Structure-Function Studies of Bacteriophage P2 Integrase and Cox protein

Eriksson, Jesper

January 2005

Probably no group of organisms has been as important as bacteriophages when it comes to the understanding of fundamental biological processes like transcriptional control, DNA replication, site-specific recombination, e.t.c. The work presented in this thesis is a contribution towards the complete understanding of these organisms. Two proteins, integrase, and Cox, which are important for the choice of the life mode of bacteriophage P2, are investigated. P2 is a temperate phage, i.e. it can either insert its DNA into the host chromosome (by site-specific recombination) and wait (lysogeny), or it can produce new progeny with the help of the host protein machinery and thereafter lyse the cell (lytic cycle). The integrase protein is necessary for the integration and excision of the phage genome. The Cox protein is involved as a directional factor in the site-specific recombination, where it stimulates excision and inhibits integration. It has been shown that the Cox protein also is important for the choice of the lytic cycle. The choice of life mode is regulated on a transcriptional level, where two mutually exclusive promoters direct whether the lytic cycle (Pe) or lysogeny (Pc) is chosen. The Cox pro-tein has been shown to repress the Pc promoter and thereby making tran-scription from the Pe promoter possible, leading to the lytic cycle. Further, the Cox protein can function as a transcriptional activator on the parasite phage, P4. P4 has gained the ability to adopt the P2 protein machinery to its own purposes. In this work the importance of the native size for biologically active integrase and Cox proteins has been determined. Further, structure-function analyses of the two proteins have been performed with focus on the protein-protein interfaces. In addition it is shown that P2 Cox and the P2 relative Wphi Cox changes the DNA topology upon specific binding. From the obtained results a mechanism for P2 Cox-DNA interaction is discussed. The results from this thesis can be used in the development of a gene delivery system based on the P2 site-specific recombination system.

Bacteriophage P2

site-specific recombination

integrase

transcriptional switch

Genetics

Genetik

Investigating the activation and regulation of the proteasome : an essential proteolytic complex

Masson, Patrick

January 2004

The proteasome is a major non-lysosomal proteolytic complex present in eukaryotic cells and has a central role in regulating many protein levels. The complex has been shown to participate in various intracellular pathways including cell cycle regulation or quality control of newly synthesized proteins and many other key pathways. This amazing range of substrates would not be possible without the help of regulators that are able to bind to the 20S proteasome and modulate its activity. Among those, the PA700 or 19S regulator and the PA28 family are the best characterized in higher eukaryotes. The 19S regulatory particle is involved in the recognition of ubiquitinated proteins, targeted for degradation by the proteasome. The PA28 (also termed 11S REG) family is composed of two members the PA28αβ and PA28γ. The function of PA28αβ is related to the adaptive immune response with a proposed contribution in MHC class I peptide presentation whereas the biological role PA28γ remains unknown. The main objectives of the laboratory, and subsequently of this thesis are to use Drosophila melanogaster model system and its advantages to better understand the precise contribution of these different activators in the regulation of the proteasome. Using genomic resources, a unique Drosophila PA28 member was identified, characterized and was shown to be a proteasome regulator with all the properties of PA28γ. Through site-directed mutagenesis we identified a functional nuclear localization signal in the homolog-specific insert region. Study of the promoter region revealed that transcription of Drosophila PA28γ (dPA28γ) gene is under control of DREF, a transcription factor involved in the regulation of genes related to DNA synthesis and cell proliferation. To confirm that dPA28γ has a role in cell cycle progression, the effect of removing dPA28γ from S2 cells was tested using RNA interference. Drosophila cells depleted of dPA28γ showed partial arrest in G1/S cell cycle transition confirming a conserved function between Drosophila and mammalian forms of PA28γ. Finally, characterization of the Dictyostelium regulator, an evolutionarily distant member of the PA28γ, was carried out using fluorogenic degradation assays. We are currently knocking-out the gene in order to determine the biological function of the activator. A second part of my work consisted in the generation of a Drosophila assay used to identify in vivo substrates of the 19S regulator, an assay system that has been originally engineered by Dantuma and coworkers in human cell lines. This was achieved by cloning of GFP behind a series of modified ubiquitins that create substrates degraded through different pathways involving the proteasome pathways. The last project of my thesis concerns the characterization of the mechanism for upregulation of proteasomal gene mRNA after MG132 (proteasome inhibitor) treatment. So far, we found that the 5´-UTR of the genes is responsible for this induction. We are now looking for the precise motif involved in this regulation.

