Understanding in vivo Significance of Allosteric Regulation in mtHsp70s : Revealing its Implications in Parkinson's Disease Progression

Samaddar, Madhuja

January 2015

Mitochondria are essential eukaryotic organelles, acting as the sites for numerous crucial metabolic and signalling pathways. The biogenesis of mitochondria requires efficient targeting of several hundreds of proteins from the cytosol, to their varied functional locations within the organelle. The translocation of localized proteins across the inner membrane, and their subsequent folding is achieved by the ATP-dependent function of mitochondrial Hsp70 (mtHsp70). It is a bonafide member of the Hsp70 chaperone family, which are involved in a multitude of functions, together aimed at protein quality control and maintenance of cellular homeostasis. These varied functions of Hsp70 proteins require binding to exposed hydrophobic patches in substrate polypeptides thus preventing non-productive associations. The interaction with substrates occurs through the substrate-binding domain (SBD) and is regulated by the ATPase activity of the nucleotide-binding domain (NBD), through a series of conformational changes. Conversely, substrate binding to the SBD also stimulates ATP hydrolysis, and thereby the core activities of the two domains are regulated by mutual allosteric signalling. This mechanism of bidirectional inter-domain communication is indispensable for Hsp70 function, which is characterized by cycles of substrate binding and release, coupled to cycles of ATP binding and hydrolysis. The process of allosteric regulation in Hsp70 proteins has been comprehensively investigated, especially in the bacterial homolog, DnaK. However, the in vivo functional significance of inter-domain communication in the eukaryotic mtHsp70 system and the mechanism of its regulation remain unexplored. Furthermore, the complex physiological implications of impairment in allosteric communication and their correlation with diverse disease conditions, including Myelodysplastic syndrome (MDS), and Parkinson’s disease (PD), are yet to be elucidated. Based on this brief introduction, the primary research objectives set out in the present thesis were to: 1. uncover the regulation of ligand-modulated allosteric communication between the two domains of mtHsp70; and its in vivo significance in the context of protein import into the organelle. (Chapter 2) 2. understand the role of mtHsp70 in progression of Parkinson’s disease; and to study the modulation of α-synuclein toxicity by the protein quality control function of the mtHsp70 chaperone network. (Chapters 3 and 4) We have employed a battery of genetic and biochemical approaches to investigate the above questions using the Saccharomyces cerevisiae mtHsp70 protein, Ssc1; an essential protein that is involved in a plethora of critical functions in this eukaryotic model system. Objective 1: Structural studies, primarily in bacterial DnaK, have yielded mechanistic insights into its interactions with ligands and cochaperones, as well as conformational transitions in different ligand-bound states. In recent years, the availability of crystal structures of full-length DnaK and detailed information from NMR studies and single-molecule resolution spectroscopic analyses (both DnaK and eukaryotic Hsp70s), have significantly contributed to our understanding of the inter-domain interface, critical residues and contacts, and the energetics of the entire process of ligand-modulated conformational changes. Although eukaryotic mtHsp70s have a high degree of conservation with DnaK, they possess significant differences in their conformational and biochemical properties. They are essential for a vast repertoire of physiological functions, which are distinctly different from their bacterial counterpart. Using a combined in vivo and in vitro approach, we have uncovered specific structural elements within mtHsp70s, which are required for allosteric modulation of the chaperone cycle and maintenance of in vivo functions of the protein. Foremost, we demonstrate that a conserved SBD loop, L4,5 plays a critical role in inter-domain communication, and multiple mutations in this loop result in significant growth and protein translocation defects. The mutants are associated with a specific set of altered biochemical properties, which are indicative of impaired inter-domain communication. Using the loop L4,5 mutant, E467A as a template for genetic screening, we report a series of intragenic suppressor mutations, which are capable of correcting a distinct subset of the altered properties, and thereby leading to restoration of in vivo functions, including growth, preprotein import and mitochondria biogenesis. The suppressors modify the altered conformational landscape associated with E467A, and also provide us with information regarding unique aspects governing the regulation of