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Molecular characterization of Mst77F and implication in Drosophila spermatogenesisKost, Nils 03 August 2012 (has links)
No description available.
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DNA condensate morphology Examples from the test tube and nature /Vilfan, Igor Drasko. January 2005 (has links)
Thesis (Ph. D.)--Chemistry and Biochemistry, Georgia Institute of Technology, 2006. / Nicholas V. Hud, Committee Chair ; Donald F. Doyle, Committee Member ; Rigoberto Hernandez, Committee Member ; Roger M. Wartell, Committee Member ; Loren D. Willliams, Committee Member.
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Insights into the Role of Nucleic Acid Structure and Topology in Controlling CondensationSarkar, Tumpa 09 July 2007 (has links)
DNA condensation is a fundamental process in all living organisms. The highly abundant nucleoid-associated proteins, HU and IHF, present in bacteria, have been shown to play an important role in shaping the nucleoid. However, the exact mechanism is not well understood. In this thesis, we have demonstrated that both HU and IHF guide DNA to condense into linear bundle-like structures in presence of cellular condensing components, but the proteins alone do not condense DNA into densely packed structures. Our results suggest a mechanism by which HU and IHF could act as architectural proteins during in vitro and in vivo DNA condensation.
More recently, DNA condensation has attracted much attention for its relevance in optimizing artificial DNA delivery systems for gene therapy. The research presented in this dissertation provides in depth biophysical studies that demonstrate how local modulations in the nucleic acid structure can be used to control both the size and the morphology DNA condensates. We describe a novel strategy for improving the condensation of oligonucleotides that is based on the self-organization of half-sliding complementary oligonucleotides into long duplexes (ca. kb) with flexible sites at regular intervals along the duplex backbones, in the form of single-stranded nicks or single-stranded gaps. Our results also provide new insights into the role of DNA flexibility in condensate formation and suggest the potential for the use of this DNA structure in the design of vectors for oligonucleotide and gene delivery.
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Condensation of DNA by spermine in the bulk and in the bacteriophage capsid : a cryo-electron microscopy studySung, Baeckkyoung 25 August 2011 (has links) (PDF)
By using cryo-electron microscopy, we analyzed the morphology and structure of long double-stranded DNA chains condensed upon addition of varying amounts of the tetravalent polycation spermine (polyamine). Experiments have been performed i) with chains diluted in the bulk and ii) with individual chains confined in a virus capsid.Bulk experiments have been done with lambda DNA (48.5 kbp) at low concentration (0.03 mM Ph) and in low salt conditions (10 mM Tris HCl, 1 mM EDTA, pH 7.6). We explored a wide range of spermine concentration, from the onset of precipitation (0.05 mM sp) up to above the resolubilization limit (400 mM sp). Sixteen min after mixing spermine and DNA, samples have been trapped in thin films and vitrified in liquid ethane to keep ionic conditions unchanged, and imaged at low temperature with low doses of electrons (cryoTEM). DNA chains mostly form large aggregates of toroids in which DNA chains are hexagonally packed with interhelical spacings of 2.93, 2.88, and 2.95 nm at 0.05, 1 and 100 mM spermine, respectively, in agreement with previous X-ray data. At higher spermine concentration (200 mM), hexagonal toroids are replaced by cholesteric bundles with a larger interhelical spacing (3.32 nm). We conclude that the shape and the structure of the liquid crystalline sp-DNA condensates are linked to the DNA interhelix spacing and determined by the ionic conditions i.e. by the cohesive energy between DNA strands. Outside of the precipitation domain (400 mM spermine), DNA chains form a soluble network of thin fibers (4-6 nm in diameter) that let us reconsider the state of these DNA chains in excess of spermine. We also designed experiments to visualize condensates formed 6-60 sec after mixing Lambda DNA with 0.05 mM spermine, under identical buffer conditions. Among multiple original shapes (not found after 16 min), the presence of stretched and helical elongated fibers seen only 9sec after addition of spermine let us propose that DNA chains are immediately stretched upon addition of spermine, relax into helical structures and finally form small toroids (containing in some cases less than one Lambda chain) that further grow and aggregate. We also analyzed the dimensions and structural details of the complete collection of toroids, and reveal the existence of geometric constraints that remain to be clarified. Since it was only exceptionally possible to prevent the aggregation of DNA in dilute solution, we used another approach to observe the collapse of single DNA chains. We handled a population of T5 viruses containing a fraction of their initial genome (12-54 kbp long). The Na-DNA chain, initially confined in the small volume of the capsid (80nm in diameter) is collapsed by the addition of spermine. Compared to the first set of experiments, we explored a higher DNA concentration range (0.45 mM Phosphates in the whole sample) and the spermine concentration was varied from 0.05 to 0.5 mM (which corresponds to much lower +/- charge ratios). Experiments are thus performed close to the precipitation line, in the coexistence region, between the region where all chains are in a coil conformation, and the region where all chains are collapsed into toroids. We describe the existence of intermediate states between the coil and the toroidal globule that were not reported yet. In these "hairy toroids", part of the DNA chain is condensed in the toroid and the other part stays uncondensed outside of it. The interhelical spacing was also measured; it is larger in these partly-condensed toroids than in the fully organized toroids formed at higher spermine concentration.These two series of experiments show the interest of cryoEM to analyze the structural polymorphism and local structure of spermine-DNA aggregates. We also demonstrated how the confinement interferes with DNA condensation and the interest to investigate such effects that are important in the biological context.
