Protein crosslinking experiments using glutaraldehyde suggested that PI-MleI exists in solution as a monomer, consistent with double-motif LAGLIDADG enzymes. To test whether the purified PI-MleI can bind to the DNA and display any DNA-binding specificity, we carried out electrophoretic mobility shift assays with both single-stranded and double-stranded cognate DNA. The enzyme displayed robust binding to cognate doublestranded DNA, compared to the cognate single-stranded DNA. DNA binding was further found to be sequence independent though the presence of the cognate sequence was required for maximal binding. The stability and specificity of PI-MleI-cognate DNA complexes were further examined by salt titration and competition experiments, which indicated high stability and specificity. After establishing the stable binding of recombinant PI-MleI to the cognate duplex DNA, we next investigated its endonuclease activity on the cognate plasmid pMLR containing the intein-less recA allele, in the absence or presence of divalent cations. The cleavage was monitored by the conversion of supercoiled pMLR to nicked circular as well as linear duplex DNA. PI-MleI exhibited both single-stranded nicking and double-stranded DNA cleavage activity. PI- MleI exhibits endonuclease activity both in the presence of Mg2+ or Mn2+ through a two step reaction. PI-MleI mediated cleavage though was found to be divalent cation dependent however was nucleotide cofactor independent, unlike PI-MtuI, which cleaves the cognate DNA substrate in the presence of ATP. PI-MleI endonuclease activity was assayed under different conditions and found to display a broad divalent cation, pH and temperature dependence. The kinetic experiments revealed slow turnover rate of PI-MleI suggesting its weak endonuclease activity in contrast to robust cleavage activity displayed by several other known LAGLIDADG homing endonucleases. An intriguing observation emerged from the cleavage site mapping of PI-MleI at singlenucleotide resolution. PI-MleI displayed a staggered double- strand break in the homing site by nicking in the left flanking sequence 44 to 47 bp and in the right flanking sequence 16 to 25 bp, away from the intein insertion site. Similar cleavage patterns have been earlier observed for few GIY-YIG homing endonucleases. To gain further mechanistic insights into the PI-MleI mediated catalysis, we examined the binding of PI-MleI to the cognate DNA by DNase I and (OP)2 Cu footprinting experiments. Both the footprinting approaches revealed interaction of PI-MleI with a region upstream and downstream of its own insertion site, conferring protection to 16 nucleotide residues on the upper and 12 nucleotide residues on the lower strand, respectively. The asymmetric footprints have been earlier observed for some members of LAGLIDADG-type homing endonucleases wherein protection on the complementary strands was found to be out of register by 2 to 3 nucleotides, respectively. In case of PI-MleI, however the footprint formed on the complementary strands of the homing site is non-overlapping, indicating the asymmetric mode of interaction of the enzyme. Surprisingly, PI-MleI footprint was not evident at the cleavage sites and this could be due to the unstable binding of the intein at these regions. To decipher the interaction of PI-MleI at the cleavage sites and to ascertain if these interactions have any functional implications in terms of alterations in base-pairing positioning or strand separation to mediate DNA catalysis, we probed the structure of PI-MleI-DNA complexes with KMnO4. KMnO4 treatment of PI-MleI-cognate DNA complexes revealed the presence of hypersensitive T residues on both the strands at the cleavage sites, but showed no such reactive T residues within the PI-MleI-binding regions. Also, hyper-sensitive T residues were not seen at or near the intein-insertion site or in the region between binding and cleavage sites suggesting that PI-MleI upon binding its cognate DNA induces distortions selectively at the cleavage region. To validate these findings and to test whether such alterations occurred on all substrate DNA molecules or on a small sub-population of target molecules, we used a more sensitive 2-aminopurine fluorescence approach. To this end, six cognate duplex DNA molecules each containing 2-aminopurine (2-AP) at different positions such as at the insertion site, in the DNAbinding region, at or near to the cleavage sites were synthesized to monitor helical distortions in the target DNA. The 2-AP containing cognate DNA duplexes were incubated with increasing concentrations of PI-MleI in the assay buffer and monitored the changes in 2-AP fluorescence intensity in the spectral region from 330 to 450 nm. Out of the 2-AP placed at several positions within the cognate substrate, only the 2-aminopurines at the cleavage site showed enhanced fluorescence with PI-MleI addition, consistent with the hyper-sensitivity of T residues during KMnO4 probing. The findings suggest that DNA distortion might assist PI-MleI in widening the minor groove at the cleavage site and make the scissile phosphates accessible to the enzyme active site similar to what has been seen with other LAGLIDADG homing enzymes. These observations suggest that PI-MleI binds to cognate DNA flanking its insertion site, induces helical distortion at the cleavage sites and generates two staggered double-strand breaks. Together, these