allosteric communication, especially in physiological contexts. Strikingly, they reveal that restoration of communication in the NBD to SBD direction is sufficient for function, when the protein is primed in a high ATPase activity state. In this unique scenario, the requirement for ATPase stimulation upon substrate binding is rendered unnecessary, thereby making conformational changes in the SBD to NBD direction, dispensable for function. Further, we provide evidence to show that loop L4,5 functions synergistically with the linker region, working in tandem for organization of the inter-domain interface and propagation of communication. Together, our analyses provide the first insights into regulation of allosteric inter-domain communication in vivo and their implications in mitochondrial protein translocation and organelle biogenesis. Objective 2: Point mutations in the loop L4,5 have been associated with Myelodysplastic syndrome. Additionally, a mutation isolated in clinical cases of Parkinson’s disease was found to be impaired in allosteric communication. These observations further highlight the importance of efficient inter-domain communication in mtHsp70 in the complex physiological scenario of eukaryotic cells. Independent clinical screens of PD patients have revealed unique point mutations in the mtHsp70 and a strong association of the gene locus with the disease progression. This is also correlated with decreased mtHsp70 levels in affected neurons and the interactions of this protein with established PD-candidate proteins like α-synuclein and Dj-1. Further, mitochondrial dysfunction is a common phenomenon associated with neurodegenerative disorders. To understand the specific role of mtHsp70 in PD, we have developed a yeast model for studying the disease variants in isolation from other players of the multifactorial disease, and in complete absence of the wild type protein. We generated two analogous PD-mutations in Ssc1, R103W and P486S; which recapitulated the symptoms of mitochondrial dysfunction in affected neurons, including cell death, inner membrane depolarization, increased generation of ROS, and respiratory incompetence. At the molecular level, we observed an increased aggregation propensity of R103W, while P486S exhibited futile enhanced interaction with J-protein cochaperone partners thereby resulting in loss of chaperoning activity and impaired mitochondrial protein quality control. Remarkably, these altered biochemical properties mimicked similar defects in the human mtHsp70 variants, therefore, affirming the involvement of mtHsp70 in PD progression. To further investigate the relevance of impaired mitochondrial protein quality control in PD, we have explored whether mtHsp70 can act as a genetic modifier of α-synuclein toxicity. It is known that α-synuclein can act as an unfolded substrate for the Hsp70 chaperone system and also deposits as intracellular aggregates in PD-affected brains. Intriguingly, it is known to translocate into mitochondria under conditions of neuronal stress in spite of lacking a canonical mitochondrial signal sequence. Utilizing our yeast-PD model, we find that targeting of α-synuclein A30P disease variant into mitochondria leads to a severe mitochondrial dysfunction phenotype in the wild type Ssc1 background, but not the P486S mutant background. This results in multiple cellular manifestations, which are reversed upon overexpression of the Ssc1 chaperone. Significantly, increasing the J-protein cochaperone availability also leads to reversal of the mutant-associated defects. However, the simultaneous overexpression of both together does not additively improve the protective effects; highlighting the importance of the relative availability of chaperone and cochaperone proteins in preventing aggregation. Our analyses further reveal that while both the wild type and P486S Ssc1 proteins are equally capable of delaying aggregation of α-synuclein, only the wild-type chaperone is better able to prevent aggregation in the presence of its J-protein cochaperone, leading to accumulation of soluble oligomeric species. These observations raised the intriguing possibility, that the reduced chaperoning ability of the proline to serine PD-mutant is, in fact, a compensatory adaptation, favoring the aggregation of α-synuclein over its more toxic soluble oligomeric form. We verify this hypothesis with the aggregation kinetics of A30P α-synuclein, whose intrinsically lower aggregation tendency results in a pronounced delay in aggregation with the wild-type chaperone, thereby strongly favoring the toxic oligomeric species and correlating with the observed lethality in yeast cells. In conclusion, our study provides a model of α-synuclein aggregation-related toxicity and its modulation by the extent of protein quality control within the mitochondrial matrix, through the action of the mtHsp70 chaperone network.