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Condensation of DNA by spermine in the bulk and in the bacteriophage capsid : a cryo-electron microscopy study / Condensation de l'ADN par la spermine en solution et dans la capside de bactériophage : une étude par cryo-microscopie électroniqueSung, Baeckkyoung 25 August 2011 (has links)
Nous avons analysé par cryomicroscopie électronique la morphologie et la structure de longues chaines d’ADN condensées par un polycation tétravalent, la spermine (polyamine). Les expériences ont été réalisées i) avec des solutions de chaînes diluées et ii) avec des chaines isolées confinées dans la capside d’un virus.Les expériences ont été réalisées avec de l’ADN Lambda (48kbp) en solution diluée (0.03 mM Ph) et à faible concentration ionique (10 mM Tris HCl, 1 mM EDTA, pH 7.6). Nous avons exploré une large gamme de concentrations en spermine, allant du seuil de précipitation (0.05 mM sp) jusqu’à la limite de re-solubilization et au-delà (400 mM sp). Seize minutes après mélange de l’ADN et de la spermine, les échantillons sont piégés en film mince et vitrifiés à basse température pour garder intactes les conditions ioniques, puis imagés à basse température sous faibles doses d’électrons (cryoMET). La plupart des chaînes d’ADN forment des agrégats de tores de structure hexagonale avec des interdistances entre hélices de 2.93, 2.88, et 2.95 nm pour des concentrations en spermine respectivement égales à 0.05, 1 et 100 mM spermine, ce qui est en bon accord avec les données collectées précédemment par diffraction des rayons X. A concentration plus élevée en spermine (200mM), les tores hexagonaux sont remplacés par des faisceaux cholestériques de structure plus lâche (3.32 nm entre hélices). Nous en déduisons que la forme comme la structure des condensats cristallins liquides ADN-sp sont liées aux interdistances entre hélices et déterminés par les conditions ioniques i.e. par l’énergie cohésive entre chaînes d’ADN. En dehors du domaine de précipitation (400mM sp), les molécules d’ADN forment un réseau soluble de fines fibres (4-6nm de diamètre) qui nous amènent à reconsidérer l’état de ces chaiînes en présence de spermine. Nous avons également conçu des expériences pour visualiser les agrégats formés 6 à 60 sec après addition de la spermine dans les mêmes conditions de tampon. Parmi les nombreuses formes originales que nous avons observées (absentes après 16 min), la présence de fibres étirées ou en hélice, visibles seulement après 9sec, nous conduit à proposer que les chaines d’ADN soient immédiatement étirées après addition de spermine puis relaxent sous forme de fibres hélicoïdales qui donnent naissance à de petits toroids (comprenant quelquefois moins d’une chaine) qui grandissent et fusionnent. Nous avons également analysé les dimensions de l’ensemble des tores observés et montré l’existence de contraintes géométriques qui restent à élucider. Puisqu’il était généralement impossible de prévenir l’agrégation des chaines d’ADN, nous avons choisi une autre approche pour analyser le collapse de chaines d’ADN individuelles. Nous avons utilisé une population de virus T5 contenant une fraction de leur génome initial (12-54 kbp). La molécule d’ADN, initialement confinée dans le petit volume de la capside (de de 80nm diamètre) est collapsée par addition de spermine. Par comparaison avec le premier jeu de données, nous avons travaillé à concentration plus élevée en ADN (0.45 mM Phosphates dans l’ensemble de l’échantillon) et la concentration en spermine a été ajustée entre 0.05 et 0.5 mM (ce qui correspond à des rapports de charges +/- bien inférieurs). Ces expériences ont donc été réalisées au voisinage de la ligne de précipitation, dans la « région de coexistence », entre le domaine où les chaines sont en condition de pelote et le domaine ou les chaines sont toutes collapsées sous forme de tores. Nous avons montré l’existence de formes intermédiaires entre ces deux états que nous appelons « tores chevelus » dans lesquels une partie de la molécule est condensées dans le tore alors que l’autre partie reste non condensée. Les distances entre hélices ont également été mesurées. Elles sont plus grandes dans ces structures intermédiaires que dans les tores formés à plus forte concentration