Protein-protein interactions in the bacteriophage T4-coded dCTPase-dUTPase

Ungermann, Christian

04 May 1993

Graduation date: 1993

Bacteriophage T4

Multienzyme complexes

Ligases

DNA -- Synthesis

Proteins -- Reactivity

Escherichia coli -- Genetics

A study of the dynamics of the protein core of the L99A mutant of T4 lysosome using nuclear magnetic resonance relaxation dispersion /

Hon, Bin,

January 2002

Thesis (Ph. D.)--University of Oregon, 2002. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 159-167). Also available for download via the World Wide Web; free to University of Oregon users.

Deposition of model viruses on cellulose

Li, Zhuo, 1982-

January 2008

A bioactive paper is a paper that can detect, capture and deactivate water and airborne pathogens. In this project, we presented a model "bioactive paper" made by attaching T4 bacteriophages to a cellulose substrate. T4 bacteriophages can be genetically engineered to possess copies of cellulose-binding modules (CBM) on their capsids. This allows them to bind specifically onto cellulose surfaces. Our model surface is a thin film of regenerated cellulose made by spin coating a glass or quartz substrate with a cellulose triacetate and subsequently hydrolyzing the surface back to cellulose. We successfully demonstrated the attachment of the CBM-T4 bacteriophages onto cellulose substrates by the phage viability test. The deposition kinetics were measured using an impinging jet apparatus combined with an evanescent wave light scattering (EWLS) system. We first tested the apparatus by using amidine latex particles deposited on the cellulose at different flow rates and found them to be in a good agreement with the constant potential double-layer model. The adhesion experiments were also performed in an impinging jet apparatus in which the CBM-T4 bacteriophages and the unassembled protein complexes from a suspension of 4.08 x 10 8 PFU/mL were allowed to diffuse to the cellulose surface, The competitive diffusion kinetics were again studied by the EWLS technique. For CBM-T4, the blocking time was found to be around 58 minutes and the maximum surface number density of phages was 5.9 x 1010 per m 2. / Key phrases: bioactive paper, cellulose film, cellulose binding module, bacteriophage T4, evanescent wave light scattering, unassembled protein complex, diffusion kinetics

Biosensors -- Design and construction.

Cellulose.

Organic thin films.

Bacteriophage T4.

Escherichia coli.

Structural design of cell-penetrating protein needles toward development of intracellular delivery systems / 細胞内分子輸送システム構築を指向した細胞膜貫通針蛋白質の構造設計

Inaba, Hiroshi

23 January 2015

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第18693号 / 工博第3971号 / 新制||工||1611(附属図書館) / 31626 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 北川 進, 教授 梅田 眞郷, 教授 濵地 格 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Protein needle

Protein chemistry

Plasma membrane translocation

Intracellular delivery

Bio-nanomaterial

Bacteriophage T4

500

Deposition of model viruses on cellulose

Li, Zhuo, 1982-

January 2008

No description available.

Bacteriophage T4.

Organic thin films.

Escherichia coli.

Cellulose.

Biosensors -- Design and construction.

Organization of the T4 dNTP synthetase complex at DNA replication sites

Kim, JuHyun

02 February 2005

With respect to a multienzyme complex of deoxyribonucleoside triphosphate (dNTP) synthesis somehow juxtaposed with DNA replication sites, our laboratory has demonstrated the existence of a multienzyme complex in T4-infected E. coli, named the T4 dNTP synthetase complex, but the idea of direct linkage of dNTP synthesis to DNA replication and organization of the complex has not been well established. This study had two objectives. The first objective was to test the specific hypothesis that gp32, the single-stranded DNA binding protein encoded by gene 32, plays a role in recruiting enzymes of dNTP synthesis to the replisome and in organizing the dNTP synthetase complex. By use of two newly created gene 32 mutants along with several experimental approaches, DNA-cellulose chromatography, coimmunoprecipitation, and glutathione-S-transferase pull downs, interactions of gp32 with thymidylate synthase (gptd), ribonucleotide reductase (gpnrdA/B), and E. coli NDP kinase have been identified. These results support the hypothesis that gp32 helps to recruit enzymes of dNTP synthesis to DNA replication sites. As the second objective, I investigated contributions of two host proteins, E. coli nueleoside diphosphate kinase (NDP kinase) and adenylate kinase (Adk), to the organization of the complex. As an important step to understand roles of E. coli NDP kinase in the complex, I identified direct interactions of E. coli NDP kinase with gpnrdA/B, dCMP hydroxymethylase (gp42), and dihydrofolate reductase (gpfrd) by means of coimmunoprecipitation and glutathione-S-transferase pull-down experiments. Interestingly, these interactions were influenced by the presence of substrate nucleotides or an analog for E. coli NDP kinase, suggesting that metabolite flux may affect the preference of E. coli NDP kinase binding to enzymes in the complex in vivo. Meanwhile, Adk involvement in DNA precursor synthesis has been suggested, particularly in phage T4-infected E. coli, from observations of increased thermostability of temperature-sensitive Adk in situ. The involvement of E. coil Adk in the complex was demonstrated by identifying some proteins of the T4 dNTP synthetase complexgp42, dNMP kinase (gpl), gpfrd, and E. coli NDP kinasedirectly interacting with Adk, implying that E. coil Adk would be properly located in the complex to efficiently carry out the conversion of dNDPs to dNTPs. This implication was supported by measurements of T4 DNA synthesis. Taken together, this research strongly supports the idea of connection of dNTP synthesis to DNA replication and allows us to take a step toward understanding the organization of the complex at DNA replication sites. / Graduation date: 2005