Eukaryotic Organelle

Mitochonodria

Parkinson's Disease Progression

Mitochondrial Heat Shock Protein 70

Hsp70 Proteins

Saccharomyces cerevisiae mtHsp70 Protein

Allosteric Regulation

Mitochondrial Protein Import

Mitochondria Biogenesis

Mitochondrial HSP70 Chaperon Network

Heat Shock Proteins

mtHSp70

mtHsp70s

Parkinson's Disease

Biochemistry

Reading 'Ruth' in the Restoration period : a call for inclusion

Jones, Edward Allen

January 2012

This study considers the origin and purpose of Ruth and concludes that it is best to read the narrative as a call for an inclusive attitude toward any person, Jew or Gentile, who desired to join the Judean community in the Restoration period. In chapter one, I review the difficulties that scholars face in ascertaining Ruth's place in Israel's history, and I outline approaches that they have used to try to establish its purpose and origin. I discuss major interpretive positions, which date the book either to the monarchic period, to the exilic period, or to the Restoration period, and I articulate the format of my own study. In chapter two, I consider how the author of Ruth uses characterization to highlight Ruth, a Gentile outsider, and to criticize the Bethlehemite community. Only Boaz accepts Ruth, which leads to his participation in the line of David. In chapter three, I discuss how the author also magnifies Ruth's character by comparing her with Israel's ancestors. In these ways, Ruth demonstrates that an outsider can embody the ideals of the Restoration community and that they can also be a benefit to the nation. In chapters four and five, I examine arguments for dating Ruth to particular periods in Israel's history. In chapter four, I consider efforts to date the language of Ruth as well as the legal practices that the story describes. I also discuss the narrative's supposed congruence with the concerns of various social settings in Israel's history. In chapter five, I draw on current research on refugee communities to see how the experiences of such people can help us understand the concerns of the Restoration community. In chapter six, I review my arguments for regarding Ruth as a call for inclusion in the Restoration period, and I consider how this conclusion should affect the field of Ruth studies as well as the wider field of Second Temple studies.

222

Studies On Phosphorylation And Oligomerization Of Rotavirus Nonstructural Protein 5 (NSP5) And Cellular Pathways That Regulate Virus Replication