en spermine. Ces deux séries d’expériences montrent l’intérêt des méthodes de cryo-microscopie pour étudier la structure locale des phases condensées de l’ADN. Nous avons montré comment le confinement modifie le comportement de l’ADN en solution et l’intérêt d’étudier ces effets compte tenu de son importance dans le contexte biologique. / By using cryo-electron microscopy, we analyzed the morphology and structure of long double-stranded DNA chains condensed upon addition of varying amounts of the tetravalent polycation spermine (polyamine). Experiments have been performed i) with chains diluted in the bulk and ii) with individual chains confined in a virus capsid.Bulk experiments have been done with lambda DNA (48.5 kbp) at low concentration (0.03 mM Ph) and in low salt conditions (10 mM Tris HCl, 1 mM EDTA, pH 7.6). We explored a wide range of spermine concentration, from the onset of precipitation (0.05 mM sp) up to above the resolubilization limit (400 mM sp). Sixteen min after mixing spermine and DNA, samples have been trapped in thin films and vitrified in liquid ethane to keep ionic conditions unchanged, and imaged at low temperature with low doses of electrons (cryoTEM). DNA chains mostly form large aggregates of toroids in which DNA chains are hexagonally packed with interhelical spacings of 2.93, 2.88, and 2.95 nm at 0.05, 1 and 100 mM spermine, respectively, in agreement with previous X-ray data. At higher spermine concentration (200 mM), hexagonal toroids are replaced by cholesteric bundles with a larger interhelical spacing (3.32 nm). We conclude that the shape and the structure of the liquid crystalline sp-DNA condensates are linked to the DNA interhelix spacing and determined by the ionic conditions i.e. by the cohesive energy between DNA strands. Outside of the precipitation domain (400 mM spermine), DNA chains form a soluble network of thin fibers (4-6 nm in diameter) that let us reconsider the state of these DNA chains in excess of spermine. We also designed experiments to visualize condensates formed 6-60 sec after mixing Lambda DNA with 0.05 mM spermine, under identical buffer conditions. Among multiple original shapes (not found after 16 min), the presence of stretched and helical elongated fibers seen only 9sec after addition of spermine let us propose that DNA chains are immediately stretched upon addition of spermine, relax into helical structures and finally form small toroids (containing in some cases less than one Lambda chain) that further grow and aggregate. We also analyzed the dimensions and structural details of the complete collection of toroids, and reveal the existence of geometric constraints that remain to be clarified. Since it was only exceptionally possible to prevent the aggregation of DNA in dilute solution, we used another approach to observe the collapse of single DNA chains. We handled a population of T5 viruses containing a fraction of their initial genome (12-54 kbp long). The Na-DNA chain, initially confined in the small volume of the capsid (80nm in diameter) is collapsed by the addition of spermine. Compared to the first set of experiments, we explored a higher DNA concentration range (0.45 mM Phosphates in the whole sample) and the spermine concentration was varied from 0.05 to 0.5 mM (which corresponds to much lower +/- charge ratios). Experiments are thus performed close to the precipitation line, in the coexistence region, between the region where all chains are in a coil conformation, and the region where all chains are collapsed into toroids. We describe the existence of intermediate states between the coil and the toroidal globule that were not reported yet. In these “hairy toroids”, part of the DNA chain is condensed in the toroid and the other part stays uncondensed outside of it. The interhelical spacing was also measured; it is larger in these partly-condensed toroids than in the fully organized toroids formed at higher spermine concentration.These two series of experiments show the interest of cryoEM to analyze the structural polymorphism and local structure of spermine-DNA aggregates. We also demonstrated how the confinement interferes with DNA condensation and the interest to investigate such effects that are important in the biological context.
