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Studies of metazoan proteasome function and regulationLundgren, Josefin January 2005 (has links)
Biological processes depend upon the structural and functional quality of the molecules that comprise living organisms. The integrity of molecules such as DNA, RNA, proteins, carbohydrates and lipids is crucial and the precise three-dimensional shape and the detailed chemistry of these molecules orchestrate the biochemical processes vital for life. Within a cell, each protein must be present at a specific concentration during certain specific conditions. To maintain cellular homeostasis and the ability to respond to the environment the proteome is in a dynamic state of synthesis and degradation. In eukaryotic cells the ubiquitin-proteasome pathway is the principal mechanism for regulated protein turnover in both the cytoplasm and the nucleus. The 20S proteasome is a cylindrical multi-subunit protease. Proteasomes play an essential role in the targeted and timely ordered degradation of key regulatory proteins and their inhibitors. The 26S proteasome is a 2.500 kDa complex composed of the 20S proteasome sandwiched between two 19S regulators. This is the enzymatic complex responsible for ATP-dependent ubiquitin mediated protein degradation. A polyubiquitin chain attached to a protein serves as a general recognition signal for destruction via the 26S proteasome. It is known that the 19S regulator confers ubiquitin recognition and substrate unfolding to the 20S proteasome, however, the specific functions for many of the different subunits within the 19S complex are not known. We have used RNA interference to study the S13/Rpn11 and S5a/Rpn10 subunits of Drosophila melanogatser proteasomes. We have produced stable cell lines with the human S13 gene under inducible promoters that was used to rescue the knockdown phenotype after RNA interference. The rescue was successful in demonstrating that the human protein is a functional homologue to the Drosophila protein. We call the technique RNAi+c (RNA interference + complementation). This procedure enabled us to also test different mutants of the human S13 protein for their ability to function in the proteasome. Using RNA interference to a Drosophila proteasome subunit in combination with complementation with a corresponding human protein we have been able to study residues important for the deubiquitinating activity of this subunit (Paper I). Interestingly, upon a decrease of either S13 or S5a we see an induction in the levels of active 20S proteasomes. Increase in the levels of the non-targeted 19S subunit can be detected when RNAi treatment is carried out on either S13 or S5a. We have used RNA interference and proteasomal inhibition together with whole genome microarray analysis to reveal a co-regulated network of proteasome genes. This network likely contributes to an overall regulatory system that maintains proper proteasome levels in the cell. Initial studies of the mechanism of transcriptional co-regulation of proteins involved in the 26S proteasome pathway were also performed (Paper II). Finally, the biological function of the proteasome regulator PA28g/REGg is not known. We have studied this regulator in Drosophila using RNA interference and promoter mapping (Paper III).
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Hsp70 nucleotide exchange factor Fes1 is essential for ubiquitin-dependent degradation of misfolded cytosolic proteinsGowda, Naveen Kumar Chandappa, Kandasamy, Ganapathi, Froehlich, Marceli S., Dohmen, R. Jürgen, Andréasson, Claes January 2013 (has links)
Protein quality control systems protect cells against the accumulation of toxic misfolded proteins by promoting their selective degradation. Malfunctions of quality control systems are linked to aging and neurodegenerative disease. Folding of polypeptides is facilitated by the association of 70 kDa Heat shock protein (Hsp70) molecular chaperones. If folding cannot be achieved, Hsp70 interacts with ubiquitylation enzymes that promote the proteasomal degradation of the misfolded protein. However, the factors that direct Hsp70 substrates toward the degradation machinery have remained unknown. Here, we identify Fes1, an Hsp70 nucleotide exchange factor of hitherto unclear physiological function, as a cytosolic triaging factor that promotes proteasomal degradation of misfolded proteins. Fes1 selectively interacts with misfolded proteins bound by Hsp70 and triggers their release from the chaperone. In the absence of Fes1, misfolded proteins fail to undergo polyubiquitylation, aggregate, and induce a strong heat shock response. Our findings reveal that Hsp70 direct proteins toward either folding or degradation by using distinct nucleotide exchange factors.
