Готові списки джерел за темами / Proteasome System

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Добірка наукової літератури з теми "Proteasome System"

Автор: Grafiati
Опубліковано: 23 вересня 2022
Оновлено: 28 вересня 2022

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Статті в журналах з теми "Proteasome System"

1

Chowdhury, Maisha, and Cordula Enenkel. "Intracellular Dynamics of the Ubiquitin-Proteasome-System." F1000Research 4 (July 24, 2015): 367. http://dx.doi.org/10.12688/f1000research.6835.1.

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Анотація:
The ubiquitin-proteasome system is the major degradation pathway for short-lived proteins in eukaryotic cells. Targets of the ubiquitin-proteasome-system are proteins regulating a broad range of cellular processes including cell cycle progression, gene expression, the quality control of proteostasis and the response to geno- and proteotoxic stress. Prior to degradation, the proteasomal substrate is marked with a poly-ubiquitin chain. The key protease of the ubiquitin system is the proteasome. In dividing cells, proteasomes exist as holo-enzymes composed of regulatory and core particles. The regulatory complex confers ubiquitin-recognition and ATP dependence on proteasomal protein degradation. The catalytic sites are located in the proteasome core particle. Proteasome holo-enzymes are predominantly nuclear suggesting a major requirement for proteasomal proteolysis in the nucleus. In cell cycle arrested mammalian or quiescent yeast cells, proteasomes deplete from the nucleus and accumulate in granules at the nuclear envelope (NE) / endoplasmic reticulum (ER) membranes. In prolonged quiescence, proteasome granules drop off the NE / ER membranes and migrate as stable organelles throughout the cytoplasm, as thoroughly investigated in yeast. When quiescence yeast cells are allowed to resume growth, proteasome granules clear and proteasomes are rapidly imported into the nucleus.Here, we summarize our knowledge about the enigmatic structure of proteasome storage granules and the trafficking of proteasomes and their substrates between the cyto- and nucleoplasm.Most of our current knowledge is based on studies in yeast. Their translation to mammalian cells promises to provide keen insight into protein degradation in non-dividing cells which comprise the majority of our body’s cells.
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2

Chowdhury, Maisha, and Cordula Enenkel. "Intracellular Dynamics of the Ubiquitin-Proteasome-System." F1000Research 4 (September 28, 2015): 367. http://dx.doi.org/10.12688/f1000research.6835.2.

Повний текст джерела
Анотація:
The ubiquitin-proteasome system is the major degradation pathway for short-lived proteins in eukaryotic cells. Targets of the ubiquitin-proteasome-system are proteins regulating a broad range of cellular processes including cell cycle progression, gene expression, the quality control of proteostasis and the response to geno- and proteotoxic stress. Prior to degradation, the proteasomal substrate is marked with a poly-ubiquitin chain. The key protease of the ubiquitin system is the proteasome. In dividing cells, proteasomes exist as holo-enzymes composed of regulatory and core particles. The regulatory complex confers ubiquitin-recognition and ATP dependence on proteasomal protein degradation. The catalytic sites are located in the proteasome core particle. Proteasome holo-enzymes are predominantly nuclear suggesting a major requirement for proteasomal proteolysis in the nucleus. In cell cycle arrested mammalian or quiescent yeast cells, proteasomes deplete from the nucleus and accumulate in granules at the nuclear envelope (NE) / endoplasmic reticulum ( ER) membranes. In prolonged quiescence, proteasome granules drop off the nuclear envelopeNE / ER membranes and migrate as droplet-like entitiesstable organelles throughout the cytoplasm, as thoroughly investigated in yeast. When quiescence yeast cells are allowed to resume growth, proteasome granules clear and proteasomes are rapidly imported into the nucleus.Here, we summarize our knowledge about the enigmatic structure of proteasome storage granules and the trafficking of proteasomes and their substrates between the cyto- and nucleoplasm.Most of our current knowledge is based on studies in yeast. Their translation to mammalian cells promises to provide keen insight into protein degradation in non-dividing cells, which comprise the majority of our body’s cells.
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3

Pedrycz, Agnieszka, and Agnieszka Kramkowska. "Mechanisms promoting and inhibiting the process of proteasomal degradation of cells." Current Problems of Psychiatry 17, no. 1 (March 1, 2016): 47–57. http://dx.doi.org/10.1515/cpp-2016-0007.

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Анотація:
AbstractDefects in the process of degradation of unneeded cellular proteins underlie many diseases. This article discusses one of the most important systems of removal of abnormal proteins. It describes the process of ubiquitination of proteins for proteasome degradation. It also describes the structure of the 26S and 20S proteasomes and the mechanism of ubiquitin-proteasome system. Proteasome proteolytic system is highly specialized and organized. Protease-proteasome 26S is particularly important for proper cell functioning. It recognizes and degrades marked proteins. Inhibition of proteasome pathway leads to cell cycle arrest and apoptosis.Efficient degradation of cellular proteins by UPS (the ubiquitin - proteasome system) - is important for signal transduction, transcriptional regulation, response to stress and the activity control of cell receptors.The development of many diseases has its origin in the dysfunction of the UPS route. This group includes diseases such as cancer, neurodegenerative disorders, immune-mediated diseases and infectious diseases. Development of effective methods for pharmacological intervention in the functioning of this system has become a great challenge. The use of specific, low molecular-weight proteasome inhibitors and enzymes catalyzing the ubiquitination gives hope for new, targeted therapies.
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4

Imkamp, Frank, Michal Ziemski, and Eilika Weber-Ban. "Pupylation-dependent and -independent proteasomal degradation in mycobacteria." Biomolecular Concepts 6, no. 4 (August 1, 2015): 285–301. http://dx.doi.org/10.1515/bmc-2015-0017.

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AbstractBacteria make use of compartmentalizing protease complexes, similar in architecture but not homologous to the eukaryotic proteasome, for the selective and processive removal of proteins. Mycobacteria as members of the actinobacteria harbor proteasomes in addition to the canonical bacterial degradation complexes. Mycobacterial proteasomal degradation, although not essential during normal growth, becomes critical for survival under particular environmental conditions, like, for example, during persistence of the pathogenic Mycobacterium tuberculosis in host macrophages or of environmental mycobacteria under starvation. Recruitment of protein substrates for proteasomal degradation is usually mediated by pupylation, the post-translational modification of lysine side chains with the prokaryotic ubiquitin-like protein Pup. This substrate recruitment strategy is functionally reminiscent of ubiquitination in eukaryotes, but is the result of convergent evolution, relying on chemically and structurally distinct enzymes. Pupylated substrates are recognized by the ATP-dependent proteasomal regulator Mpa that associates with the 20S proteasome core. A pupylation-independent proteasome degradation pathway has recently been discovered that is mediated by the ATP-independent bacterial proteasome activator Bpa (also referred to as PafE), and that appears to play a role under stress conditions. In this review, mechanistic principles of bacterial proteasomal degradation are discussed and compared with functionally related elements of the eukaryotic ubiquitin-proteasome system. Special attention is given to an understanding on the molecular level based on structural and biochemical analysis. Wherever available, discussion of in vivo studies is included to highlight the biological significance of this unusual bacterial degradation pathway.
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5

Schipper-Krom, Sabine, Katrin Juenemann, and Eric A. J. Reits. "The Ubiquitin-Proteasome System in Huntington’s Disease: Are Proteasomes Impaired, Initiators of Disease, or Coming to the Rescue?" Biochemistry Research International 2012 (2012): 1–12. http://dx.doi.org/10.1155/2012/837015.

