Site-specific recombination of P2-like phages; possible tools for safe gene therapy : A focus on phage ΦD145

Mandali, Sridhar

January 2010

P2-like bacteriophages integrate their genome into the E. coli host cell by a site-specific recombination event upon lysogenization. The integrative recombination occurs between a specific sequence in the phage genome, attP, and a specific sequence in the host genome, attB, generating the host-phage junctions attL and attR. The integration is mediated by the phage enzyme integrase (Int) and the host factor IHF. The excisive recombination takes place between attL and attR, and is mediated by Int, IHF and phage encoded protein Cox. For safe integration of foreign genes into eukaryotic chromosome a recombinases is necessary which can perform the integration site-specifically. P2-like phage integrases have the potential to become tools for safe gene therapy. Their target is simple but specific, and once integration has occurred it is very stable in the absence of the Cox protein. The site-specific recombination mechanism has to be understood at the molecular level. Therefore, I have initiated the characterization of the site-specific recombination system of the P2-like phage ΦD145. In this work, Int and IHF are shown to bind to the different attachment sites cooperatively. One of two possible inverted repeats in attP is shown to be the Int core recognition site. The attP core of this phage has high identity with a site on human chromosome, denoted as ΨattB. In this study we have shown that in in vivo recombination ΦD145 Int can accept ΨattB in both bacteria and in eukaryotic cells. Also shown that Int consists of an intrinsic nuclear localization signal. A study also reveled that ΦD145 Int activity was affected by the Tyr-phosphorylation. Attempts have been made to change the specificity of the other P2-like phage P2 and WΦ integrases and also structural and functional analysis was done. A study on comparative analysis of Cox proteins and Cox binding sites gave us the basic information about the recombination mechanism. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript.

bacteriophage

integrase

site-specific recombination

NATURAL SCIENCES

NATURVETENSKAP

Nucleoside diphosphokinase of Escherichia coli and its interactions with bacteriophage T4 proteins of DNA synthesis

Ray, Nancy Bisset

08 May 1992

Graduation date: 1993

Escherichia coli -- Genetics

Phosphotransferases

Bacteriophage T4

DNA -- Synthesis

Efficacy of Bacteriophage Treatment on Pseudomonas aeruginosa Biofilms

Phee, Alysen Leigh

26 November 2012

This study examined the use of phage therapy against Pseudomonas aeruginosa strain PA14 biofilms. Part 1: 24 and 96h PA14 biofilms grown in microplates were phage treated and bacterial biomass was quantified using crystal violet staining. Part 2: 24 and 96h PA14 biofilms grown in prepared root canals of human mandibular incisors were treated with phages and intra-canal samples using paper points and round burs were taken to assess phage and bacterial counts. Part 1: Two phages (JBD4 and JBD44a) were used. Treatment with phages produced significant reduction in the mean percentage of biomass in 24h (p<0.05) and 96h (p=0.08) biofilms. Part 2: In 24 and 96h biofilms in a root canal model, no significant difference was found in colony forming units after phage treatment (p>0.05). Phage application significantly reduced the biomass of 24 and 96h PA14 biofilms grown on microplates, but did not in the extracted tooth models.

Pseudomonas aeruginosa

bacteriophage therapy

apical periodontitis

root canal

0567

Efficacy of Bacteriophage Treatment on Pseudomonas aeruginosa Biofilms

Phee, Alysen Leigh

26 November 2012

This study examined the use of phage therapy against Pseudomonas aeruginosa strain PA14 biofilms. Part 1: 24 and 96h PA14 biofilms grown in microplates were phage treated and bacterial biomass was quantified using crystal violet staining. Part 2: 24 and 96h PA14 biofilms grown in prepared root canals of human mandibular incisors were treated with phages and intra-canal samples using paper points and round burs were taken to assess phage and bacterial counts. Part 1: Two phages (JBD4 and JBD44a) were used. Treatment with phages produced significant reduction in the mean percentage of biomass in 24h (p<0.05) and 96h (p=0.08) biofilms. Part 2: In 24 and 96h biofilms in a root canal model, no significant difference was found in colony forming units after phage treatment (p>0.05). Phage application significantly reduced the biomass of 24 and 96h PA14 biofilms grown on microplates, but did not in the extracted tooth models.