finding indicate the modular structure of PI-MleI having separate domains for DNA target recognition and cleavage and a bipartite structure of its homing site. After demonstrating the endonuclease activity of PI-MleI, we next examined the active site residues of PI-MleI involved in double-stranded DNA cleavage, which would further provide insights into its catalytic mechanism. Previously, sequence alignment analyses of LAGLIDADG enzymes carried out using different alignment programs identified the presence of 115VLGSLMGDGP123 sequence as DOD motif I (Block C) and 185LQRAVYLGDG194 or 210VLAIWYMDDG219C sequences as catalytic DOD motif II (Block E) in M. leprae RecA intein (PI-MleI). The bioinformatics analyses though on one hand identified the catalytic motifs in PI-MleI, on the other hand led to conflicting data in regard to the identity and the specific position of the catalytic DOD motif II within the PI-MleI polypeptide. We therefore, performed site-directed mutagenesis of key residues in these catalytic motifs and examined their effect on PI-MleI mediated catalysis. A wealth of mutagenesis and structural data, which exists concerning HEnases, suggests that catalytic centers carry essential aspartate residues, one in each of the LAGLIDADG motifs Accordingly, we chose to mutate conserved aspartates that have been previously implicated in catalysis. By site-directed mutagenesis, we constructed five mutant proteins, in which Asp122 was mutated to alanine, cysteine and threonine; whereas Asp193 and Asp218 were mutated to alanine. The identity of each mutant was ascertained by determining the complete nucleotide sequence of the mutant gene. Mutant proteins were further purified to >95% homogeneity using the purification strategy developed for wild type PI-MleI and were found to be devoid of any contaminating exonuclease. To study the effect of mutations in PI-MleI active site residues on its DNA-binding affinity, we examined the binding characteristics of the wild type PI-MleI and its aspartate variants with the intein-less recA substrate and the stability of protein-DNA complexes. All the mutants displayed similar binding affinity to the cognate DNA as that of the wild type PI-MleI, as judged by the comparison of their binding constants (Kd) which were found to be of the same order. Comparison of salt titration isotherms of wild type PI-MleI and its aspartate variants further revealed the similar salt titration midpoint for most of the mutants as that of wild type enzyme suggesting similar protein-DNA complexes stability. Although these results indicate the occurrence of stable complexes between PI-MleI variants and target DNA, to further define the DNA-binding properties of each mutant protein, wild-type PI-MleI and its variants were assayed by DNase I footprinting. All the mutants (D122A, D122C, D122T, D193A and D218A) showed an asymmetric footprint and protection of ~16 nucleotide residues on the upper and 12 nucleotide residues on the lower strand, respectively, near the intein-insertion site similar to the wild type PI-MleI. Together, these observations suggest that the aspartate substitutions in the catalytic motifs do not alter DNA recognition specificity of PI-MleI or its variants, and may not play a direct role in protein-DNA interactions, again implicating the existence of a modular structure of PI-MleI with distinct DNA-binding and catalytic domains. Wild-type PI-MleI although binds near the intein insertion site, but however was found to induce helical distortions only at the cleavage sites. To explore, if aspartate substitutions have any effect on the structural modifications in target DNA sequence, we carried out 2-aminopurine fluorescence with wild type PI-MleI and its variants. In agreement with the wild type enzyme, all the mutants showed increase in fluorescence with target DNA containing 2-AP only at the cleavage sites, but not at the binding sites. However, quantitative measurements of fluorescence change suggested that D122A and D193A mutants show nearly two-fold decrease in the magnitudes of spectral change at the cleavage site compared to wild type and other variants suggesting their involvement in the helical distortion process. To study the effect of Asp substitutions on the catalytic activity of PI-MleI, we performed cleavage assays using cognate plasmid pMLR DNA, with increasing concentrations of wild-type PI-MleI, or its variants and measured the double-stranded cleavage activity. Whereas, D122A and D193A mutants were completely inactive in double-stranded DNA cleavage under the conditions of the cleavage assay, D218A showed DNA cleavage activity comparable to that of the wild type PI-MleI. Similarly, D122T showed decrease in doublestranded DNA cleavage activity. Interestingly, D122C variant showed ~2-fold enhanced DNA cleavage, compared to the wild-type enzyme.Together, these findings provide compelling evidence to conclude that 115VLGSLMGDGP123 and 185LQRAVYLGDG194 motifs (Blocks C and E, respectively), but not 210VLAIWYMDDG219 motif (Block E), and that residues Asp122 and Asp193 play a direct role with respect to the catalytic mechanism of PI-MleI. In summary, these results suggest that the structural and mechanistic aspects of PI-MleI catalysis are distinct from other well-characterized LAGLIDADG-type homing endonucleases and thus provide further insights into understanding the function and evolution of LAGLIDADG homing enzymes.