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Анотація:
Huntington’s disease is a progressive neurodegenerative disease, caused by a polyglutamine expansion in the huntingtin protein. A prominent hallmark of the disease is the presence of intracellular aggregates initiated by N-terminal huntingtin fragments containing the polyglutamine repeat, which recruit components of the ubiquitin-proteasome system. While it is commonly thought that proteasomes are irreversibly sequestered into these aggregates leading to impairment of the ubiquitin-proteasome system, the data on proteasomal impairment in Huntington’s disease is contradictory. In addition, it has been suggested that proteasomes are unable to actually cleave polyglutamine sequencesin vitro, thereby releasing aggregation-prone polyglutamine peptides in cells. Here, we discuss how the proteasome is involved in the various stages of polyglutamine aggregation in Huntington’s disease, and how alterations in activity may improve clearance of mutant huntingtin fragments.
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6

Ding, Youming, Xiaoyan Chen, Bin Wang, Bin Yu, Jianhui Ge, and Xiaokang Shi. "Quercetin suppresses the chymotrypsin-like activity of proteasome via inhibition of MEK1/ERK1/2 signaling pathway in hepatocellular carcinoma HepG2 cells." Canadian Journal of Physiology and Pharmacology 96, no. 5 (May 2018): 521–26. http://dx.doi.org/10.1139/cjpp-2017-0655.

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Анотація:
The proteasomal system is a promising target for cancer treatment. Quercetin (Que), a flavonoid compound with antitumor ability, displays the inhibitory effect on proteasome activity. However, the underlying molecular mechanisms are ill defined. The present study found that Que treatment significantly reduced the chymotrypsin-like protease activity of proteasome whereas the trypsin- and caspase-like protease activities remained unchanged in HepG2 cancer cells, along with activation of p38 MAPK and JNK and reduction of ERK1/2 phosphorylation. Que-reduced proteasome activity could not be reverted by inhibition of p38 MAPK and JNK signaling pathway. In addition, MEK1 overexpression or knockdown upregulated or downregulated the chymotrypsin-like protease activity of proteasome, respectively. Both Que and MEK1/ERK1/2 inhibitor attenuated the expression levels of proteasome β subunits. These results indicate that Que-induced suppression of MEK1/ERK1/2 signaling and subsequent reduction of proteasome β subunits is responsible for its inhibitory impacts on proteasome activity.
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7

Goebel, Tatjana, Simone Mausbach, Andreas Tuermer, Heba Eltahir, Dominic Winter, Volkmar Gieselmann, and Melanie Thelen. "Proteaphagy in Mammalian Cells Can Function Independent of ATG5/ATG7." Molecular & Cellular Proteomics 19, no. 7 (April 16, 2020): 1120–31. http://dx.doi.org/10.1074/mcp.ra120.001983.

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The degradation of intra- and extracellular proteins is essential in all cell types and mediated by two systems, the ubiquitin-proteasome system (UPS) and the autophagy-lysosome pathway. This study investigates the changes in autophagosomal and lysosomal proteomes upon inhibition of proteasomes by bortezomib (BTZ) or MG132. We find an increased abundance of more than 50 proteins in lysosomes of cells in which the proteasome is inhibited. Among those are dihydrofolate reductase (DHFR), β-Catenin and 3-hydroxy-3-methylglutaryl-coenzym-A (HMGCoA)-reductase. Because these proteins are known to be degraded by the proteasome they seem to be compensatorily delivered to the autophagosomal pathway when the proteasome is inactivated. Surprisingly, most of the proteins which show increased amounts in the lysosomes of BTZ or MG132 treated cells are proteasomal subunits. Thus an inactivated, non-functional proteasome is delivered to the autophagic pathway. Native gel electrophoresis shows that the proteasome reaches the lysosome intact and not disassembled. Adaptor proteins, which target proteasomes to autophagy, have been described in Arabidopsis, Saccharomyces and upon starvation in mammalians. However, in cell lines deficient of these proteins or their mammalian orthologues, respectively, the transfer of proteasomes to the lysosome is not impaired. Obviously, these proteins do not play a role as autophagy adaptor proteins in mammalian cells. We can also show that chaperone-mediated autophagy (CMA) does not participate in the proteasome delivery to the lysosomes. In autophagy-related (ATG)-5 and ATG7 deficient cells the delivery of inactivated proteasomes to the autophagic pathway was only partially blocked, indicating the existence of at least two different pathways by which inactivated proteasomes can be delivered to the lysosome in mammalian cells.
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8

Gu, Xinjie, and Shutao Ma. "Recent Advances in the Discovery of Novel Peptide Inhibitors Targeting 26S Proteasome." Anti-Cancer Agents in Medicinal Chemistry 18, no. 12 (January 29, 2019): 1656–73. http://dx.doi.org/10.2174/1871520618666180813120012.

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Анотація:
Background: The 26S proteasome is a proteolytic complex of multimeric protease, which operates at the executive end of the Ubiquitin-Proteasome System (UPS) and degrades the polyubiquitylated proteins. Methods: After a brief introduction of 26S proteasome and Ubiquitin-Proteasome System (UPS), this review focuses on the structure and function of the 26S proteasome in intracellular protein level regulation. Then, physiological regulation mechanisms and processes are elaborated. In addition, the advantages and defects of approved 26S proteasome inhibitors were discussed. Finally, we summarized the novel peptide 26S proteasome inhibitors according to their structural classifications, highlighting their design strategies, inhibitory activity and Structure-Activity Relationships (SARs). Results: Cellular function maintenance relies on the proteasome metabolizing intracellular proteins to control intracellular protein levels, which is especially important for cancer cells to survive and proliferate. In primary tumors, proteasomes had a higher level and more potent activity. Currently, the approved small peptide inhibitors have proved their specific 26S proteasome inhibitory effects and considerable antitumor activities, but with obvious defects. Increasingly, novel peptide inhibitors are emerging and possess promising values in cancer therapy. Conclusion: Overall, the 26S proteasome is an efficient therapeutic target and novel 26S proteasome inhibitors hold potency for cancer therapy.
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9

Bard, Jared A. M., Ellen A. Goodall, Eric R. Greene, Erik Jonsson, Ken C. Dong, and Andreas Martin. "Structure and Function of the 26S Proteasome." Annual Review of Biochemistry 87, no. 1 (June 20, 2018): 697–724. http://dx.doi.org/10.1146/annurev-biochem-062917-011931.