Proteasome

PA28gamma

Transcriptional regulation

Drosophila

26S

Molecular biology

Molekylärbiologi

Genome-Wide Studies on the Molecular Functions of Pax7 in Adult Muscle Satellite Cells

Punch, Vincent

01 June 2011

Pax3 and Pax7 belong to a family of conserved transcription factors that play important and diverse roles in development. In the embryo, they carry out similar roles in neural and somite development, but Pax7 fails to compensate for critical functions of Pax3 in the development of limb musculature. Conversely, in the adult, Pax7 is necessary for the maintenance and survival of muscle satellite cells, whereas Pax3 cannot effectively fulfill these roles in the absence of Pax7. To identify the unique roles of Pax7 in adult muscle cells, we have analyzed global binding of Pax3 and Pax7 by ChIP-Seq. Here, we show that despite highly homologous DNA-binding domains, the majority of binding sites are uniquely recognized by Pax7 and are enriched for homeobox motifs. Genes proximal to conserved, unique Pax7 binding sites cluster into specific functional groups which may reflect the unique biological roles of Pax7. Combining Pax7 binding sites with gene expression data, we describe the regulatory networks directed by Pax7 and show that Pax7 binding is associated with positive gene regulation. Moreover, we show Myf5 is a direct target of Pax7 and identify a novel binding site in the satellite cell control region upstream of Myf5.

Pax7

Skeletal muscle

Transcriptional networks

Satellite cells

Stem cells

Regeneration

Characterization of the four genes encoding cytoplasmic ribosomal protein S15a in Arabidopsis thaliana

Hulm, Jacqueline Louise

31 March 2008

Eukaryotic cytosolic ribosomes are composed of two distinct subunits consisting of four individual ribosomal RNAs and, in Arabidopsis thaliana, 81 ribosomal proteins. Functional subunit assembly is dependent on the production of each ribosomal component. Arabidopsis thaliana r-protein genes exist in multi-gene families ranging in size from two to seven transcriptionally active members. The cytosolic RPS15a gene family consists of four members (RPS15aA, -C, -D and -F) that, at the amino acid level, share 87-100% identity. Using semi-quantitative RT-PCR I have shown that RPS15aC is not expressed and that transcript abundance differs both spatially and temporally among the remaining RPS15a genes in non-treated Arabidopsis tissues and in seedlings following a variety of abiotic stresses. A comprehensive analysis of the RPS15a 5' regulatory regions (RRs) using a series of deletion constructs was used to determine the minimal region required for gene expression and identify putative cis-regulatory elements. Transcription start site mapping using 5' RACE indicated multiple sites of initiation for RPS15aA and -F and only a single site for RPS15aD while all three genes contain a leader intron upstream of the start codon. Analysis of reporter gene activity in transgenic Arabidopsis containing a series of 5' RR deletion::GUS fusions showed that, similar to previous RT-PCR results, there was a trend for mitotically active tissues to stain for GUS activity. Putative cis-elements including the TELO box, PCNA Site II motif and pollen specific elements were identified. However, there was not always a clear correlation between the presence of a putative element and RPS15a transcript abundance or GUS activity. Although variation in transcriptional activity of each RPS15a gene has been observed, subcellular localization of both RPS15aA and -D in the nucleolus has been confirmed in planta by confocal microscopy. The results of this thesis research suggest while all three active RPS15a genes are transcriptionally regulated, additional post-transcriptional and/or translational regulation may be responsible for final RPS15a levels while differential isoform incorporation into ribosomal subunits may be the final point of r-protein regulation.