Pseudomonas aeruginosa

bacteriophage therapy

apical periodontitis

root canal

0567

Inhibition phenotype specific for orië replication-dependent phage growth, and a reappraisal of the Influence of ë P expression on <i>escherichia coli</i> cell metabolism : p-interference phenotype

Horbay, Monique Adelle

22 December 2005

Bacteriophage ë has been used as a model replicon system for forty years. While the basic ë replication initiation scheme has been elucidated for several decades, many aspects of the mechanisms are unclear. I wished to study two unanswered issues in ë replication initiation. </p><p>Replication initiation of E. coli and ë each depend upon a protein generally called a licensing factor, which brings the DnaB helicase protein to the origin site to begin DNA synthesis. The licensing factors are the products of host gene dnaC and ë gene P. The synthesis of P from ë DNA in an E. coli cell can competitively interfere with DnaC activity needed for E. coli replication initiation. I wished to learn more about what happens to a host cell when exposed to extended P expression. Previous studies in this laboratory suggested that i) the continuous expression of P was tolerated by a subset of exposed cells and that ii) host defects mapping to dnaB could suppress the effect of extended P expression (P-lethality). I used DNA sequencing to determine if these suppressor mutations were within dnaB. I screened known host mutations for their influence on P-lethality. In summary: E. coli strains with GrpD55 and GrpA80 defects were found to each have two point mutations within their dnaB genes. I was unable to isolate mutations within P that suppressed P-lethality and instead obtained regulatory mutations preventing wild type P expression. Two of these sequenced mutations showed that a cI[Ts] lambda repressor was reverted to cI wild type, blocking P expression at all assay temperatures. P-lethality was reversible in cells exposed to P for up to five hours, causing me to suggest that P-Interference be used in place of the term P-lethality. A non-inducible allele of lexA prevented P-mediated cellular filamentation and enhanced P-Interference. This suggests that induction of the SOS response helps cells to tolerate extended P expression. A host strain containing a defective ClpXP protease significantly enhanced cellular sensitivity to P-Interference. This suggests an important role for the ClpXP chaperone-protease complex in degradation of P and cellular resistance to P expression. I present models to explain the P-Interference Phenotype.</p><p>Recent reports have re-opened the possibility that the tO-oop-pO element influences ë DNA replication initiation. I have also been investigating this possibility. I found that a plasmid with tO-oop-pO (the terminator, nucleotide sequence and promoter for OOP RNA) and orië DNA sequence was inhibitory to the development of repë phages, and designated this the Inhibition Phenotype (IP). In pursuing the mechanism for this inhibition, I mutated the tO-oop-pO and orië elements. I found that the expression of the 77nt OOP RNA transcript and the presence of four 18 base pair repeats (iterons) within orië were required for the IP. I isolated spontaneous phage mutants, resistant to the IP. I determined that singly infected cells were sensitive to the IP but that multiply infected cells escaped the IP. I propose that the IP to repë phage development is directed to the initial or theta mode of ë replication initiation. I found that the theta-mode of ë replication initiation can be bypassed, likely via recombination between multiple phage genomes within a singe cell. I propose models to explain the IP and also suggest a role for OOP RNA in the regulation of ë DNA replication.

OOP RNA

DNA replication initiation

lambda P protein

bacteriophage lambda

Enzyme associations in deoxyribonucleotide biosynthesis : anti-idiotypic antibodies as probes for direct protein-protein interactions

Young, James Patrick

11 May 1992

The ability to faithfully replicate DNA is dependent upon the maintenance and regulation of its precursors, the deoxyribonucleoside triphosphates. Enzymes encoded by the bacteriophage T4 have been widely used as models of biochemical processes. A body of evidence supports the concept that the bacteriophage T4 enzymes involved in deoxyribonucleotide biosynthesis are associated as a complex within the infected Escherichia coli. This dissertation describes the continued examination of the protein-protein interactions involved in deoxynucleotide biosynthesis of bacteriophage T4. My studies on the protein-protein interactions involved in deoxyribonucleotide biosynthesis focused on two unique phage proteins, the dCMP hydroxymethylase enzyme and the translational regulator RegA. An initial study was undertaken to determine if the generation of anti-idiotypic antibodies would prove useful in the identification of direct interactions between dCMP hydroxymethylase and other proteins of the deoxyribonucleotide synthetase complex. For the initial generation of anti-idiotypic antibodies, polyclonal rabbit antibodies were generated to affinity purified anti-dCMP hydroxymethylase polyclonal rabbit IgG. The anti-anti-dCMP hydroxymethylase antibody was found to be specific in binding to the bacteriophage T4 dTMP synthase. A second method to generate anti-idiotypic antibodies was attempted with the translational regulator RegA. The generation of anti-idiotypic antibodies to the RegA protein involved the purification of anti-RegA rabbit Fab fragments and the generation of anti-anti-RegA polyclonal antibodies within mice. This alternative method was determined to be inferior to the initial method for generating anti-idiotypic antibodies. Additional studies involved the examination of RegA protein-protein interactions using affinity chromatography. A number of bacteriophage T4 early proteins were determined to associate with an immobilized RegA column. / Graduation date: 1992