Endonuclease

DNA Binding

LAGLIDADG

Mycobacterium Leprae

Catalysis

Enzyme

Introns

Mycobacterium Inteins

Homing Endonucleases (HEnases)

Inteins

Mycobacterial Inteins

Mycobacterial RecA Inteins

Mycobacteria

Biochoemical Genetics

The Kluyveromyces lactis killer toxin is a transfer RNA endonuclease

Lu, Jian

January 2007

Killer strains of the yeast Kluyveromyces lactis secrete a heterotrimeric protein toxin (zymocin) to inhibit the growth of sensitive yeasts. The cytotoxicity of zymocin resides in the γ subunit (γ-toxin), however the mechanism of cytotoxicity caused by γ-toxin was previously unknown. This thesis aimed to unravel the mode of γ-toxin action and characterize the interaction between γ-toxin and its substrates. Previous studies suggested a link between the action of γ-toxin and a distinct set of transfer RNAs. In paper I, we show that γ-toxin is a tRNA anticodon endonuclease which cleaves tRNA carrying modified nucleoside 5-methoxycarbonylmethyl-2-thiouridine (mcm5s2U) at position 34 (wobble position). The cleavage occurs 3’ to the wobble uridine and yields 2’, 3’-cyclic phosphate and 5´-hydroxyl termini. In paper II, we identified the determinants in tRNA important for efficient γ-toxin cleavage. The modifications present on the wobble uridines have different effects on tRNA cleavage by γ-toxin. The Saccharomyces cerevisiae wobble modification mcm5 group has a strong positive effect, whereas the Escherichia coli wobble modification 5-methylaminomethyl group has a strong inhibitory effect on tRNA cleavage. The s2 group present in both S. cerevisiae and E. coli tRNAs has a weaker positive effect on the cleavage. The anticodon stem loop (ASL) of tRNA represents the minimal structural requirement for γ-toxin action. Nucleotides U34U35C36A37C38 in the ASL are required for optimal cleavage by γ-toxin, whereas a purine at position 32 or a G at position 33 dramatically reduces the reactivity of ASL. Screening for S. cerevisiae mutants resistant to zymocin led to the identification of novel proteins important for mcm5s2U formation (paper III). Sit4p (a protein phosphatase), Sap185p and Sap190p (two of the Sit4 associated proteins), and Kti14p (a protein kinase) are required for the formation of mcm5 side chain. Ncs2p, Ncs6p, Urm1p, and Uba4p, the latter two function in a protein modification (urmylation) pathway, are required for the formation of s2 group. The gene product of YOR251C is also involved in the formation of s2 group. The involvement of multiple proteins suggests that the biogenesis of mcm5s2U is very complex.

Molecular biology

K. lactis γ-toxin

tRNA endonuclease

modified nucleosides

5-methoxycarbonylmethyl-2-thiouridine

5-methylaminomethyl-2-thiouridine

anticodon stem loop

Molekylärbiologi

Studies into the structural basis of the DNA uridine endonuclease activity of exonuclease III homolog Mth212 / Untersuchungen zur strukturellen Voraussetzungen der DNA Uridin-Endonuklease Aktivität von einem Exonuklease III Homolog - Mth212

Tseden, Khaliun

02 May 2011

No description available.

570 Biowissenschaften, Biologie

Biology (incl. Psychology)

DNA Uridin-Endonuklease

gerichtete Evolution

gezielte Mutagenese

DNA uridine endonuclease

directed evolution

directed mutagenesis

42.13

WJD 300: Mutationen {Biologie, Genetik}