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Анотація:
As the endpoint for the ubiquitin-proteasome system, the 26S proteasome is the principal proteolytic machine responsible for regulated protein degradation in eukaryotic cells. The proteasome's cellular functions range from general protein homeostasis and stress response to the control of vital processes such as cell division and signal transduction. To reliably process all the proteins presented to it in the complex cellular environment, the proteasome must combine high promiscuity with exceptional substrate selectivity. Recent structural and biochemical studies have shed new light on the many steps involved in proteasomal substrate processing, including recognition, deubiquitination, and ATP-driven translocation and unfolding. In addition, these studies revealed a complex conformational landscape that ensures proper substrate selection before the proteasome commits to processive degradation. These advances in our understanding of the proteasome's intricate machinery set the stage for future studies on how the proteasome functions as a major regulator of the eukaryotic proteome.
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10

Yadav, Dhananjay, Ji Yeon Lee, Nidhi Puranik, Pallavi S. Chauhan, Vishal Chavda, Jun-O. Jin, and Peter C. W. Lee. "Modulating the Ubiquitin–Proteasome System: A Therapeutic Strategy for Autoimmune Diseases." Cells 11, no. 7 (March 24, 2022): 1093. http://dx.doi.org/10.3390/cells11071093.

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Анотація:
Multiple sclerosis (MS) is an autoimmune, neurodegenerative disease associated with the central nervous system (CNS). Autoimmunity is caused by an abnormal immune response to self-antigens, which results in chronic inflammation and tissue death. Ubiquitination is a post-translational modification in which ubiquitin molecules are attached to proteins by ubiquitinating enzymes, and then the modified proteins are degraded by the proteasome system. In addition to regulating proteasomal degradation of proteins, ubiquitination also regulates other cellular functions that are independent of proteasomal degradation. It plays a vital role in intracellular protein turnover and immune signaling and responses. The ubiquitin–proteasome system (UPS) is primarily responsible for the nonlysosomal proteolysis of intracellular proteins. The 26S proteasome is a multicatalytic adenosine-triphosphate-dependent protease that recognizes ubiquitin covalently attached to particular proteins and targets them for degradation. Damaged, oxidized, or misfolded proteins, as well as regulatory proteins that govern many essential cellular functions, are removed by this degradation pathway. When this system is affected, cellular homeostasis is altered, resulting in the induction of a range of diseases. This review discusses the biochemistry and molecular biology of the UPS, including its role in the development of MS and proteinopathies. Potential therapies and targets involving the UPS are also addressed.
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Дисертації з теми "Proteasome System"

1

Bingol, Baris Zinn Kai George. "Ubiquitin-proteasome system at the synapse /." Diss., Pasadena, Calif. : Caltech, 2006. http://resolver.caltech.edu/CaltechETD:etd-05272006-184911.

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2

Gupta, Nilaksh. "UBIQUITIN-PROTEASOME SYSTEM MODULATES PLATELET FUNCTION." Cleveland State University / OhioLINK, 2014. http://rave.ohiolink.edu/etdc/view?acc_num=csu1408896695.

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3

Menéndez, Benito Victoria. "The ubiquitin-proteasome system during proteotoxic stress /." Stockholm, 2006. http://diss.kib.ki.se/2006/91-7140-706-5/.

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4

Ghannam, Khetam [Verfasser]. "Ubiquitin proteasome system and myopathies / Khetam Ghannam." Berlin : Medizinische Fakultät Charité - Universitätsmedizin Berlin, 2015. http://d-nb.info/1075493374/34.

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5

Jolly, R. S. "The ubiquitin proteasome system in Huntington's disease." Thesis, University College London (University of London), 2008. http://discovery.ucl.ac.uk/1444454/.

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Анотація:
Huntington's disease (HD) is an autosomally dominant, progressive movement disorder, caused by an expansion in the polyglutamine tract of huntingtin protein. HD is pathologically characterised by the presence of insoluble, proteinaceous neuronal intranuclear inclusions (NHs) and dystrophic neurite inclusions (DNIs) in affected neurons that can be immunostained for ubiquitin and other proteins involved in the ubiquitin-proteasome system (UPS). The UPS is a highly conserved mechanism for degradation of both normal and misfolded proteins in eukaryotic cells. This has led to suggestions that the UPS is inhibited in HD. This study utilises microscopy, biochemistry and fluorometric assays to examine the molecular composition of aggregates and the potential dysfunction of the UPS in the R6/2 mouse line, an established model of HD. The ultrastructure of aggregates is shown to be predominantly amorphous and granular in appearance and likely to be formed through the process of transglutamination. Immunohistochemical data shows that certain chaperones, ubiquitin-like proteins (UBLs) and proteins involved in the UPS localise to Nils and DNIs differentially. Fluorometric assays demonstrate that the proteasome exhibits a differential profile in R6/2 mice where both chymotrypsin-like and PGPH-like activities are markedly increased whilst trypsin-like activity is decreased relative to litter-mate control mice. Furthermore, these activity changes may be explained by alterations in proteasome regulation, levels and maturation. These results suggest that, in the R6/2 line, the proteasome is not inhibited by the presence of mutant huntingtin, rather that there are alterations of the catalytic activities of the proteasome. It appears that Nil's act not only as focal points of proteolysis, but also of proteasome biogenesis. This is consistent with, and extends, the concept of clastosomes.
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6

Min, Mingwei. "Decoding the mitotic exit ubiquitin-proteasome system." Thesis, University of Cambridge, 2014. https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.708388.

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7

Rieger, Melanie. "Strukturelle und funktionelle Anpassung des Ubiquitin-Proteasomsystems an IFN-gamma." Doctoral thesis, Humboldt-Universität zu Berlin, Mathematisch-Naturwissenschaftliche Fakultät I, 2009. http://dx.doi.org/10.18452/15888.