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Analysis of functional domains required for hRad18 interactions with HHR6B and hUbc9Ma, Xinfeng 29 March 2006
DNA post-replication repair (PRR) is a cellular tolerance mechanism by which eukaryotic cells survive lethal lesions during or after DNA synthesis. In the yeast Saccharomyces cerevisiae, modification of proliferating cell nuclear antigen (PCNA) by ubiquitin and by small ubiquitin-like modifier (SUMO) plays an important role in PRR. PCNA ubiquitination is dependent on Rad6, a ubiquitin-conjugating enzyme (E2) and Rad18, a ubiquitin ligase (E3). Rad6 and Rad18 form a stable complex. PCNA sumoylation is dependent on Ubc9, an E2 specific to SUMO modification. <p>PRR in mammalian cells is less well understood. However, human Rad18 (hRad18) has been found to interact with human Rad6 (HHR6A/B). In this study, we detected physical interaction between hRad18 and human Ubc9 (hUbc9) through yeast two-hybrid assays. In order to define the domain(s) of hRad18 involved in the formation of a complex with HHR6B or hUbc9, a series of yeast two-hybrid constructs containing various hRAD18 gene deletions and mutations were made. A C-terminal region of hRad18, containing the putative HHR6A/B binding domain (amino acids 340 to 395), interacts with HHR6A/B while the N-terminus (amino acids 1-93) does not. Yeast Rad18 has a homologous fragment of the HHR6A/B binding domain and this fragment is sufficient to interact with yeast Rad6 in yeast two-hybrid assays, so we infer that hRad18 interacts with HHR6B through the same domain. Surprisingly, both the N-terminal and C-terminal fragments of hRad18 can interact with hUbc9, suggesting the existence of two separate domains in hRad18 interacting with hUbc9. The N-terminal fragment of hRad18 contains only a RING finger domain (amino acids 25-64), which is probably responsible for binding to hUbc9. The C-terminal fragment of hRad18 with HHR6A/B binding domain deletion can still interact with hUbc9, suggesting that the HHR6A/B binding domain is not involved in hUbc9 interaction. A key cysteine mutation (C28F) in the RING finger domain abolished the interactions of hRad18 with both HHR6A/B and hUbc9. This amino acid substitution is likely to alter the three-dimensional structure of the protein, thus making the protein unstable. Taken together, results obtained from this study suggest that hRad18 may regulate the modification status of PCNA by interacting with two different E2s, HHR6A/B and hUbc9, through distinct domains.
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Characterization of the E3 Ubiquitin ligase EEL-1 in DNA Damage-induced Germ Line Apoptosis in C. elegansRoss, Ashley Jane 28 July 2010 (has links)
E3 ubiquitin ligases are important regulators of several cellular processes, including apoptosis. To determine the extent to which E3 ligases regulate DNA damage-induced apoptotic signalling in C. elegans, a high-throughput RNAi screen was performed in our laboratory. We identified the E3 ubiquitin ligase EEL-1 as a positive regulator of DNA damage-induced germ cell apoptosis. ARF-BP1, the mammalian EEL-1 ortholog, negatively regulates both the tumour suppressor protein p53 and the anti-apoptotic protein Mcl-1. In C. elegans, we found that eel-1 regulates DNA damage-induced germ cell apoptosis by a mechanism downstream of cep-1/p53 and upstream of ced-9/mcl-1. My results show that unlike ARF-BP1, EEL-1 does not regulate CED-9/Mcl-1 protein levels, suggesting a novel mechanism of apoptosis regulation in C. elegans for this E3 ligase. Unexpectedly, eel-1 causes synthetic sterility in ced-9 loss-of-function mutants that is suppressed by ablation of the Apaf-1 orthologue ced-4, suggesting an additional role for these genes in oogenesis.