DNA -- Synthesis

Anti-idiotypic antibodies

Bacteriophage T4

Enzymes

Proteins -- Reactivity

The Role of Bacteriophage Lambda gpK in Tail Assembly and Host Cell Entry

Coburn, David Lawson

06 December 2011

The bacteriophage lambda tail protein gpK is required for tail assembly. The activity of the protein can be found at the assembling tail tip and is believed to be localized to this structure. GpK is a 27 kDa protein that has sequence identity to two families of proteins: the Mov34 family of peptidases and the NlpC/P60 family of peptidoglycan endopeptidases. Point substitutions and complementation data confirm that gpK possesses each of these domains and that they can function in trans. When the Mov34 domain is inactivated tail assembly is disrupted whereas when the NlpC/P60 domain is inactivated tails assemble but are inactive. Evidence is presented here that the C-terminal domain possesses lytic activity in isolation but not when part of the full-length protein.

Bacteriophage lambda

tail assembly

peptidoglycan hydrolase

gpK

0307

Inhibition phenotype specific for orië replication-dependent phage growth, and a reappraisal of the Influence of ë P expression on <i>escherichia coli</i> cell metabolism : p-interference phenotype

Horbay, Monique Adelle

22 December 2005

Bacteriophage ë has been used as a model replicon system for forty years. While the basic ë replication initiation scheme has been elucidated for several decades, many aspects of the mechanisms are unclear. I wished to study two unanswered issues in ë replication initiation. </p><p>Replication initiation of E. coli and ë each depend upon a protein generally called a licensing factor, which brings the DnaB helicase protein to the origin site to begin DNA synthesis. The licensing factors are the products of host gene dnaC and ë gene P. The synthesis of P from ë DNA in an E. coli cell can competitively interfere with DnaC activity needed for E. coli replication initiation. I wished to learn more about what happens to a host cell when exposed to extended P expression. Previous studies in this laboratory suggested that i) the continuous expression of P was tolerated by a subset of exposed cells and that ii) host defects mapping to dnaB could suppress the effect of extended P expression (P-lethality). I used DNA sequencing to determine if these suppressor mutations were within dnaB. I screened known host mutations for their influence on P-lethality. In summary: E. coli strains with GrpD55 and GrpA80 defects were found to each have two point mutations within their dnaB genes. I was unable to isolate mutations within P that suppressed P-lethality and instead obtained regulatory mutations preventing wild type P expression. Two of these sequenced mutations showed that a cI[Ts] lambda repressor was reverted to cI wild type, blocking P expression at all assay temperatures. P-lethality was reversible in cells exposed to P for up to five hours, causing me to suggest that P-Interference be used in place of the term P-lethality. A non-inducible allele of lexA prevented P-mediated cellular filamentation and enhanced P-Interference. This suggests that induction of the SOS response helps cells to tolerate extended P expression. A host strain containing a defective ClpXP protease significantly enhanced cellular sensitivity to P-Interference. This suggests an important role for the ClpXP chaperone-protease complex in degradation of P and cellular resistance to P expression. I present models to explain the P-Interference Phenotype.</p><p>Recent reports have re-opened the possibility that the tO-oop-pO element influences ë DNA replication initiation. I have also been investigating this possibility. I found that a plasmid with tO-oop-pO (the terminator, nucleotide sequence and promoter for OOP RNA) and orië DNA sequence was inhibitory to the development of repë phages, and designated this the Inhibition Phenotype (IP). In pursuing the mechanism for this inhibition, I mutated the tO-oop-pO and orië elements. I found that the expression of the 77nt OOP RNA transcript and the presence of four 18 base pair repeats (iterons) within orië were required for the IP. I isolated spontaneous phage mutants, resistant to the IP. I determined that singly infected cells were sensitive to the IP but that multiply infected cells escaped the IP. I propose that the IP to repë phage development is directed to the initial or theta mode of ë replication initiation. I found that the theta-mode of ë replication initiation can be bypassed, likely via recombination between multiple phage genomes within a singe cell. I propose models to explain the IP and also suggest a role for OOP RNA in the regulation of ë DNA replication.