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Das Ubiquitin-Proteasom-System ist an der Degradation cytosolischer Proteine und der Generierung von Antigenen beteiligt, die über MHC Klasse I Moleküle CD8+ T Zellen präsentiert werden. Die Antigenprozessierung wird durch Typ I und II Interferone beeinflusst, welche die Formierung des Immunoproteasoms und des Proteasomen-Aktivators PA28 induzieren und so die katalytische Aktivität des Ubiquitin-Proteasom-Systems qualitativ verändern. In der vorliegenden Arbeit wurde im Zellkulturmodell unter dem Einfluss von IFN gamma die zunehmende Inkorporation der Immunountereinheiten in de novo assemblierende 20S Proteasomen und die daraus resultierende Veränderung der proteolytische Aktivität untersucht. Die Inkorporation der Immunountereinheiten wurde mittels 2D Gelelektrophorese und Western Blots von 20S Proteasomen untersucht, die nach unterschiedlicher Stimulationsdauer mit IFN gamma aus HeLa Zellen isoliert wurden. Es konnte gezeigt werden, dass innerhalb der ersten 24h einer IFN gamma Stimulation die strukturelle Heterogenität des zellulären Proteasomenpools zunimmt, indem sowohl intermediäre als auch Immunoproteasomen assemblieren. In der Nativ-PAGE von Lysaten IFN gamma stimulierter Zellen wurde eine Zunahme des 20S Proteasoms als freier Komplex und in Assoziation mit PA28 beobachtet, während die Menge des zum ATP-abhängigen Abbau von polyubiquitinierten Proteinen notwendigen 26S Proteasoms unverändert blieb. Die Stimulation mit IFN gamma hatte eine Steigerung der gesamtproteasomalen Aktivität zur Folge, die unter Inhibition der Interaktion zwischen 20S Proteasom und PA28 verzögert erfolgte. Die katalytischen Eigenschaften isolierter Proteasomen wurden anhand der Generierung eines immunrelevanten Hepatitis C CTL Epitops des viralen Core Proteins in vitro untersucht. Im Verlauf der IFN gamma Stimulation de novo assemblierte Proteasomen wiesen jeweils unterschiedliche Präferenzen für die Generierung des untersuchten CTL Epitops auf. Eine weitere, proteasomen-spezifische Änderung der katalytischen Aktivität bewirkte die Assoziation des Proteasomen-Aktivators. Innerhalb der ersten zwölf Stunden einer IFN gamma Stimulation wurde das Epitop vermehrt mit der Unterstützung des Proteasomen-Aktivators generiert, nach 24 Stunden zunehmend durch freies 20S Proteasom. Die Ergebnisse der vorgestellten Arbeit zeigen, dass Strukturvarianten des Proteasoms zusammen mit PA28 redundant funktionieren und eine hohe proteolytische Plastizität des UPS gewährleisten.
The ubiquitin proteasome system is responsible for the degradation of cytosolic proteins and the processing of MHC class I restricted antigens. The generation of these antigens is influenced by type I and II interferons which induce the expression of immunoproteasomes and the proteasome activator PA28; and thereby impact the quality of peptides processed by the proteasome system. The adoption of the proteasome system to a proinflammatory environment has been investigated in a cell culture model by isolating proteasomes after different stages of IFN gamma stimulation. The composition of isolated proteasomes was analysed by 2D PAGE and western blot approach. The presented work shows that within 24h of IFN gamma stimulation an increasing heterogeneity of the cellular proteasome pool is observed, resulting from the assembly of both intermediate type proteasomes and immunoproteasomes at the early stage of IFN gamma stimulation. It could be shown by native PAGE of HeLa cell lysates that IFN gamma induces increasing amounts of 20S proteasomes and PA28 associated proteasomes without decreasing the amount of 26S proteasomes that are necessary for the ATP dependent degradation of ubiquitinated proteins; and resulting in an enhanced total proteasomal activity in vitro. This increase in activity was delayed when the interaction of 20S proteasomes and PA28 was inhibited. A comparative analysis of the ability of isolated 20S proteasomes to generate a known hepatitis C virus derived CTL epitope in vitro proved that during early IFN gamma stimulation de novo assembled proteasomes exhibited a structure specific preference to generate the HCV CTL epitope either alone or in combination with the proteasome activator PA28. Within the first 12h of IFN gamma stimulation the epitope was generated with higher efficiency by 20S proteasomes in association with PA28, whereas after 24h the impact of PA28 on the proteasome pool was less pronounced. The presented work shows that IFN gamma induces a heterogeneity of 20S proteasomes in the early stage of stimulation, acting in combination with the proteasome activator in a redundant manner; and provides a high proteolytic placticity of the proteasome system.
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8

Silva, Elisabete Rodrigues do Monte. "Caracterização do repertório peptídico intracelular de células expressando o proteassomo imune." Universidade de São Paulo, 2014. http://www.teses.usp.br/teses/disponiveis/42/42134/tde-26062014-184010/.

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Células eucarióticas contêm vários tipos de proteassomo que regulam o processo de degradação de proteína. Proteassomos são proteases multicatalíticas que são responsáveis pela maior parte de degradação não-lisossomal de proteínas em células eucarióticas. As três subunidades catalíticas do proteassomo são β1, β2 e β5. Em condições de stress e resposta imune essas três subunidades são substituídas por β1i, β2i and β5i, respectivamente, para formar o proteassomo imune. Estas três subunidades induzíveis, parecem alterar as especificidades de peptidase do proteassoma imune em células tratadas com IFN-g. Nosso objetivo no presente trabalho foi caracterizar um modelo celular para a indução do proteassomo imune, e ainda investigar o repertório peptídeo intracelular produzido por esta forma particular do proteassoma, através da técnica de espectrometria de massas. Em resumo, os nossos dados mostraram um aumento de 3 vezes do peptídeo EL28 derivado da proteína RPT2 em células HeLa tratadas com o IFN-g. O peptídeo EL28 pode ser de relevância clínica para o tratamento de distúrbios relacionados com a apresentação de antígenos, visto que ele parece ativar a atividade quimotripsina-like quando incubado com o extrato celular de células HeLa.
Eukaryotic cells contain several types of proteasome regulating the process of protein degradation. The proteasome are responsible for most non - lysosomal protein degradation in eukaryotic cells. The three catalytic subunits of the proteasome are β1, β2 and β5. Under conditions of stress and immune response these three subunits are replaced by β1i, β2i and β5i, respectively, to form the immune proteasome . These three inducible subunits, appear to alter the specificity of the immune proteasome peptidase in cells treated with IFN-g. Our aim in this study was to characterize a cellular model for the induction of the immune proteasome, and even investigate the intracellular peptide repertoire produced by this particular form of the proteasome, through the technique of mass spectrometry. In summary, our data showed an increase of 3 times the peptide derived from RPT2 EL28 protein in HeLa cells treated with IFN-g. The EL28 peptide may be of clinical relevance for the treatment of disorders related to antigen presentation, since it seems to activate the chymotrypsin-like activity when incubated with the cell extract of HeLa cells.
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9

Verhoef, Lisette Gerridina Gezina Catharina. "The role of the ubiquitin-proteasome system in neurodegenerative disorders /." Stockholm, 2006. http://diss.kib.ki.se/2006/91-7140-743-X/.

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10

Seeger, Michael [Verfasser]. "Functional aspects of the ubiquitin-proteasome system / Michael Seeger." Berlin : Medizinische Fakultät Charité - Universitätsmedizin Berlin, 2015. http://d-nb.info/1070498343/34.

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Книги з теми "Proteasome System"

1

Mayor, Thibault, and Gary Kleiger, eds. The Ubiquitin Proteasome System. New York, NY: Springer New York, 2018. http://dx.doi.org/10.1007/978-1-4939-8706-1.

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2

name, No. The ubiquitin-proteasome proteolytic system: From classical biochemistry to human diseases. Singapore: World Scientific, 2002.