Namsa, Nima Dondu

07 1900

Rotavirus is one of the leading etiological agents of gastroenteritis in young of many species including humans worldwide and is responsible for about 600,000 infant deaths per annum. Rotavirus belongs to the Reoviridae family, and its genome is composed of 11 double-stranded RNA segments that encode six structural proteins and six nonstructural proteins. Rotavirus replication is fully cytoplasmic and occurs within highly specialized regions called viroplasms. NSP2 and NSP5 have been shown to be essential for viroplasm formation and, when co-expressed in uninfected cells, to form viroplasm¬like structures. A recent study suggest a key role for NSP5 in architectural assembly of viroplasms and in recruitment of viroplasmic proteins, containing four structural (VP1, VP2, VP3 and VP6) and two nonstructural (NSP2 and NSP5) proteins. NSP5, the translation product of gene segment 11 has a predicted molecular eight of 21 kDa. NSP5 has been reported to exist in multiple isoforms ranging in size from 28-and 32-35 kDa from a 26-kDa precursor has been attributed to O-glycosylation and hyperphosphorylation. To study different properties of the protein, recombinant NSP5 containing an N-terminal hisidine tag was expressed in bacteria and purified by affinity chromatography. A significant observation was the similarity in phosphorylation property of the bacterially expressed and that expressed in mammalian cells. While the untagged recombinant protein failed to undergo phosphorylation in vitro, addition of His tag or deletions at the N-terminus promoted phosphorylation of the protein in vitro, which is very similar to the reported properties exhibited by the corresponding proteins expressed in mammalian cells. Phosphorylation of NSP5 in vitro is independent of the cell type from which the extract is derived suggesting that the kinases that phosphorylate NSP5 are distributed in all cell types. Among the C-terminal deletion mutants studied, NH-∆C5 and NH-∆C10 were phosphorylated better than full-length NSP5, but NH-∆C25 and NH¬∆C35 showed substantial reduction in the level of phosphorylation compared to full-length NSP5. These results indicate that the C-terminal 30 residues spanning the predicted α-helical domain of NSP5 are critical for its phosphorylation in vitro which is in correspondence with previous findings that C-terminal 21 amino acids of NSP5 direct its insolubility, hyperphosphorylation, and VLS formation. The results revealed that though the tagged full-length and some of the mutants could be phosphorylated in vitro, they are not suitable substrates for hyperphosphorylation unlike the similar proteins expressed in mammalian cells or infected cells. Analysis by western blot and mass spectrometry revealed that the bacterially expressed NH-NSP5 is indeed phosphorylated. It appears that prior phosphorylation in bacteria renders the protein conformationally not amendable for hyperphosphorylation by cellular kinases in vitro. Mutation of the highly conserved proline marginally enhanced its phosphorylation in vitro but the stability of protein is affected. Notably, mutation of S67A, identified as a critical residue for the putative caesin kinase-I and-II pathways of NSP5 phosphorylation, affected neither the phosphorylation nor the ATPase activity of NSP5. These results suggest that bacterially expressed NSP5 by itself has undectable auto-kinase activity and it is hypophosphorylated. Purified recombinant NSP5 has been reported to possess an Mg¬ 2+-dependent ATP-specific triphosphatase activity. The results indicated that deletion of either C-terminal 48 amino acids or N-terminal 33 residues severely affected the ATPase activity of recombinant NSP5, underlying the importance of both N-and C-terminal domains for NSP5 ATP hydrolysis function. NSP5 expressed in rotavirus infected cells exists as inter-molecular disulfide-linked dimeric forms and it appears that the 46 kDa isoforms, that are phosphorylated, corresponds to dimer as revealed by western blotting. Analytical gel filtration analysis of NH-NSP5, NH-ΔN43 and NH-ΔN33-ΔC25 showed most of the proteins in void volume, but an additional peak corresponding to the mass of dimeric species further supports that NSP5 is basically a dimer that undergoes oligomerization. Analysis by sucrose-gradient fractionation revealed that NH-NSP5 and NH-ΔN43 proteins were mainly distributed in the lower fraction of the gradient suggesting the existence of high molecular weight complexes or higher oligomers. The multimeric nature of NSP5 and its mutants was further confirmed by dynamic light scattering which suggests that high molecular weight complexes are of homogenous species. The correlation curves showed a low polydispersity distribution and a globular nature of recombinant NH-NSP5 proteins. The present results clearly demonstrate that dimer is the basic structural unit of NSP5 which undergoes oligomerization to form a complex consisting of about 20-21 dimers. The nonstructural protein 5 is hyperphosphorylated in infected cells and cellular kinases have been implicated to be involved in its phosphorylation. NSP5 contains multiple consensus sites for phosphorylation by several kinases, but the cellular kinases that specifically phosphorylate NSP5 in infected cells are yet to be identified. Previous studies from our laboratory using signaling pathway inhibitors revealed that recombinant NH¬NSP5 and its deletion mutants can be phosphorylated in vitro by purified cellular kinases and by mammalian cell extracts. These studies also showed the involvement of PI3K-Akt and MAPK signaling pathways in NSP5 phosphorylation and a negative role for GSK3β in the phosphorylation of bacterially expressed recombinant NSP5 in vitro. In the present work, using phospho-specific anti-Ser9 GSK3β antibody, we observed that GSK3β is inactivated in a rotavirus infected MA104 cells in a strain-independent manner. GSK3β¬specific small interfering RNA (siRNA-GSK3β) reduced GSK3β levels leading to increased level of synthesis of the structural rotavirus protein VP6 and NSP5 hyperphosphorylation compared to control siRNA. The pharmacological kinase inhibitors (LY294002, Genistein, PD98059, and Rapamycin) studies at the concentrations tested did not significantly affect rotavirus infection as seen from the number foci, while U0126 severely affected rotavirus replication. The results clearly demonstrated the importance of the MEK1/2 signaling pathway in the successful replication of rotavirus and NSP5 hyperphosphorylation in rotavirus-infected cells. In contrast inhibition of GSK3β activity by LiCl, increased in general, the number of foci by greater than 2-fold for all viral strains studied. These results suggest that MEK1/2 pathway majorly contributes to GSK3β inactivation in rotavirus infected cells. Thus, our results reveal that rotavirus activates both the PI3K/Akt and FAK/ERK1/2 MAPK pathways and appears to utilize them as a strategy to activate mTOR, and inhibit GSK3β through phosphorylation on serine 9, the negative regulator of rotavirus NSP5 phosphorylation, and thus facilitate translational competence of rotaviral mRNAs during virus replication cycle. It was shown previously in the laboratory by co-immunoprecipitation assay that Hsp70 interacts with rotaviral proteins VP1 and VP4 in rotavirus-infected mammalian cells. In this study, the interactions between Hsp70 with VP1 and VP4 were further evaluated in vitro by GST-pull down assay. It was observed that the N-terminal ATPase and C-terminal peptide-binding domain of Hsp70 is necessary for its direct interaction with VP1 and VP4. The presence of Hsp70 in purified double-and triple-layered virus particles further supported the observed interactions of rotaviral proteins VP1 and VP4 with Hsp70. However, the specific interaction observed between Hsp70 and rotaviral capsid proteins, VP1 and VP4 in viral particles suggests that Hsp70 has an important role during rotavirus assembly which requires further investigation.