Bacteriophage T4

DNA replication

Deoxyribonucleotides -- Synthesis

Microbial enzymes

Virus-induced enzymes

DNA-binding proteins

Protein-protein interactions

A Study of DNA Replication and Repair Proteins from Bacteriophage T4 and a Related Phage

Senger, Anne Benedict

January 2004

No description available.

Chemistry, Biochemistry

DNA replication

bacteriophage T4

bacteriophage KVP40

helicase assembly

single-stranded binding

protein crystallization

DNA purification

Analysis of the Interactions between the 5' to 3' Exonuclease and the Single-Stranded DNA-Binding Protein from Bacteriophage T4 and Related Phages

Boutemy, Laurence S.

14 October 2008

No description available.

Biochemistry

DNA replication

protein-protein interactions

protein-DNA interactions

macromolecular crystallography

SAXS

RNase H

32 protein

bacteriophage T4

Mechanism Of Interaction Of Escherichia Coli σ70 With Anti-Sigma Factors

Sharma, Umender K

07 1900

In bacteria, the RNA polymerase (RNAP) consists of the following subunits: α2, β, β’, ω and σ. The core RNAP (α2ββ’ω) possesses the polymerising activity and it associates with one of the sigma factors to initiate transcription from a promoter region on the DNA template. All bacteria carry an essential housekeeping sigma factor and a number of extra cytoplasmic function (ECF) sigma factors. During alternate physiological states, a major part of transcriptional regulation is carried out by sigma factors, which act as transcriptional switches, thus, making it possible for bacteria to adapt to varied environmental signals by transcribing the necessary set of genes. Bacteriophages utilise various mechanisms for subverting the bacterial biochemical machinery for their advantage. One such example in E. coli is AsiA protein encoded by an early gene of T4 bacteriophage. Because of its property of binding to σ70, AsiA can inhibit transcription from E. coli promoters bearing –10 and –35 DNA sequences leading to inhibition of growth. σ70 of E. coli is also regulated by a stationary phase specific protein, Rsd, whose major function seems to be helping the cell in switching the transcription in favour of stationary phase genes. In this study we have investigated the mechanism of interaction of T4 AsiA and E. coli Rsd to σ70 of E. coli and also tried to determine the basis of differential inhibition of E. coli growth by AsiA and Rsd. In chapter one we have reviewed the published literature on regulation of transcription in bacteria. Some of the well known mechanisms of regulating gene expression are: DNA supercoiling, two component signal transduction system (TCS), regulation by alarmone ppGpp and 6S RNA, and sigma-antisigma interactions. Most bacteria carry a number of sigma factors and each of them is dedicated to transcribing genes in response to environmental signals. Intracellular levels of sigma factors and their binding affinity to core RNAP are deciding factors for initiating transcription from specific subsets of genes. In addition, sigma factor activity is also controlled by specific proteins, which bind to sigma factors (anti-sigma factors) under certain environmental conditions. A number of anti-sigma factors have been isolated from a variety of bacteria and the mechanisms of action of binding to cognate sigma factors have been worked out by using genetic, biochemical and structural tools. In chapter two, using yeast two hybrid assay (YTH), we have identified the regions of σ70 which interact with AsiA, and it was observed that amino acid residues from 547-603, encompassing region 4.1 and 4.2 are involved in binding to σ70. Interestingly, we found that truncated σ70 fragments lacking the N-terminal regions, apparently bound to AsiA with higher affinity compared to full length σ70. As AsiA expression, because of its transcription inhibitory activity, is inhibitory to E.coli growth, co-expression of the truncated C-terminal σ70 fragments (e.g. residues 493-613, σ70C121), which bind to σ70 with high affinity, could relieve growth inhibition. The complex of GST:AsiA-σ70C121 could be purified from E. coli cells. GST:AsiA purified from E .coli cells was found to be associated with RNAP subunits. Since further studies on this interaction required GST:AsiA preparation devoid of RNAP subunits, we decided to express this protein in S. cerevisiae. Bioinformatics analysis indicated the absence of a σ70 homologue in S.cerevisiae. As expected, GST:AsiA purified from the yeast was found to be free from any RNAP like proteins. The protein purified from yeast was used for in-vitro binding experiments. Our YTH analysis had indicated that deletion a part of region 4.1 or 4.2 of σ70 leads to loss of binding to AsiA. However, the published NMR structure of AsiA