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Role of DNedd4 Splice Isoforms in Neuromuscular Synaptogenesis in Drosophila MelanogasterZhong, Yunan 01 June 2011 (has links)
Drosophila Nedd4 (DNedd4), an E3 ubiquitin ligase, is known to be involved in neuromuscular (NM) synaptogenesis during embryogenesis. To further elucidate its mechanism and function in this process, two major splice isoforms, dNedd4 short (dNedd4S) and dNedd4 long (dNedd4L), were studied. My work shows that while dNedd4S positively regulates NM synaptogenesis, dNedd4L plays a negative role in this process. Unique regions in dNedd4L, including the N-terminal 66 amino acid-long sequence (but not the putative dAkt phosphorylation site) and the middle 159 amino acid-long sequence, as well as the catalytic site, are required for its negative function. I proposed one possible mechanism of dNedd4L acting as a negative regulator of dNedd4S. Results from my studies of the putative effect of dNedd4L on the catalytic activity of dNedd4S in vitro, as well as on the function of dNedd4S towards Comm in Drosophila S2 cells, did not support this mechanism.
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Characterization of the E3 Ubiquitin ligase EEL-1 in DNA Damage-induced Germ Line Apoptosis in C. elegansRoss, Ashley Jane 28 July 2010 (has links)
E3 ubiquitin ligases are important regulators of several cellular processes, including apoptosis. To determine the extent to which E3 ligases regulate DNA damage-induced apoptotic signalling in C. elegans, a high-throughput RNAi screen was performed in our laboratory. We identified the E3 ubiquitin ligase EEL-1 as a positive regulator of DNA damage-induced germ cell apoptosis. ARF-BP1, the mammalian EEL-1 ortholog, negatively regulates both the tumour suppressor protein p53 and the anti-apoptotic protein Mcl-1. In C. elegans, we found that eel-1 regulates DNA damage-induced germ cell apoptosis by a mechanism downstream of cep-1/p53 and upstream of ced-9/mcl-1. My results show that unlike ARF-BP1, EEL-1 does not regulate CED-9/Mcl-1 protein levels, suggesting a novel mechanism of apoptosis regulation in C. elegans for this E3 ligase. Unexpectedly, eel-1 causes synthetic sterility in ced-9 loss-of-function mutants that is suppressed by ablation of the Apaf-1 orthologue ced-4, suggesting an additional role for these genes in oogenesis.
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Role of DNedd4 Splice Isoforms in Neuromuscular Synaptogenesis in Drosophila MelanogasterZhong, Yunan 01 June 2011 (has links)
Drosophila Nedd4 (DNedd4), an E3 ubiquitin ligase, is known to be involved in neuromuscular (NM) synaptogenesis during embryogenesis. To further elucidate its mechanism and function in this process, two major splice isoforms, dNedd4 short (dNedd4S) and dNedd4 long (dNedd4L), were studied. My work shows that while dNedd4S positively regulates NM synaptogenesis, dNedd4L plays a negative role in this process. Unique regions in dNedd4L, including the N-terminal 66 amino acid-long sequence (but not the putative dAkt phosphorylation site) and the middle 159 amino acid-long sequence, as well as the catalytic site, are required for its negative function. I proposed one possible mechanism of dNedd4L acting as a negative regulator of dNedd4S. Results from my studies of the putative effect of dNedd4L on the catalytic activity of dNedd4S in vitro, as well as on the function of dNedd4S towards Comm in Drosophila S2 cells, did not support this mechanism.