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3

Rechsteiner, Martin, Aaron J. Ciechanover, and R. John Mayer. Ubiquitin-Proteasome System. Wiley & Sons, Incorporated, John, 2008.

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4

Rechsteiner, Martin, Aaron J. Ciechanover, and R. John Mayer. Ubiquitin-Proteasome System. Wiley & Sons, Limited, John, 2008.

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Ciechanover, Aaron J., and Maria G. Masucci. The Ubiquitin-Proteasome Proteolytic System. WORLD SCIENTIFIC, 2002. http://dx.doi.org/10.1142/5051.

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Rechsteiner, Martin, Aaron J. Ciechanover, and R. John Mayer. Ubiquitin-Proteasome System and Disease. Wiley & Sons, Incorporated, John, 2008.

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7

(Editor), Leonidas Stefanis, and J. N. Keller (Editor), eds. The Proteasome in Neurodegeneration. Springer, 2006.

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The Ubiquitin Proteasome System: Methods and Protocols. Humana, 2018.

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9

Rechsteiner, Martin, Aaron J. Ciechanover, and R. John Mayer. Cell Biology of the Ubiquitin-Proteasome System. Wiley & Sons, Incorporated, John, 2008.

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10

Mayer, J., and R. Layfield. The Ubiquitin-proteasome System (Essays in Biochemistry). Portland Pr, 2005.

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Частини книг з теми "Proteasome System"

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Dunnett, Stephen B., James Winslow, Tomasz Schneider, Helen J. Cassaday, Stephan G. Anagnostaras, Jennifer R. Sage, Stephanie A. Carmack, et al. "Ubiquitin-Proteasome System." In Encyclopedia of Psychopharmacology, 1353. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68706-1_779.

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Attaix, Didier. "Ubiquitin-Proteasome System." In Encyclopedia of Exercise Medicine in Health and Disease, 885–87. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-540-29807-6_191.

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Bose, Rohini, Gurpreet Manku, Martine Culty, and Simon S. Wing. "Ubiquitin–Proteasome System in Spermatogenesis." In Advances in Experimental Medicine and Biology, 181–213. New York, NY: Springer New York, 2014. http://dx.doi.org/10.1007/978-1-4939-0817-2_9.

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Wang, Yan, and Wei-Dong Le. "Autophagy and Ubiquitin-Proteasome System." In Autophagy: Biology and Diseases, 527–50. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-15-0602-4_25.

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Mao, Youdong. "Structure, Dynamics and Function of the 26S Proteasome." In Subcellular Biochemistry, 1–151. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-58971-4_1.

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AbstractThe 26S proteasome is the most complex ATP-dependent protease machinery, of ~2.5 MDa mass, ubiquitously found in all eukaryotes. It selectively degrades ubiquitin-conjugated proteins and plays fundamentally indispensable roles in regulating almost all major aspects of cellular activities. To serve as the sole terminal “processor” for myriad ubiquitylation pathways, the proteasome evolved exceptional adaptability in dynamically organizing a large network of proteins, including ubiquitin receptors, shuttle factors, deubiquitinases, AAA-ATPase unfoldases, and ubiquitin ligases, to enable substrate selectivity and processing efficiency and to achieve regulation precision of a vast diversity of substrates. The inner working of the 26S proteasome is among the most sophisticated, enigmatic mechanisms of enzyme machinery in eukaryotic cells. Recent breakthroughs in three-dimensional atomic-level visualization of the 26S proteasome dynamics during polyubiquitylated substrate degradation elucidated an extensively detailed picture of its functional mechanisms, owing to progressive methodological advances associated with cryogenic electron microscopy (cryo-EM). Multiple sites of ubiquitin binding in the proteasome revealed a canonical mode of ubiquitin-dependent substrate engagement. The proteasome conformation in the act of substrate deubiquitylation provided insights into how the deubiquitylating activity of RPN11 is enhanced in the holoenzyme and is coupled to substrate translocation. Intriguingly, three principal modes of coordinated ATP hydrolysis in the heterohexameric AAA-ATPase motor were discovered to regulate intermediate functional steps of the proteasome, including ubiquitin-substrate engagement, deubiquitylation, initiation of substrate translocation and processive substrate degradation. The atomic dissection of the innermost working of the 26S proteasome opens up a new era in our understanding of the ubiquitin-proteasome system and has far-reaching implications in health and disease.
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Schubert, Ulrich. "Function(s) of the Ubiquitin—Proteasome System in Retrovirus Budding." In Proteasome Inhibitors in Cancer Therapy, 217–30. Totowa, NJ: Humana Press, 2004. http://dx.doi.org/10.1007/978-1-59259-794-9_18.

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Bode, Nadine J., and K. Heran Darwin. "The Pup-Proteasome System of Mycobacteria." In Molecular Genetics of Mycobacteria, 667–80. Washington, DC, USA: ASM Press, 2015. http://dx.doi.org/10.1128/9781555818845.ch32.

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Tydlacka, Suzanne, Shi-Hua Li, and Xiao-Jiang Li. "The Ubiquitin–Proteasome System in Synapses." In Folding for the Synapse, 201–12. Boston, MA: Springer US, 2010. http://dx.doi.org/10.1007/978-1-4419-7061-9_10.

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Samanovic, Marie I., Huilin Li, and K. Heran Darwin. "The Pup-Proteasome System of Mycobacterium tuberculosis." In Subcellular Biochemistry, 267–95. Dordrecht: Springer Netherlands, 2013. http://dx.doi.org/10.1007/978-94-007-5940-4_10.

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10

Patterson, Cam, and Jörg Höhfeld. "Molecular Chaperones and the Ubiquitin-Proteasome System." In Protein Degradation, 1–30. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2008. http://dx.doi.org/10.1002/9783527620210.ch1.

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Тези доповідей конференцій з теми "Proteasome System"

1

Driscoll, James J., and Sajjeev Jagannathan. "Abstract 1708: Metabolic regulation of the ubiquitin+proteasome system." In Proceedings: AACR 104th Annual Meeting 2013; Apr 6-10, 2013; Washington, DC. American Association for Cancer Research, 2013. http://dx.doi.org/10.1158/1538-7445.am2013-1708.

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Selvaraju, Karthik, Arjan Mofers, Paola Pellegrini, Ellin-Kristina Hillert, Padraig D'Arcy, and Stig Linder. "Abstract 2795: Screening and characterization of drugs that inhibit the ubiquitin-proteasome system." In Proceedings: AACR Annual Meeting 2018; April 14-18, 2018; Chicago, IL. American Association for Cancer Research, 2018. http://dx.doi.org/10.1158/1538-7445.am2018-2795.

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3

Lee, Yun-Song, and Sun-Yong Kim. "Cigarette Smoke Causes AKT Degradation Through Ubiquitin Proteasome System In Human Lung Fibroblasts." In American Thoracic Society 2011 International Conference, May 13-18, 2011 • Denver Colorado. American Thoracic Society, 2011. http://dx.doi.org/10.1164/ajrccm-conference.2011.183.1_meetingabstracts.a2117.