gene expression

transcriptional regulation

Arabidopsis

S15a

ribosomal protein

ribosome

Characterization of the IIIa protein of porcine adenovirus type 3

Van Kessel, Jill Andrea

26 April 2006

The L1 region of the porcine adenovirus (PAdV)-3 genome encodes a protein of 622 amino acids named IIIa. Although it binds a neighboring group of nine (GON) hexons at the capsid level and cement the icosahedral shell that contains the viral DNA, little is known regarding its function with respect to viral life cycle. Moreover, the known location of IIIa protein in the capsid may help to express targeting ligands for altering the tropism of PAdV-3. The objective of this study was to characterize the IIIa protein of porcine adenovirus Type 3 (PAdV-3). <p> In order to characterize the IIIa protein, polyclonal antisera were raised in rabbits against different regions of IIIa. Anti-IIIa sera detected a specific protein of 70 kDa in PAdV-3 infected cells using Western blot assay. Immunofluorescence studies indicated that IIIa is predominantly localized in the nucleus of PAdV-3 infected cells. Analysis of PAdV-3 IIIa using antibodies specific for N- and C- terminal domains of the protein suggested that although the N-terminus and C-terminal domains of IIIa are immunogenic, they are not exposed on the surface of PAdV-3 virions. These results were further confirmed by our inability to isolate a chimeric PAdV-3 virion containing a heterologous protein fused to the N-terminus or C-terminus of IIIa. <p>Functional analysis suggested that IIIa may transactivate the major late promoter and down regulate the early region (E) 1A promoter. In order to locate the domains of IIIa responsible for different functions, in-frame deleted/truncated forms of IIIa were constructed. Analysis of the deleted/truncated forms of IIIa suggested that a) the sequences located between amino acids 273-410 and between amino acids 410-622b) affect the nuclear localization and transactivation function respectively.<p>Since protein- protein interactions are important for the biological functions of the protein, we determined the interaction of PAdV-3 IIIa with other viral proteins. IIIa was found to interact with DNA binding protein (DBP), E3 13.7 kDa protein, hexon, fiber, and pIX. These results suggest that PAdV3 IIIa may do more in the viral life cycle than merely act as cement between the hexons to maintain capsid stability and may actually be involved in regulating early to late gene transcription at appropriate stages during viral infection.

antibody production

IIIa expression

recombinant adenovirus

nuclear localization

transcriptional activation

Characterization of regulation of expression and nuclear/nucleolar localization of Arabidopsis ribsomal proteins

Savada, Raghavendra Prasad

04 July 2011

Ribosomal proteins (RPs), synthesized in the cytoplasm, need to be transported from the cytoplasm to the nucleolus (a nuclear compartment), where a single molecule of each RP assembles with rRNAs to form the large and small ribosomal subunits. The objectives of this research were to identify nuclear/nucleolar localization signals (NLSs/NoLSs; generally basic motifs) that mediate the transport of Arabidopsis RPL23aA, RPL15A and RPS8A into the nucleus and nucleolus, and to study transcriptional regulation and subcellular localization of RPs. While all previous research has shown that nucleolar localization of proteins is mediated by specific basic motifs, in this study, I showed that a specific number of basic motifs mediated nucleolar localization of RPL23aA, rather than any specific motifs. In this protein, single mutations of any of its eight putative NLSs (pNLSs) had no effect on nucleolar localization, however, the simultaneous mutation of all eight completely disrupted nucleolar localization, but had no effect on nuclear localization. Furthermore, mutation of any four of these pNLSs had no effect on localization, while mutation of more than four increasingly disrupted nucleolar localization, suggesting that any combination of four of the eight pNLSs is able to mediate nucleolar localization. These results support a charge-based system for the nucleolar localization of RPL23aA. While none of the eight pNLSs of RPL23aA were required for nuclear localization, in RPS8A and RPL15A, of the 10 pNLSs in each, the N-terminal two and three NLSs, respectively, were absolutely required for nuclear/nucleolar localization. Considering the presence of only a single molecule of each RP in any given ribosome, which obligates the presence of each RP in the nucleolus in equal quantities, I studied transcriptional regulation of Arabidopsis RP genes and the subcellular localization of five RP families to determine the extent of coordinated regulation of these processes. Variation of up to 300-fold was observed in the expression levels of RP genes. However, this variation was drastically reduced when the expression level was considered at the RP gene family level, indicating that coordinate regulation of expression of RP genes, coding for individual RP isoforms, is more stringent at the family level. Subcellular localization also showed differential targeting of RPs to the cytoplasm, nucleus and nucleolus, together with a significant difference in the nucleolar import rates of RPS8A and RPL15A. Although one could expect coordinated regulation of the processes preceding ribosomal subunit assembly in the nucleolus, my results suggest differential regulation of these processes.

