The Regulatory Particle of the <i>Saccharomyces cerevisiae</i> Proteasome

Glickman, Michael S.; Rubin, David M.; Fried, Victor A.; Finley, Daniel

doi:10.1128/mcb.18.6.3149

Cited by 467 publications

(461 citation statements)

References 109 publications

(86 reference statements)

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“…This sequence was identical to that in Genbank Accession D14663, identi®ed previously as the human subunit 10 of the 26S proteasome regulatory particle, a multi-subunit complex that regulates core particle-mediated degradation of proteins including several oncogene or tumor suppressor gene products (Dubiel et al, 1995;Glickman et al, 1998b).…”

Section: Sequence Analysismentioning

confidence: 57%

“…A more striking similarity occurs at residues 240 ± 348 (32% identical and 57% similar/identical), representing the PINT/PCI domain present in components of multisubunit complexes such as the proteasome, the translation initiation factor eIF3, and the cop9/ signalosome (Glickman et al, 1998a). While it remains to be determined whether up-regulation of p44 S10 expression a ects proteasome function, the expression of many growth-regulatory proteins are regulated by the proteasome pathway, including cyclins, CDK inhibitors, p53, NF-kB, c-Fos, c-Jun, and others (Hochstrasser, 1996;Coux et al, 1996;Glickman et al, 1998b). Consistent with a role for proteasome activity in tumor progression is the regulation of G1-S and M phase cell cycle transitions by ubiquitin-mediated degradation of multiple cellular proteins such as the G1 CDK inhibitor SIC1 (King et al, 1996).…”

Section: Discussionmentioning

confidence: 99%

“…The predicted polypeptides from these species were very similar in size to human p44 S10 , which contains 389 residues, and were identical in sequence in 40 ± 47% of residues. As previously shown for the human subunit, the homologous S. cerevisiae sequence was recently con®rmed as proteasome regulatory particle subunit RPN7 by denaturing gel electrophoresis and amino acid sequence analysis of the puri®ed proteasome (Dubiel et al, 1995;Glickman et al, 1998b).…”

Section: Sequence Analysismentioning

confidence: 92%

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The p44S10 locus, encoding a subunit of the proteasome regulatory particle, is amplified during progression of cutaneous malignant melanoma

et al. 2000

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Section: Sequence Analysismentioning

confidence: 57%

Section: Discussionmentioning

confidence: 99%

Section: Sequence Analysismentioning

confidence: 92%

See 1 more Smart Citation

The p44S10 locus, encoding a subunit of the proteasome regulatory particle, is amplified during progression of cutaneous malignant melanoma

et al. 2000

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“…The base Rpn subunits are involved in the recognition of the poly-ubiquitin chain and the Rpt ATPase subunits guide the unfolding and translocation of the polypeptide substrate into the CP ( Finley et al , 1998). In contrast to the RP base subunits, the subunits comprising the RP lid are only of the non-ATPase class: Rpn3, Rpn5-9, Rpn11 and Rpn12 ( Glickman et al , 1998). The main known function of the RP lid is the processing of poly-ubiquitin chains.…”

Section: Discussion/analysis Of the Literaturementioning

confidence: 99%

Intracellular Dynamics of the Ubiquitin-Proteasome-System

Chowdhury

Enenkel

2015

F1000Res

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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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“…DHH1 is a non-essential DEAD-box helicase that has been implicated in SWE1 function (Strahl-Bolsinger and Tanner, 1993;Warbick and Glover, 1994;Moriya and Isono, 1999), translation (Ladomery et al, 1997), transcription (Hata et al, 1998) and cell cycle arrest under stressful conditions (Maekawa et al, 1994;Bergkessel and Reese, unpublished). RPN11 encodes a regulatory subunit of the 26S proteasome that is required for G 2 /M progression (Glickman et al, 1998;Rinaldi et al, 1998) and for the activation of the transcription factor Gcn4p by UV-induced stress (Stitzel et al, 2001). YBR157C is the only gene product that has not been characterized; however, its expression is cell cycle-regulated, Genetic analysis of TAF68/61 1199 peaking at mitosis (Cho et al, 1998;Spellman et al, 1998).…”

Section: Isolation Of High Copy Suppressors Of the Taf68-9 Mutantmentioning

confidence: 99%

Genetic analysis of TAF68/61 reveals links to cell cycle regulators

Reese

Green

2001

Yeast

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In yeast, inactivation of certain TBP-associated factors (TAF II s) results in arrest at specific stages of the cell cycle. In some cases, cell cycle arrest is not observed because overlapping defects in other cellular processes precludes the manifestation of an arrest phenotype. In the latter situation, genetic analysis has the potential to reveal the involvement of TAF II s in cell cycle regulation. In this report, a temperature-sensitive mutant of TAF68/61 was used to screen for high-copy dosage suppressors of its growth defect. Ten genes were isolated: TAF suppressor genes, TSGs 1-10. Remarkably, most TSGs have either a genetic or a direct link to control of the G 2 /M transition. Moreover, eight of the 10 TSGs can suppress a CDC28 mutant specifically defective for mitosis (cdc28-1N) but not an allele defective for passage through start. The identification of these genes as suppressors of cdc28-1N has identified four unreported suppressors of this allele. Moreover, synthetic lethality is observed between taf68-9 and cdc28-1N. The isolation of multiple genes involved in the control of a specific phase of the cell cycle argue that the arrest phenotypes of certain TAF II mutants reflect their role in specifically regulating cell cycle functions.

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The Regulatory Particle of the Saccharomyces cerevisiae Proteasome

Cited by 467 publications

References 109 publications

The p44S10 locus, encoding a subunit of the proteasome regulatory particle, is amplified during progression of cutaneous malignant melanoma

The p44S10 locus, encoding a subunit of the proteasome regulatory particle, is amplified during progression of cutaneous malignant melanoma

Intracellular Dynamics of the Ubiquitin-Proteasome-System

Genetic analysis of TAF68/61 reveals links to cell cycle regulators

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