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ILLUMINATING DNA PACKAGING IN SPERM CHROMATIN: HOW POLYCATION LENGTHS, UNDERPROTAMINATION AND DISULFIDE LINKAGES ALTERS DNA CONDENSATION AND STABILITYKirchhoff, Daniel 01 January 2019 (has links)
During spermiogenesis, somatic chromatin is remodeled and a vast majority (> 90%) of DNA histones are replaced by short arginine-rich peptides called protamines. This compaction is immense, with protamine-DNA self-assembly in sperm chromatin resulting in a final volume roughly 1/6th of a somatic nucleus. This near crystalline organization of the DNA in sperm is thought crucial both for the transport of the paternal genes as well as for the protection of genetic information as sperm chromatin is transcriptionally inactive and all DNA repair mechanisms are shut down.
Chapter 1 will include an overview of the topics discussed in this document, including: sperm chromatin, Sperm chromatin remodeling, DNA damage, and the effect of DNA damage to sperm DNA.
Chapter 2 will contain a brief overview of the techniques used within this study. This includes: Small-angle X-ray Scattering, gel electrophoresis, DNA precipitation assays, and ethidium bromide dissociation assays.
In chapter 3, we will discuss the effect of DNA packaging on the accessibility of free radicals to damage condensed DNA. A variety of polycations were used to condense plasmid DNA in reconstituted samples. After condensation, the DNA-polycation condensates were exposed to 2,2'-Azobis(2-amidinopropane) dihydrochloride (AAPH) for 1 hour, decondensed, and the plasmid DNA examined by gel electrophoresis. By comparing the intensities of the supercoiled, open coiled and linear bands, we were able to identify the presence of single-strand nicks and double-strand breaks in DNA. DNA packaging densities for all polycation-DNA systems were determined by small-angle X-Ray scattering (SAXS). Our results show that for similar length polycations, the amount of oxidative damage scales directly with the DNA packaging with more tightly condensed DNA being damaged less. However, our results also show that DNA damage is also dependent on polycation length, with DNA condensed by shorter polycations being damaged more than DNA condensed with longer polycations even at similar packaging densities.
Protamine has long been thought to play a role in protecting spermatic DNA from damaging agents in vivo. However, the relationship between the hypercondensation of sperm chromatin, the DNA integrity, and the transfer of epigenetic information from sperm to oocyte and potential to alter gene expression in the early embryo are poorly understood. In Chapter 4, we examine how underprotamination affects free radical accessibility and DNA stability in reconstituted sperm chromatin. Specifically, reconstituted salmon protamine- plasmid DNA condensates (polyplexes) were formed at precise protamine/DNA ratios and subsequently subjected to exposure to AAPH free radicals. Agarose gel electrophoresis was then used to assess DNA damage by observing topology alternations in the decondensed polyplexes. FPG-DNA glycosylase has also been used to more accurately determine oxidative damage beyond just nicks and double-strand breaks in the various condensed states. We show that higher levels of protamination correlate to greater levels of protection to the DNA from oxidative damage up until full charge compensation. Furthermore, we also demonstrate that poorly compacted chromatin could be recovered by the introduction of small cationic peptides in underprotaminated condensates as well as actual sperm nuclei. SAXS studies were performed to show that the introduction of cationic peptides resulted in tighter DNA packaging densities in the underprotaminated sperm chromatin.