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Wiggins, Kimberly R., Valerie Davis, Dhiral Phadke, Ruchir Shah, and Trevor K. Archer. "Abstract 3928: Inhibition of the ubiquitin proteasome system differentially regulates glucocorticoid receptor-mediated transcriptional processes." In Proceedings: AACR 103rd Annual Meeting 2012‐‐ Mar 31‐Apr 4, 2012; Chicago, IL. American Association for Cancer Research, 2012. http://dx.doi.org/10.1158/1538-7445.am2012-3928.

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Harrison, Tim, Xavier Jacq, Colin O'Dowd, Gerald Gavory, Oliver Barker, Christina Bell, Frank Burkamp, et al. "Abstract LB-049: Targeting the ubiquitin-proteasome system by small molecule inhibition of the DUBome." In Proceedings: AACR Annual Meeting 2019; March 29-April 3, 2019; Atlanta, GA. American Association for Cancer Research, 2019. http://dx.doi.org/10.1158/1538-7445.sabcs18-lb-049.

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Tamari, Keisuke, Kazuhiko Hayashi, Yoshihiro Kano, Masamitsu Konno, Takahito Fukusumi, Shimpei Nishikawa, Shinichiro Hasegawa, et al. "Abstract 3960: Identification of osteosarcoma cancer stem cells using an imaging system for proteasome activity." In Proceedings: AACR Annual Meeting 2014; April 5-9, 2014; San Diego, CA. American Association for Cancer Research, 2014. http://dx.doi.org/10.1158/1538-7445.am2014-3960.

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Harrison, Tim, Xavier Jacq, Colin O'Dowd, Gerald Gavory, Oliver Barker, Christina Bell, Frank Burkamp, et al. "Abstract LB-049: Targeting the ubiquitin-proteasome system by small molecule inhibition of the DUBome." In Proceedings: AACR Annual Meeting 2019; March 29-April 3, 2019; Atlanta, GA. American Association for Cancer Research, 2019. http://dx.doi.org/10.1158/1538-7445.am2019-lb-049.

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Tamari, Keisuke, Hideshi Ishii, Kazuhiko Hayashi, Masamitsu Konno, Koichi Kawamoto, Naohiro Nishida, Jun Kozeki, et al. "Abstract 3319: Identification of cervical cancer stem cells by using an imaging system for proteasome activity." In Proceedings: AACR 106th Annual Meeting 2015; April 18-22, 2015; Philadelphia, PA. American Association for Cancer Research, 2015. http://dx.doi.org/10.1158/1538-7445.am2015-3319.

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Jang, A. J., B. Y. Kang, Y. Zhao, P. Gallo, R. L. Benza, and M. Passineau. "Novel PAH Candidate Gene, HINT3, and New Therapeutic Approach of the Ubiquitin Proteasome System in PAH." In American Thoracic Society 2019 International Conference, May 17-22, 2019 - Dallas, TX. American Thoracic Society, 2019. http://dx.doi.org/10.1164/ajrccm-conference.2019.199.1_meetingabstracts.a5060.

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Yu, PEIFENG. "Dynamic Activity Regulation of the Ubiquitin-26S Proteasome System and Autophagy is Essential for Proper Seed Development." In ASPB PLANT BIOLOGY 2020. USA: ASPB, 2020. http://dx.doi.org/10.46678/pb.20.1049094.

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Звіти організацій з теми "Proteasome System"

1

Modgil, Dimple. System Design, Algorithm Development, and Verification for Optoacoustic Molecular Imaging of Protease Expression in Breast Cancer. Fort Belvoir, VA: Defense Technical Information Center, May 2009. http://dx.doi.org/10.21236/ada506325.

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Barkan, Alice, and Zach Adam. The Role of Proteases in Regulating Gene Expression and Assembly Processes in the Chloroplast. United States Department of Agriculture, January 2003. http://dx.doi.org/10.32747/2003.7695852.bard.

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Chloroplasts house many biochemical processes that are essential for plant viability. Foremost, among these is photosynthesis, which requires the protein-rich thylakoid membrane system. The activation of chloroplast genes encoding thylakoid membrane proteins and the targeting and assembly of these proteins together with their nuclear-encoded partners are essential for the elaboration of the thylakoid membrane. Several nuclear-encoded proteins that regulate chloroplast gene expression and that mediate the targeting of proteins to the thylakoid membrane have been identified in recent years, and many more remain to be discovered. The abundance of such proteins is critical and is likely to be determined to a significant extent by their stability, which in turn, is influenced by chloroplast protease activities. The primary goal of this project was to link specific proteases to specific substrates, and in particular, to specific regulatory and assembly proteins. We proposed a two-pronged approach, involving genetic analysis of the consequences of the mutational loss of chloroplast proteases, and biochemical analysis of the degradation pathways of specific proteins that have been shown to control chloroplast gene expression. Our initial bioinformatic analysis of chloroplast proteases allowed us to identify the set of pro teases that is targeted to the chloroplast. We used that information to recover three Arabidopsis mutants with T - DNA insertions in specific chloroplast protease genes. We carried out the first analysis of the stability of a regulator of chloroplast gene expression (CRS2), and found that the protein is much less stable than are typical components of the photosynthetic apparatus. Genetic reagents and analytical methods were developed that have set the stage for a rapid advancement of our understanding of chloroplast proteolysis. The results obtained may be useful for manipulating the expression of transgenes in the chloroplast and for engineering plants whose photosynthetic activity is optimized under harsh environmental conditions.
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Chen, Junping, Zach Adam, and Arie Admon. The Role of FtsH11 Protease in Chloroplast Biogenesis and Maintenance at Elevated Temperatures in Model and Crop Plants. United States Department of Agriculture, May 2013. http://dx.doi.org/10.32747/2013.7699845.bard.