OOP RNA

DNA replication initiation

lambda P protein

bacteriophage lambda

The Final Step in Phage Lysis: The Role of the Rz-Rz1 Spanin Complex in the Disruption of the Outer Membrane

Berry, Joel Dallas

2010 May 1900

The purpose of the work described in this dissertation is to better understand the role of Rz and Rz1 function with respect to phage lysis. We determined using both a genetic and biochemical approach that the Rz protein is an inner membrane protein containing a single N-terminal transmembrane domain (TMD) with an Nin/Cout topology. Consistent with previous work on Rz1, the Rz1 lipoprotein was found to be localized to the outer membrane (OM). Following localization, both Rz and Rz1 form homodimers in vivo due to intermolecular disulfide formation. Despite being localized to apposing membranes, the two proteins form a complex. A small number of phages encode a potential single protein equivalent of Rz-Rz1. This protein, termed a spanin, is predicted to tether the inner and outer membranes by a single polypeptide chain. Based on complementation, it was concluded that gp11 from the phage T1 is a functional equivalent of Rz-Rz1. Gp11, and by analogy the Rz-Rz1 two-component spanin complex, threads the meshwork of the PG layer. The presence of an Rz-Rz1 complex, which forms in the presence of peptidoglycan (PG), is supported by in vivo results. The soluble periplasmic domains of Rz and Rz1, which are dimeric and monomeric respectively, were purified. Circular dichroism analysis indicates that Rz is structured, with significant α-helical content, whereas Rz1, in which 10 out 39 residues are proline, is unstructured. Mixing the proteins results in the formation of a complex with significant new α-helical content. Negative-stain images reveal ~ 25 nm x ~ 4 nm rod-shaped structures. Holin independent activity of Rz and Rz1 is found to disrupt whole cells. Furthermore, time lapse microscopy of λ and λRzam lysis allows us to conclude that Rz and Rz1 are essential for lysis. These results suggest a model for Rz-Rz1 function which begins with Rz and Rz1 forming a complex through direct interaction prior to holin and endolysin function. Holin-mediated hole formation allows the endolysin to degrade PG which sterically hinders Rz-Rz1 activity. Removal of PG by endolysin degradation thus triggers Rz-Rz1 OM disruption via fusion of the inner and outer membranes.

Phage Lysis

Bacteriophage lambda

Rz and Rz1 spanin complex

Bacteriophage P1: a new paradigm for control of phage lysis

Xu, Min

01 November 2005

The N-terminal hydrophobic domain of the phage P1 endolysin Lyz was found to facilitate the export of Lyz in a sec-dependent fashion, explaining the ability of Lyz to cause lysis of E.coli in the absence of the P1 holin. The N-terminal domain of Lyz is demonstrated to be both necessary and sufficient not only for export to the membrane but also for release into the periplasm of this endolysin. We propose that this unusual N-terminal domain functions as a "signal arrest- release" (SAR) sequence, which first directs the endolysin to the periplasm in membrane-tethered form and then allows it to be released as a soluble active enzyme in the periplasm. To understand why release from the membrane is required for the physiological expression of the lytic activity of Lyz, we examined the role of its seven cysteine residues in the biogenesis of the active endolysin. The inactive, membrane-tethered and the active, soluble forms of Lyz differ in their pattern of intramolecular disulfide bonding. We conclude that the release of Lyz from the membrane leads to an intramolecular thiol-disulfide bond isomerization causing a dramatic conformational change in the Lyz protein. As a result, an active site cleft that is missing in nascent Lyz is generated in the mature form of the endolysin. Examination of the protein sequences of related bacteriophage endolysins suggests that the presence of an SAR sequence is not unique to Lyz. Studies on holin and antiholin indicated that P1 encodes two holins, LydA and LydC. The antiholin LydB inhibits LydA by binding to it directly on the membrane. All above results demonstrate a new paradigm for control of phage lysis, which is, upon depolarization of the membrane by holin function at a programmed time, endolysin is released from the bilayer leading to the immediate lysis of the host.

Bacteriophage P1

endolysin

holin

antiholin

SAR domain

lysis