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Structural and Functional Analysis of Two Novel Protein Ligases, Dcn1 and IpaHChou, Yang-Chieh 05 January 2012 (has links)
The ubiquitination pathway regulates virtually all cellular processes such as cell cycle control and immune surveillance in eukaryotes, and is thus highly regulated through a variety of means. For instance, the Cullin-RING ubiquitin E3 ligases are regulated by neddylation through the action of a newly identified protein Dcn1. In chapter two, I describe an X-ray crystal structure of yeast Dcn1, encompassing an N-terminal ubiquitin association (UBA) domain and a C-terminal domain of unique architecture, which I termed the PONY (POtentiating NeddYlation) domain. I describe the identification of the reciprocal, conserved binding surfaces on both Dcn1 and yeast cullin Cdc53. In collaboration with Dr. Matthias Peter’s group (ETH Zurich), we show that Dcn1 is necessary and sufficient for cullin neddylation in a purified recombinant system. Together, our data identify Dcn1 as the long sought-after Nedd8 E3 ligase for cullin neddylation.
As a modulator of immune surveillance and inflammatory responses, the ubiquitin system serves as an attractive target for subversion by pathogens. In chapter three, I present a structural and functional analysis of a newly identified bacterial ubiquitin E3 ligase IpaH, present in various pathogenic and commensal bacteria. I demonstrate that the leucine-rich repeat (LRR) substrate recognition domains of different IpaH enzymes auto-inhibit the enzymatic activity of the adjacent catalytic domain by two distinct but conserved structural mechanisms. Auto-inhibition is required for the biological activity of two IpaH enzymes in a yeast model system. Retro-engineering of auto-inhibition into a constitutively active IpaH enzyme from Yersinia demonstrates that most of the infrastructure required to support auto-inhibition is evolutionarily conserved.
In brief, my research provides insights into the mechanism of action of two newly identified protein ligases in the ubiquitination pathway, namely the Nedd8 E3 ligase Dcn1 and bacterial ubiquitin E3 ligase IpaH.
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Structural and Functional Analysis of Two Novel Protein Ligases, Dcn1 and IpaHChou, Yang-Chieh 05 January 2012 (has links)
The ubiquitination pathway regulates virtually all cellular processes such as cell cycle control and immune surveillance in eukaryotes, and is thus highly regulated through a variety of means. For instance, the Cullin-RING ubiquitin E3 ligases are regulated by neddylation through the action of a newly identified protein Dcn1. In chapter two, I describe an X-ray crystal structure of yeast Dcn1, encompassing an N-terminal ubiquitin association (UBA) domain and a C-terminal domain of unique architecture, which I termed the PONY (POtentiating NeddYlation) domain. I describe the identification of the reciprocal, conserved binding surfaces on both Dcn1 and yeast cullin Cdc53. In collaboration with Dr. Matthias Peter’s group (ETH Zurich), we show that Dcn1 is necessary and sufficient for cullin neddylation in a purified recombinant system. Together, our data identify Dcn1 as the long sought-after Nedd8 E3 ligase for cullin neddylation.
As a modulator of immune surveillance and inflammatory responses, the ubiquitin system serves as an attractive target for subversion by pathogens. In chapter three, I present a structural and functional analysis of a newly identified bacterial ubiquitin E3 ligase IpaH, present in various pathogenic and commensal bacteria. I demonstrate that the leucine-rich repeat (LRR) substrate recognition domains of different IpaH enzymes auto-inhibit the enzymatic activity of the adjacent catalytic domain by two distinct but conserved structural mechanisms. Auto-inhibition is required for the biological activity of two IpaH enzymes in a yeast model system. Retro-engineering of auto-inhibition into a constitutively active IpaH enzyme from Yersinia demonstrates that most of the infrastructure required to support auto-inhibition is evolutionarily conserved.
In brief, my research provides insights into the mechanism of action of two newly identified protein ligases in the ubiquitination pathway, namely the Nedd8 E3 ligase Dcn1 and bacterial ubiquitin E3 ligase IpaH.
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Studies on UEV, a new regulator of polyubiquitination: Functional aspects and genomic analysisLoukili, Moureddine 28 May 2002 (has links)
No description available.
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