Nuclear/Nucleolar localization

Transcriptional regulation

Arabidopsis

Ribosomal proteins

Ribosomes

Disrupting the Non-specific Interactions between DNA and the Escherichia coli Transcriptional Repressor NikR

Krecisz, Sandra

20 July 2012

The Escherichia coli transcription factor NikR is responsible for nickel-mediated repression of the nik operon. The crystal structure of NikR in complex with its operator sequence provided insight into the mechanistic details of nickel-activated NikR-DNA complex formation. The crystal structure revealed that the α3 helix and its preceding loop (residues 63-79) in two of the metal-binding domains—which become structurally ordered after high-affinity nickel binding—make non-specific contacts with the DNA phosphodiester backbone. The proposed mechanism of NikR binding to DNA suggests that the non-specific interactions between the DNA phosphodiester backbone and the positively-charged residues Lys64 and Arg65 anchor NikR to the DNA, thereby allowing the protein to initiate a one-dimensional search for its recognition sequence. The DNA-binding studies presented here strongly support an important role for Lys64 and Arg65 in NikR-DNA complex formation which is in agreement with the proposed model of NikR binding to DNA.

NikR

nickel

transcription factor

transcriptional repressor

0485

0487

Disrupting the Non-specific Interactions between DNA and the Escherichia coli Transcriptional Repressor NikR

Krecisz, Sandra

20 July 2012

The Escherichia coli transcription factor NikR is responsible for nickel-mediated repression of the nik operon. The crystal structure of NikR in complex with its operator sequence provided insight into the mechanistic details of nickel-activated NikR-DNA complex formation. The crystal structure revealed that the α3 helix and its preceding loop (residues 63-79) in two of the metal-binding domains—which become structurally ordered after high-affinity nickel binding—make non-specific contacts with the DNA phosphodiester backbone. The proposed mechanism of NikR binding to DNA suggests that the non-specific interactions between the DNA phosphodiester backbone and the positively-charged residues Lys64 and Arg65 anchor NikR to the DNA, thereby allowing the protein to initiate a one-dimensional search for its recognition sequence. The DNA-binding studies presented here strongly support an important role for Lys64 and Arg65 in NikR-DNA complex formation which is in agreement with the proposed model of NikR binding to DNA.

NikR

nickel

transcription factor

transcriptional repressor

0485

0487

Regulation of heat shock factor 1 (HSF1) DNA-binding and transcription

Mercier, Philippe Arthur

17 September 2003

Cellular stress invokes a protective response in which heat shock factor 1 (HSF1) is activated to increase heat shock protein (Hsp) expression. HSF1 exists as a latent monomer in unstressed cells. Upon stress HSF1 forms homotrimers, increasing its affinity for the heat shock DNA element upstream of all Hsp genes. A second conformational change is required for HSF1 to gain transcriptional competence. During prolonged heat shock or following the resumption of normal conditions HSF1 DNA-binding and transcriptional activities are reduced and HSF1 returns to the monomeric state in a process called attenuation. During the activation/deactivation cycle HSF1 is modified by small ubiquitin-related modifier (SUMO-1) conjugation and undergoes several phosphorylation and dephosphorylation events that modulate HSF1 activity. Hyperphosphorylation of HSF1 is hypothesized to trigger HSF1 transcriptional activity. HSF1 also interacts with a dynamic series of Hsp90/Hsp70-based chaperone heterocomplexes that negatively regulate DNA-binding, and transcriptional activity, and promote attenuation. This thesis was aimed at characterizing the mechanisms regulating HSF1 DNA-binding, and transcriptional activity. Expression of human HSF1 in Xenopus oocytes altered the set-point of DNA-binding in response to heat indicating that both the cellular environment and innate properties of the molecule allow HSF1 to set its activation/deactivation set-point in response to stress in vivo. HSF1 DNA-binding but not transcription was activated in oocytes treated with a high temperature heat shock. Further characterization of this observation determined that HSF1 activated by a brief high temperature heat shock inhibited transcriptionally competent HSF1 from activating transcription. It was hypothesized that this phenomenon exists to ensure the eventual death of the cell due to the accumulation of excessive damage and potential mutation caused by severe stress. The most significant observation made in this thesis is that Hsp expression was detected in oocytes injected with reporter plasmid only during recovery from a high temperature heat shock. These results led to the proposal of a model in which HSF1 trimers are either assembled in a transcriptionally incompetent form or one that has the potential to become transcriptionally competent during stress, prior to DNA-binding. The identity of HSF1-binding proteins that interact with HSF1 at different stages of activation/deactivation was characterized in an effort to assign regulatory roles to these proteins. HSF1 was detected in a high molecular weight complex (350-600 kDa) during all phases of the activation/deactivation cycle. HSF1 at different stages of activation was tested for interaction with specific molecular chaperones by electrophoretic mobility supershift analysis. Hsp90, p23, FKBP52, Hip and Hop are all associated with transcriptionally active and inactive HSF1 suggesting that interaction of HSF1 with any of these molecules does not activate HSF1 transcriptional activity. These results do not exclude the possibility that the function of these molecular chaperones may change during activation of HSF1 transcription or that post-translational modifications may be the primary mechanism that drives HSF1 from a transcriptionally inactive to active form.