in complex with peptides corresponding to region 4 of σ70, showed that either region 4.1 or 4.2 alone can bind to AsiA indicating at the possible existence of two binding sites for AsiA. In order to confirm the physiological significance of this finding, we studied the interaction of truncated σ70 fragments lacking either region 4.1 or 4.2 with AsiA in-vivo in E. coli and in-vitro by affinity pull down assays. It was observed that σ70 fragments lacking either region 4.1 (σ70∆4.1) or 4.2 (σ70∆4.2), did not neutralize the GST:AsiA toxicity, indicating lack of interaction. The affinity purified GST:AsiA from these E. coli cells did not have σ70∆4.1 or σ70∆4.2 associated with it. Similar results were obtained from pull down assays in-vitro, where we found that σ70∆4.1 or σ70∆4.2 do not show any observable interaction with AsiA. This clearly established that the minimum region of σ70 required for physiologically relevant interaction with AsiA consists of both the regions 4.1 and 4.2. Chapter 3 of this thesis has been devoted to this aspect of AsiA-σ70 interaction. Having defined the minimum region of σ70 interacting with AsiA, we sought to identify the regions and amino acid residues of AsiA, which are critical for interaction with σ70. The approach for identification of mutants and their characterisation has been discussed in chapter 4. For this purpose, we made systematic deletions in the N and C-terminal regions of the protein and also isolated random mutants of AsiA, which lack binding to σ70 and thus are non-inhibitory to E. coli growth. It was found that deletion of 5 amino acids from N-terminus and 17 amino acids from C-terminus did not alter the inhibitory activity of AsiA. In contrast, deletion of N-terminal 10 amino residues led to complete loss of activity, while in the C-terminus, a gradual loss of activity was observed when amino acid residues beyond 17 amino acids were deleted. A 34 amino acids C-terminal deletion mutant was found to be completely inactive. E10K mutant was found to be inactive, but changes of E to other amino acids such as S, Y, L, A and Q were tolerated, indicating that negative charge at E10 is not a crucial element for interaction with σ70. Inactive mutants could be overexpressed in E. coli and showed reduced binding in YTH assay and were also poor inhibitors of in-vivo transcription in E. coli. We concluded that the primary σ70 binding site of AsiA is present in the N-terminus, yet C-terminal 64-73 amino acid residues are required for effective binding in-vivo. These studies also correlate the inhibitory potential of AsiA with its σ70 binding proficiency. In chapter 5, we have made a comparative analysis of mechanism of interaction of AsiA and Rsd to E. coli RNAP. Overexpression of Rsd was found to be less inhibitory to E. coli cell growth than that of AsiA. The affinity purified GST-AsiA from E. coli was found to have all the RNAP subunits associated with it, whereas, only σ70 was found to be associated with similarly purified GST:Rsd, pointing towards differences in binding to RNAP. In affinity pull down assays, in-vitro, it was found that both AsiA and Rsd do not show any observable binding to core RNAP. Binding of AsiA to σ70 in holo RNAP led to the formation of a ternary complex, whereas no ternary complex was observed when Rsd was made to interact with holo RNAP. Analysis of protein-protein interaction by YTH showed that region 4.1 and 4.2 are critical for binding of both AsiA and Rsd to σ70. However, in the case of Rsd, the surface of interaction is not limited to this region only and other regions of σ70 make significant contribution to this binding. Possibly, the interaction of Rsd with the core binding regions of σ70 prevents its association with core RNAP. Kinetic analysis of binding by surface plasmon resonance (SPR) showed that binding affinities (Kd) of AsiA and Rsd to σ70 are in similar range. Therefore, we concluded that the ability of AsiA to trap the holo RNAP is, probably, responsible for higher inhibitory activity of this protein compared to that of Rsd. Thus, T4 AsiA and E. coli Rsd, which share regions of interaction on σ70, have evolved differences in their mechanism of binding to RNAP such that T4 AsiA, by trapping the holo RNAP subverts the complete bacterial transcription machinery to transcribe its own genes. Rsd, on the other hand, has evolved to interact primarily with σ70, which favours the utilisation of core RNAP by other sigma factors.

Cytoplasmic Factor

Escherichia coli Cytoplasmic Factor

Transciption Regulation

Bacterial RNA Polymerase (RNAP)

Gene Expression

Bacterial Mutants

Bacteriophages - Genes

Bacteriophage T4

T4 AsiA

Anti-Sigma Factors

Escherichia coli σ70

Sigma(70)

Sigma 70

Rsd

Biochemical Genetics