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specific objectives of this proposal were to: 1) determine the location, topology, and oligomerization of FtsH11 protease; 2) identify the substrate/s of FtsH11 and the downstream components involved in maintaining thermostability of chloroplasts; 3) identify new elements involved in FtsH11 protease regulatory network related to HT adaptation processes in chloroplast; 4) Study the role of FtsH11 homologs from crop species in HT tolerance. Background to the topic: HT-tolerant varieties that maintain high photosynthetic efficiency at HT, and cope better with daily and seasonal temperature fluctuations are in great need to alleviate the effect of global warming on food production. Photosynthesis is a very complex process requiring accurate coordination of many complex systems and constant adjustments to the changing environments. Proteolytic activities mediated by various proteases in chloroplast are essential part of this process and critical for maintaining normal chloroplast functions under HT. However, little is known about mechanisms that contribute to adaptation of photosynthetic processes to HT. Our study has shown that a chloroplast-targeted Arabidopsis FtsH11 protease plays an essential and specific role in maintaining thermostability of thylakoids and normal photosynthesis at moderate HT. We hypothesized that FtsH11 homologs recently identified in other plant species might have roles similarly to that of AtFtsH1. Thus, dissecting the underlying mechanisms of FtsH11 in the adaptation mechanisms in chloroplasts to HT stress and other elements involved will aid our effort to produce more agricultural products in less favorable environments. Major conclusions, solutions, achievements - Identified the chloroplast inner envelope membrane localization of FtsH11. - Revealed a specific association of FtsH11 with the a and b subunits of CPN60. - Identified the involvement of ARC6, a protein coordinates chloroplast division machineries in plants, in FtsH11 mediated HT adaptation process in chloroplast. -Reveal possible association of a polyribonucleotide nucleotidyltransferase (cpPNPase), coded by At3G03710, with FtsH11 mediated HT adaptation process in chloroplast. - Mapped 4 additional loci in FtsH11 mediated HT adaptation network in chloroplast. - Demonstrated importance of the proteolytic activity of FtsH11 for thermotolerance, in addition to the ATPase activity. - Demonstrated a conserved role of plant FtsH11 proteases in chloroplast biogenesis and in maintaining structural and functional thermostability of chloroplast at elevated temperatures. Implications, both scientific and agricultural:Three different components interacting with FtsH11 were identified during the course of this study. At present, it is not known whether these proteins are directly involved in FtsH11mediated thermotolerance network in chloroplast and/or how these elements are interrelated. Studies aiming to connect the dot among biological functions of these networks are underway in both labs. Nevertheless, in bacteria where it was first studied, FtsH functions in heat shock response by regulating transcription level of σ32, a heat chock factor regulates HSPsexpression. FtsH also involves in control of biosynthesis of membrane components and quality control of membrane proteins etc. In plants, both Arc 6 and CPN60 identified in this study are essential in chloroplast division and developments as mutation of either one impairs chloroplast division in Arabidopsis. The facts that we have found the specific association of both α and β CPN60 with FtsH11 protein biochemically, the suppression/ enhancement of ftsh11 thermosensitive phenotype by arc6 /pnp allele genetically, implicate inter-connection of these networks via FtsH11 mediated network(s) in regulating the dynamic adaptation processes of chloroplast to temperature increases at transcriptional, translational and post-translational levels. The conserved role of FtsH11 proteases in maintaining thermostability of chloroplast at HT demonstrated here provides a foundation for improving crop photosynthetic performance at high temperatures.
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Gafni, Yedidya, Moshe Lapidot, and Vitaly Citovsky. Dual role of the TYLCV protein V2 in suppressing the host plant defense. United States Department of Agriculture, January 2013. http://dx.doi.org/10.32747/2013.7597935.bard.

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TYLCV-Is is a major tomato pathogen, causing extensive crop losses in Israel and the U.S. We have identified a TYLCV-Is protein, V2, which acts as a suppressor of RNA silencing. Intriguingly, the counter-defense function of V2 may not be limited to silencing suppression. Our recent data suggest that V2 interacts with the tomato CYP1 protease. CYP1 belongs to the family of papain-like cysteine proteases which participate in programmed cell death (PCD) involved in plant defense against pathogens. Based on these data we proposed a model for dual action of V2 in suppressing the host antiviral defense: V2 targets SGS3 for degradation and V2 inhibits CYP1 activity. To study this we proposed to tackle three specific objectives. I. Characterize the role of V2 in SGS3 proteasomal degradation ubiquitination, II. Study the effects of V2 on CYP1 maturation, enzymatic activity, and accumulation and, III. Analyze the effects of the CYP1-V2 interaction on TYLCV-Is infection. Here we describe results from our study that support our hypothesis: the involvement of the host's innate immune system—in this case, PCD—in plant defense against TYLCV-Is. Also, we use TYLCV-Is to discover the molecular pathway(s) by which this plant virus counters this defense. Towards the end of our study we discovered an interesting involvement of the C2 protein encoded by TYLCV-Is in inducing Hypersensitive Response in N. benthamianaplants which is not the case when the whole viral genome is introduced. This might lead to a better understanding of the multiple processes involved in the way TYLCV is overcoming the defense mechanisms of the host plant cell. In a parallel research supporting the main goal described, we also investigated Agrobacteriumtumefaciens-encoded F-box protein VirF. It has been proposed that VirF targets a host protein for the UPS-mediated degradation, very much the way TYLCV V2 does. In our study, we identified one such interactor, an Arabidopsistrihelix-domain transcription factor VFP3, and further show that its very close homolog VFP5 also interacted with VirF. Interestingly, interactions of VirF with either VFP3 or VFP5 did not activate the host UPS, suggesting that VirF might play other UPS-independent roles in bacterial infection. Another target for VirF is VFP4, a transcription factor that both VirF and its plant functional homolog VBF target to degradation by UPS. Using RNA-seqtranscriptome analysis we showed that VFP4 regulates numerous plant genes involved in disease response, including responses to viral and bacterial infections. Detailed analyses of some of these genes indicated their involvement in plant protection against Agrobacterium infection. Thus, Agrobacterium may facilitate its infection by utilizing the host cell UPS to destabilize transcriptional regulators of the host disease response machinery that limits the infection.
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Droby, Samir, Michael Wisniewski, Martin Goldway, Wojciech Janisiewicz, and Charles Wilson. Enhancement of Postharvest Biocontrol Activity of the Yeast Candida oleophila by Overexpression of Lytic Enzymes. United States Department of Agriculture, November 2003. http://dx.doi.org/10.32747/2003.7586481.bard.