In Chapter 5, we examine the role of disulfide bonds on DNA packaging in mammalian sperm chromatin. Mammalian protamine, unlike fish, are known to have cysteine residues capable of forming inter- and intra-protamine disulfide bonds. In bull, prior work had shown evidence for the formation of a unique hairpin secondary structure due to the folding of the ends of the protamine molecule by intramolecular disulfide linkages. Between folds is an arginine-rich region known as the DNA binding region. The DNA binding region has a local arginine fraction (~60-75%) that is much higher than the arginine fraction within the full bull protamine sequence (~50%). Previous work by the DeRouchey lab has shown that the percent arginine was crucial for DNA condensation in small arginine-rich peptides. We hypothesize that the fraction of arginine is also critical to DNA remodeling in sperm chromatin. SAXS studies showed that disulfide bond reduction resulted in complete decondensation of bull sperm nuclei. Here, we have used cysteine alkylation chemistry to add neutral or charged functional groups to the protamine cysteine, thereby inhibiting the formation of these disulfide bonds. This chemistry both prevents the formation of the hairpin as well as modifies the overall charge of the protamine. Through ethidium bromide exclusion assays, we measured binding of these altered protamines to calf thymus DNA and determined that a percent cationic charge of above 50% is necessary for the protamine to effectively condense DNA. In addition, we show that DNA condensation of bull protamine with the hairpin is nearly identical to piscine protamines which have no disulfide linkages but a net arginine fraction of 60-75%. Upon disruption of the hairpin, however, complete condensation does not occur despite a net charge on the protamine of +26.
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UNDERSTANDING DNA CONDENSATION BY LOW GENERATION (G0/G1) AND ZWITTERIONIC G4 PAMAM DENDRIMERSAn, Min 01 January 2016 (has links)
Cationic polymers have shown potential as gene delivery vectors due to their ability to condense DNA and protect it from cellular and restriction nucleases. Dendrimers are hyperbranched macromolecules with precisely defined molecular weights and highly symmetric branches stemming from a central core. The nanosize, tunable surface chemistries and ease of surface functionalization has made dendrimers an attractive alternative to conventional linear polymers for DNA delivery applications. The commercially available, cationic dendrimer poly(amidoamine) or PAMAM is the most widely studied dendrimer for use as a gene delivery vector. The aim of this dissertation is to provide an increased understanding of the packaging and forces within PAMAM–DNA complexes.
In Chapter 4, we will discuss the effect of molecular chain architecture on DNA-DNA intermolecular forces by examining DNA condensed by low generation (G0 & G1) PAMAM and comparing them to comparably charged linear arginine peptides. Using osmotic stress coupled with X-ray scattering, we are able to determine the structure and forces within dendrimer-DNA complexes, or dendriplexes. We show that PAMAM–DNA assemblies display significantly different physical behavior than linear cation–DNA assemblies. In Chapter 5, we examine the role of pH on condensation in these same low generation PAMAM-DNA complexes. PAMAM dendrimers have both terminal primary amines and internal tertiary amines with different pKas of approximately 9 and 6, respectively. We show changes in the pH at condensation greatly influence the resulting packaging as well as the resulting phase behavior for PAMAM dendriplexes. In Chapter 6, we examine the packaging of DNA by G4 PAMAM as a function of the percent zwitterionic modification. Many cationic polymers, including PAMAM, have shown high transfection efficiency in cell culture and potential for in vitro and in vivo applications, but its development is hindered by cytotoxicity in many cell lines and tissues. We hypothesize that zwitterionic PAMAM (zPAMAM) represent a new means to tune polymer-DNA interactions through PAMAM surface charge potentially enhancing intracellular unpackaging while reducing cellular toxicity. These zPAMAM complexes are currently under investigation for their potential as safer and more efficient materials for DNA delivery.
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SYNTHESIS AND DEVELOPMENT OF ZWITTERIONIC PEI (zPEI) FOR OPTIMIZED DELIVERY OF NUCLEIC ACIDSDuke, Joseph Raleigh, III 01 January 2017 (has links)
Gene therapy holds promise for the treatment a wide range of diseases ranging from cystic fibrosis to cardiovascular disease to cancer. The need for safe and efficient gene delivery methods remains the primary barrier to human gene therapy. Non-viral vector materials, including polymers, can be designed to be biocompatible and non-immunogenic, but lack the efficiency to be clinically relevant. Gene therapy awaits the development of new materials that are both safe and efficient. Here, we have synthesized a series of modified zwitterionic polymers based on the common transfecting agent polyethylenimine (PEI). Using a variety of biochemical and biophysical methods we have studied structure-function relation in zPEI-DNA as a function of percent modification. Our results show significant structural rearrangements in the DNA condensates with increasing zwitterionic character. The percent zwitterionic modification determines not only DNA packaging but the serum stability of the resulting polyplexes with more highly modified zPEI releasing DNA more readily.