Rotaviruses

Rotaviral Nonstructural Proteins

Nonstructural Protein

Viral Proteins

Heat Shock Protein 70 (Hsp70)

Viral Replication

Rotaviral Replication

Rotavirus Nonstructural Protein 5 (NSP5)

Rotavirus

Rotaviral Structural Proteins

Rotaviral Proteins

Nonstructural Protein 5

VP1

VP4

Virology

Na čí straně stojíš? Radikální levice v poválečném Finsku - fenomén marxismu-leninismu v zemi mimo východní blok / Whose side are you on? Radical Left in postwar Finland - on the phenomenon of Marxism-Leninism outside the Eastern Bloc

Skálová, Barbora

January 2021

Barbora Skálová Whose side are you on? Radical Left in postwar Finland - on the phenomenon of Marxism-Leninism outside the Eastern Bloc Abstract The dissertation aims to explore the phenomenon of a radical left movement - Taistoists - which at the turn of the 60s and 70s for a short period of time dominated the student and cultural circles in Finland. The dissertation strives to shed light on the reasons for the uprise of the - in European context unique - pro-Soviet, Marxist-Leninist and "anti-anti- establishment" youth movement, and on its influence on home and foreign policy of Finland in terms of so-called Finlandization. The work also puts the movement into the Czechoslovakian context, mainly in relation to the 1968 Warsaw Pact invasion. The dissertation discusses the theoretical anticapitalistic background of the movement and compares it to the theoretical background and political practice of coeval New Left movements in Europe and the USA. The experience of the members of the movement has been elaborated in the oral history part based on personal interviews. The oral history chapter aims to offer an explanation and a broader perspective of the taistolaiset phenomenon presented by direct witnesses and participants of the movement.

Umělkyně tvořící v okruhu českého undergroundu / Women-artist of the Czech underground movement

Kubáč, Vilém

January 2020

Women-artist of the Czech underground movement Abstract The thesis will deal with the artworks by woman artists, who lived and created in Czech underground subculture of the 1970s and 1980s Czechoslovakia. Underground subculture was rather a lifestyle and dislike to the establishment. The thesis focuses on woman artists, for example, Naďa Plíšková, Zorka Ságlová, Kateřina Černá, Věra Jirousová, Juliána Jirousová, Iva Vodrážková and some others. It will examine if women, who were making art in the Czech underground subculture, had any female specificity of artworks, personal life or their position in the underground community. Keywords Czech Underground Culture in 1970s and 1980s, Communism, Normalization, Feminism, Independent Domestic Structures, Czech and Czechoslovak Art

Vliv druhu a dávky polymeru na vlastnosti modifikovaných pojiv / Influence of

Dostál, Filip

January 2020

The diploma thesis is focused on polymer modified binders with different polymer doses. The theoretical part describes the history of the use of bitumen, the extraction of bitumen from oil and behavious of the polymer type SBS/SB, which is used in the diploma thesis on modified binders. Further, the theoretical part describes the empirical and functional tests of bitumen binders. In the practical part the results of indidual tests are presented and compared with the standard ČSN 65 7222-1. At the end of the diploma thesis are summarized results of work and evaluation of binders with the best achieved properties.