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Enhancing the activity of biocontrol agents could be the most important factor in their success in controlling fruit disease and their ultimate acceptance in commercial disease management. Direct manipulation of a biocontrol agent resulting in enhancement of diseases control could be achieved by using recent advances in molecular biology techniques. The objectives of this project were to isolate genes from yeast species that were used as postharvest biocontrol agents against postharvest diseases and to determine their role in biocontrol efficacy. The emphasis was to be placed on the yeast, Candida oleophila, which was jointly discovered and developed in our laboratories, and commercialized as the product, Aspire. The general plan was to develop a transformation system for C . oleophila and either knockout or overexpress particular genes of interest. Additionally, biochemical characterization of the lytic peptides was conducted in the wild-type and transgenic isolates. In addition to developing a better understanding of the mode of action of the yeast biocontrol agents, it was also our intent to demonstrate the feasibility of enhancing biocontrol activity via genetic enhancement of yeast with genes known to code for proteins with antimicrobial activity. Major achievements are: 1) Characterization of extracellular lytic enzymes produced by the yeast biocontrol agent Candida oleophila; 2) Development of a transformation system for Candida oleophila; 3) Cloning and analysis of C.oleophila glucanase gene; 4) Overexpression of and knockout of C. oleophila glucanase gene and evaluating its role in the biocontrol activity of C. oleophila; 5) Characterization of defensin gene and its expression in the yeast Pichiapastoris; 6) Cloning and Analysis of Chitinase and Adhesin Genes; 7) Characterization of the rnase secreted by C . oleophila and its inhibitory activity against P. digitatum. This project has resulted in information that enhanced our understanding of the mode of action of the yeast C . oleophila. This was important step towards enhancing the biocontrol activity of the yeast. Fungal cell wall enzymes produced by the yeast antagonist were characterized. Different substrates were identified to enhance there production in vitro. Exo-b-1, 3 glucanase, chitinase and protease production was stimulated by the presence of cell-wall fragments of Penicillium digitatum in the growing medium, in addition to glucose. A transformation system developed was used to study the role of lytic enzymes in the biocontrol activity of the yeast antagonist and was essential for genetic manipulation of C . oleqphila. After cloning and characterization of the exo-glucanase gene from the yeast, the transformation system was efficiently used to study the role of the enzyme in the biocontrol activity by over-expressing or knocking out the activity of the enzyme. At the last phase of the research (still ongoing) the transformation system is being used to study the role of chitinase gene in the mode of action. Knockout and over expression experiments are underway.
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Citovsky, Vitaly, and Yedidya Gafni. Suppression of RNA Silencing by TYLCV During Viral Infection. United States Department of Agriculture, December 2009. http://dx.doi.org/10.32747/2009.7592126.bard.

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Анотація:
The Israeli isolate of Tomato yellow leaf curl geminivirus (TYLCV-Is) is a major tomato pathogen, causing extensive (up to 100%) crop losses in Israel and in the south-eastern U.S. (e.g., Georgia, Florida). Surprisingly, however, little is known about the molecular mechanisms of TYLCV-Is interactions with tomato cells. In the current BARD project, we have identified a TYLCV-Is protein, V2, which acts as a suppressor of RNA silencing, and showed that V2 interacts with the tomato (L. esculentum) member of the SGS3 (LeSGS3) protein family known to be involved in RNA silencing. This proposal will use our data as a foundation to study one of the most intriguing, yet poorly understood, aspects of TYLCV-Is interactions with its host plants – possible involvement of the host innate immune system, i.e., RNA silencing, in plant defense against TYLCV-Is and the molecular pathway(s) by which TYLCV-Is may counter this defense. Our project sought two objectives: I. Study of the roles of RNA silencing and its suppression by V2 in TYLCV-Is infection of tomato plants. II. Study of the mechanism by which V2 suppresses RNA silencing. Our research towards these goals has produced the following main achievements: • Identification and characterization of TYLCV V2 protein as a suppressor of RNA silencing. (#1 in the list of publications). • Characterization of the V2 protein as a cytoplasmic protein interacting with the plant protein SlSGS3 and localized mainly in specific, not yet identified, bodies. (#2 in the list of publications). • Development of new tools to study subcellular localization of interacting proteins (#3 in the list of publications). • Characterization of TYLCV V2 as a F-BOX protein and its possible role in target protein(s) degradation. • Characterization of TYLCV V2 interaction with a tomato cystein protease that acts as an anti-viral agent. These research findings provided significant insights into (I) the suppression of RNA silencing executed by the TYLCV V2 protein and (II) characterization some parts of the mechanism(s) involved in this suppression. The obtained knowledge will help to develop specific strategies to attenuate TYLCV infection, for example, by blocking the activity of the viral suppressor of gene silencing thus enabling the host cell silencing machinery combat the virus.
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Grumet, Rebecca, and Benjamin Raccah. Identification of Potyviral Domains Controlling Systemic Infection, Host Range and Aphid Transmission. United States Department of Agriculture, July 2000. http://dx.doi.org/10.32747/2000.7695842.bard.

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Анотація:
Potyviruses form one of the largest and most economically important groups of plant viruses. Individual potyviruses and their isolates vary in symptom expression, host range, and ability to overcome host resistance genes. Understanding factors influencing these biological characteristics is of agricultural importance for epidemiology and deployment of resistance strategies. Cucurbit crops are subject to severe losses by several potyviruses including the highly aggressive and variable zucchini yellow mosaic virus (ZYMV). In this project we sought to investigate protein domains in ZYMV that influence systemic infection and host range. Particular emphasis was on coat protein (CP), because of known functions in both cell to cell and long distance movement, and helper component-protease (HC-Pro), which has been implicated to play a role in symptom development and long distance movement. These two genes are also essential for aphid mediated transmission, and domains that influence disease development may also influence transmissibility. The objectives of the approved BARD project were to test roles of specific domains in the CP and HC-Pro by making sequence alterations or switches between different isolates and viruses, and testing for infectivity, host range, and aphid transmissibility. These objectives were largely achieved as described below. Finally, we also initiated new research to identify host factors interacting with potyviral proteins and demonstrated interaction between the ZYMV RNA dependent RNA polymerase and host poly-(A)-binding protein (Wang et al., in press). The focus of the CP studies (MSU) was to investigate the role of the highly variable amino terminus (NT) in host range determination and systemic infection. Hybrid ZYMV infectious clones were produced by substituting the CP-NT of ZYMV with either the CP-NT from watermelon mosaic virus (overlapping, but broader host range) or tobacco etch virus (TEV) (non- overlapping host range) (Grumet et al., 2000; Ullah ct al., in prep). Although both hybrid viruses initially established systemic infection, indicating that even the non-cucurbit adapted TEV CP-NT could facilitate long distance transport in cucurbits, after approximately 4-6, the plants inoculated with the TEV-CPNT hybrid exhibited a distinct recovery of reduced symptoms, virus titer, and virus specific protection against secondary infection. These results suggest that the plant recognizes the presence of the TEV CP-NT, which has not been adapted to infection of cucurbits, and initiates defense responses. The CP-NT also appears to play a role in naturally occurring resistance conferred by the zym locus in the cucumber line 'Dina-1'. Patterns of virus accumulation indicated that expression of resistance is developmentally controlled and is due to a block in virus movement. Switches between the core and NT domains of ZYMV-NAA (does not cause veinal chlorosis on 'Dina-1'), and ZYMV-Ct (causes veinal chlorosis), indicated that the resistance response likely involves interaction with the CP-NT (Ullah and Grumet, submitted). At the Volcani Center the main thrust was to identify domains in the HC-Pro that affect symptom expression or aphid transmissibility. From the data reported in the first and second year report and in the attached publications (Peng et al. 1998; Kadouri et al. 1998; Raccah et al. 2000: it was shown that: 1. The mutation from PTK to PAK resulted in milder symptoms of the virus on squash, 2. Two mutations, PAK and ATK, resulted in total loss of helper activity, 3. It was established for the first time that the PTK domain is involved in binding of the HC-Pro to the potyvirus particle, and 4. Some of these experiments required greater amount of HC-Pro, therefore a simpler and more efficient purification method was developed based on Ni2+ resin.
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