transcriptional inhibitor

DNA-binding

transcription

heat shock

HSF1

The role of protein phosphatase 5 (PP5) in the regulation of heat shock factor 1 (HSF1) in <i>xenopus laevis</i> oocytes

McLoughlin, Christine Louise

22 October 2003

Cells are continuously exposed to a variety of physiological and environmental stresses that can lead to protein aggregation and/or denaturation, and eventually cell death. In order to ensure survival, cells have evolved a stress response that monitors, detects, and responds to changes within the cellular environment. The stress response is characterized by the up-regulation of heat shock protein (hsp) genes whose products can mediate the assembly and/or degradation of misfolded or aggregated proteins within the cell. This stress-induced upregulation of heat shock protein encoding genes is under the regulation of heat shock transcription factor 1 (HSF1) and its associated proteins that together form what is known as the HSF1 heterocomplex. In eukaryotic cells, HSF1 exists as a non-DNA binding monomer in the absence of stress. Upon exposure to stress, HSF1 undergoes trimerization and acquires the ability to bind heat shock elements (HSEs) located upstream of all hsp genes and after further modification, can become converted into a transcriptionally active form. Following prolonged stress or after removal of stress, HSF1 loses its ability to bind DNA and transcription ceases in a process termed attenuation. <p>Several studies have suggested that the DNA-binding and transcriptional activities of HSF1 are regulated by phosphorylation and dephosphorylation events and by chaperone-based folding mechanisms similar to those involved in the regulation of glucocorticoid receptors. Protein phosphatase 5 (PP5) has been identified as a member of the glucocorticoid receptor chaperone complex and its phosphatase activity has been shown to regulate the maturation and activation of the receptor. It has been suggested that PP5 may regulate HSF1 in a manner similar to that of glucocorticoid receptors however it has not yet been determined how PP5 interacts with the HSF1 heterocomplex or if PP5 functions to regulate HSF1-DNA binding and/or HSF1 transactivation.<p>Utilizing the Xenopus model system, I tested the hypothesis that PP5 regulates the DNA binding and transcriptional activities of HSF1 through interactions with the HSF1 heterocomplex. Increasing the activity of PP5, either through the elevation of PP5 protein levels or by activating endogenous PP5, resulted in decreased HSF1-DNA binding as well as accelerated attenuation after the removal of stress. Conversely, inhibiting the phosphatase activity of PP5 using okadaic acid or by immunotargetting, where an antibody recognizing PP5 was microinjected into the nuclei of oocytes, resulted in delayed HSF1 attenuation. Transcription assays performed using activated PP5 also demonstrated that PP5 acts to decrease HSF1-mediated transcription. Immunoprecipitation and gel mobility supershift assays were also used to show that PP5 interacts with the HSF1 heterocomplex and PP5-HSP90 binding mutants illustrated that PP5 may exert its repressive effects independently of binding directly to HSP90.

regulation of HSF1

HSF1 transcriptional activation

HSF1-DNA binding