Editorial Frühjahr 2018

22 July 2019

No description available.

info:eu-repo/classification/ddc/290

ddc:290

info:eu-repo/classification/ddc/940

ddc:940

Způsoby získávání tabuizovaných informací o drogách narkomany v Československu / Ways of Obtaining Taboo Information about Drugs by Addicts in Czechoslovakia

Poštolková, Lucie

January 2013

This thesis deals with the transmission of information about hard drugs which were concealed by social system in the 70th and 80th of 20th century from perspectives of drug users. We focus on the problematics of informational sources and channels by means of the social system and the systems theory of Niklas Luhmann. We analyse, by using grounded theory, information environment which influenced the drug subculture. The data sources consist of 35 interviews with addicts who were actively taking hard drugs before 1989. The aim of this thesis is a comprehensive look at the functioning of the drug subculture, transmission of taboo information in society 70th and 80th of 20th century by the theory of social capital and social systems.

Třetí pilíř zahraniční politiky? Západoněmecká zahraniční kulturní politika v 60. a 70. letech 20. století / The Third Pillar of Foreign Policy? West German Foreign Cultural Policy in the 1960s and 1970s

Baštová, Petra

January 2016

This doctoral thesis deals with fundamental changes in West German foreign cultural policy during the 1960s and 1970s. Its objective is not only to examine how and under what circumstances the first (West) German conception of foreign cultural policy was conceived or which institutions and individuals participated most actively in its formation, but also to assess the understanding and definitions of foreign cultural policy and its role in the overall foreign policy of the Federal Republic of Germany. Further, the topic is analysed within a broad historical and international context. The research primarily uses the methodology of political history but has also been inspired by cultural history and political science.

Functional Effects of ARV-1502 Analogs Against Bacterial Hsp70 and Implications for Antimicrobial Activity

Brakel, Alexandra, Kolano, Lisa, Kraus, Carl N., Otvos Jr, Laszlo, Hoffmann, Ralf

03 April 2023

The antimicrobial peptide (AMP) ARV-1502 was designed based on naturally occurring short proline-rich AMPs, including pyrrhocoricin and drosocin. Identification of chaperone DnaK as a therapeutic target in Escherichia coli triggered intense research on the ligand- DnaK-interactions using fluorescence polarization and X-ray crystallography to reveal the binding motif and characterize the influence of the chaperone on protein refolding activity, especially in stress situations. In continuation of this research, 182 analogs of ARV-1502 were designed by substituting residues involved in antimicrobial activity against Gramnegative pathogens. The peptides synthesized on solid-phase were examined for their binding to E. coli and S. aureus DnaK providing 15 analogs with improved binding characteristics for at least one DnaK. These 15 analogs were distinguished from the original sequence by their increased hydrophobicity parameters. Additionally, the influence of the entire DnaK chaperone system, including co-chaperones DnaJ and GrpE on refolding and ATPase activity, was investigated. The increasingly hydrophobic peptides showed a stronger inhibitory effect on the refolding activity of E. coli chaperones, reducing protein refolding by up to 64%. However, these more hydrophobic peptides had only a minor effect on the ATPase activity. The most dramatic changes on the ATPase activity involved peptides with aspartate substitutions. Interestingly, these peptides resulted in a 59% reduction of the ATPase activity in the E. coli chaperone system whereas they stimulated the ATPase activity in the S. aureus system up to 220%. Of particular note is the improvement of the antimicrobial activity against S. aureus from originally >128 μg/mL to as low as 16 μg/mL. Only a single analog exhibited improved activity over the original value of 8 μg/mL against E. coli. Overall, the various moderate-throughput screenings established here allowed identifying (un)favored substitutions on 1) DnaK binding, 2) the ATPase activity of DnaK, 3) the refolding activity of DnaK alone or together with co-chaperones, and 4) the antimicrobial activity against both E. coli and S. aureus.

info:eu-repo/classification/ddc/540

ddc:540