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Functional Cyclic Carbonate Monomers and Polycarbonates : Synthesis and Biomaterials ApplicationsMindemark, Jonas January 2012 (has links)
The present work describes a selection of strategies for the synthesis of functional aliphatic polycarbonates. Using an end-group functionalization strategy, a series of DNA-binding cationic poly(trimethylene carbonate)s was synthesized for application as vectors for non-viral gene delivery. As the end-group functionality was identical in all polymers, the differences observed in DNA binding and in vitro transfection studies were directly related to the length of the hydrophobic poly(trimethylene carbonate) backbone and the number of functional end-groups. This enabled the use of this polymer system to explore the effects of structural elements on the gene delivery ability of cationic polymers, revealing striking differences between different materials, related to functionality and cationic charge density. In an effort to achieve more flexibility in the synthesis of functional polymers, polycarbonates were synthesized in which the functionalities were distributed along the polymer backbone. Through polymerization of a series of alkyl halide-functional six-membered cyclic carbonates, semicrystalline chloro- and bromo-functional homopolycarbonates were obtained. The tendency of the materials to form crystallites was related to the presence of alkyl as well as halide functionalities and ranged from polymers that crystallized from the melt to materials that only crystallized on precipitation from a solution. Semicrystallinity was also observed for random 1:1 copolymers of some of the monomers with trimethylene carbonate, suggesting a remarkable ability of repeating units originating from these monomers to form crystallites. For the further synthesis of functional monomers and polymers, azide-functional cyclic carbonates were synthesized from the bromo-functional monomers. These were used as starting materials for the click synthesis of triazole-functional cyclic carbonate monomers through Cu(I)-catalyzed azide–alkyne cycloaddition. The click chemistry strategy proved to be a viable route to obtain structurally diverse monomers starting from a few azide-functional precursors. This paves the way for facile synthesis of a wide range of novel functional cyclic carbonate monomers and polycarbonates, limited only by the availability of suitable functional alkynes.
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Bactericidal Mechanisms of Escapin, A Protein in the Ink of a Sea HareKo, Kochun 07 May 2011 (has links)
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A 60 kDa monomeric protein isolated from the defensive purple ink secretion of the sea hare Aplysia californica has broad antimicrobial activity in tryptone peptone rich medium. This protein, which we call ‘escapin’, belongs to an L-amino acid oxidase family. The goals of my project were 1) to determine the products of escapin’s oxidation of its main substrate L-lysine, 2) to characterize the antimicrobial effects of escapin’s products, and 3) determine bactericidal mechanisms of action of these products.
Escapin is a powerful bactericidal agent against several bacteria species including Escherichia coli, Pseudomonas aeruginosa, Staphylococcus aureus, and Vibrio harveyi. Escapin operates through a two-step process: 1) deamination of L-amino acids (especially L-lysine) by enzymatic activity to produce escapin intermediate products of L-lysine (EIP-K), hydrogen peroxide, and ammonia; and 2) EIP-K simultaneously reacts with hydrogen peroxide to generate escapin end products (EEP-K). EIP exists as an equilibrium mixture of the linear a-keto analogue of lysine and its cyclic forms, and the relative amount of the linear form increases with pH decreases. The powerful bactericidal effect of escapin requires the simultaneous presence of hydrogen peroxide and EIP-K in weak acidic conditions, which suggests that linear form of EIP-K with hydrogen peroxide is responsible for the bactericidal effect of escapin. Using E. coli MC4100 as a model, the mechanism of action of escapin was examined. Brief treatment with EIP-K + H2O2, but not EIP-K or H2O2 alone, causes irreversible DNA condensation with a time course similar to the bactericidal effect. A mutant strain resistant to EIP-K + H2O2 was isolated, and a single point mutation was found in the oxidative stress regulator gene (oxyR). Through a complementary assay, it was shown that wild type E. coli is conferred resistance to EIP-K + H2O2 by carrying mutated oxyR plasmid. Furthermore, in this bactericidal effect, heat or cold shock does not substitute for hydrogen peroxide induced oxidative stress. Thus, escapin’s powerful bactericidal effect may be through irreversible DNA condensation mediated through hydrogen peroxide generating an oxidative stress response, but the pathway mediating EIP-K’s synergistic effect is still unclear.
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