Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.6 (RNA polymerase)
 34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Under conditions unfavorable to growth, the nematode Caenorhabditis elegans enters a developmentally arrested stage, the dauer larva. We have examined gene expression in the dauer larva and during recovery from the dauer stage. Run-on transcription assays with isolated nuclei reveal a depression of general RNA polymerase II transcription to 11-17% of that in other stages. Transcription of individual gene families (including actin, collagen, hsp70, and histone) is similarly depressed relative to actively growing stages. Dauer larvae are, however, capable of being induced for heat shock messages, indicating that they are competent to initiate and elongate transcripts. For most genes surveyed, reduced transcription in dauer larvae correlates with a decrease in message abundance. Hsp70 mRNA, however, is transcribed at lower rates but accumulates at levels comparable to those in other stages. Interestingly, dauer larvae are 15-fold enriched in a mRNA for a C. elegans hsp90 gene. Hsp90 mRNA accumulation is regulated at least in part by differential stability. Dauer larvae thus appear to have a unique pattern of gene expression. Upon placement in food, dauer larvae reenter the developmental pathway as late-stage larvae. Dauer recovery is accompanied by a temporally regulated sequence of gene expression. At least four distinct patterns of gene expression can be distinguished during exit from the dauer stage. Steady-state levels of hsp70 and polyubiquitin mRNA rise sharply within 75 min of recovery before declining by the fourth hour. Actin and histone mRNAs increase steadily following 2-4 hr of recovery, whereas myosin mRNA increases after 10 hr. In contrast, hsp90 mRNA declines sharply within the first 75 min of recovery. Changes in mRNA populations during dauer formation and exit may be physiologically relevant.
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PMID:Gene expression in the Caenorhabditis elegans dauer larva: developmental regulation of Hsp90 and other genes. 157 99

In eukaryotic cells ubiquitin is synthesized as a polyubiquitin protein or as a protein fused at the carboxyl terminus to other polypeptides. An enzyme activity, ubiquitin protein peptidase, has been proposed to process these precursors by cleaving the peptide bond between adjoining ubiquitin molecules or between ubiquitin and the fused peptides. Using the cleavage of a 35S-labeled yeast ubiquitin protein fused to a synthetic 38-residue peptide obtained by in vivo metabolic labeling in Escherichia coli in an expression system based on the interaction of bacteriophage T7 RNA polymerase and its promoter, it is possible to detect a processing activity in soluble yeast extract. The specificity of the cleavage suggests this activity could be the in vivo processing activity for various ubiquitin precursor proteins in yeast cells. A similarly labeled ubiquitin protein fused to one cysteine residue was also utilized to detect an activity capable of removing a single cysteine residue from ubiquitin in a soluble extract. Employing assays based on the cleavage of labeled ubiquitin protein fusions, a ubiquitin protein peptidase activity from Saccharomyces cerevisiae was purified about 15,000-fold to yield a protein mixture consisting of only a few protein species. The major protein band which comigrated with the activities in in vitro assays has an apparent molecular weight of 29,000 when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two other protein species, about 20,000 and 10,000 in molecular weight, also comigrated with the in vitro activities throughout the purification procedure. Though our most purified protein fraction was shown to cleave various artificial ubiquitin protein fusions under our experimental conditions, it cannot cleave a ubiquitin dimer protein, suggesting the existence of functionally distinct ubiquitin protein peptidases. Our experimental protocol for preparing various labeled ubiquitin protein precursors provides a means to explore various processing enzymes existing in cells. The same protocol may also be adapted to prepare substrates for the study of other specific protein processing enzymes.
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PMID:Purification of a ubiquitin protein peptidase from yeast with efficient in vitro assays. 255 55

Ubiquitin is a small protein that was initially found to function as a tag that can be covalently attached to proteins to mark them for destruction by a multisubunit, adenosine 5'-triphosphate-dependent protease called the proteasome. Ubiquitin is now emerging as a key regulator of eukaryotic messenger RNA synthesis, a process that depends on the RNA synthetic enzyme RNA polymerase II and the transcription factors that control its activity. Ubiquitin controls messenger RNA synthesis not only by mechanisms involving ubiquitin-dependent destruction of transcription factors by the proteasome, but also by an intriguing collection of previously unknown and unanticipated mechanisms that appear to be independent of the proteasome.
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PMID:Emerging roles of ubiquitin in transcription regulation. 1201 99

Lysine-63-linked polyubiquitin chains are not thought to signal protein degradation but instead signal for a variety of cellular processes including some types of DNA repair. RNA polymerase (Pol) II is polyubiquitinated following DNA damage or upon treatment of nuclear extracts with the transcription inhibitor alpha-amanitin. Here, we report, using a reaction in vitro, that transcription-dependent polyubiquitination of RNA Pol II consists of lysine-63-linked chains. This modification is specific for RNA Pol II engaged in active transcription and arrested by alpha-amanitin.
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PMID:Transcription-dependent polyubiquitination of RNA polymerase II requires lysine 63 of ubiquitin. 1556 15

Crustacean muscle growth is discontinuous due to molt cycle. To characterize molt-related gene expression patterns, we studied the mRNA levels of molecular chaperone-ubiquitin and heat shock protein 70 (Hsp 70) in comparison with muscle protein alpha-actin and beta-actin in marine shrimp Litopenaeus vannamei. Total RNA from abdominal muscle was isolated from 3-month-old animals in six different molt stages. The mRNA levels of target genes were detected by reverse-transcriptase-multiplex PCR and expressed as the ratio to elongation factor-1alpha. Ubiquitin mRNA levels were relatively steady over all stages of the molt cycle. Hsp70 levels were not detectable in early postmolt and late premolt stages, but showed a progressive increase from late postmolt to intermolt stages. Expression levels of alpha-actin gene were lower during postmolt, reached a plateau in intermolt and remained relatively high in premolt stage. Levels of beta-actin increased progressively from postmolt to intermolt, reaching a maximum value in premolt. Therefore, the mRNAs encoding for ubiquitin and Hsp 70 in abdominal muscle did not increase significantly in premolt stages, which is typically associated with claw muscle degradation. Muscle structural alpha-actin and cytoskeletal beta-actin were increased during intermolt and premolt stages, suggesting high muscle growth during these stages in the abdominal muscle of the L. vannamei.
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PMID:Expression patterns of ubiquitin, heat shock protein 70, alpha-actin and beta-actin over the molt cycle in the abdominal muscle of marine shrimp Litopenaeus vannamei. 1703 5

Covalent modifications of proteins by ubiquitin and the Small Ubiquitin-like MOdifier (SUMO) have been revealed to be involved in a plethora of cellular processes, including transcription, DNA repair and DNA damage responses. It has been well known that in response to DNA damage that blocks transcription elongation, Rpb1, the largest subunit of RNA polymerase II (Pol II), is ubiquitylated and subsequently degraded in mammalian and yeast cells. However, it is still an enigma regarding how Pol II responds to damaged DNA and conveys signal(s) for DNA damage-related cellular processes. We found that Rpb1 is also sumoylated in yeast cells upon UV radiation or impairment of transcription elongation, and this modification is independent of DNA damage checkpoint activation. Ubc9, an E2 SUMO conjugase, and Siz1, an E3 SUMO ligase, play important roles in Rpb1 sumoylation. K1487, which is located in the acidic linker region between the C-terminal domain and the globular domain of Rpb1, is the major sumoylation site. Rpb1 sumoylation is not affected by its ubiquitylation, and vice versa, indicating that the two processes do not crosstalk. Abolishment of Rpb1 sumoylation at K1487 does not affect transcription elongation or transcription coupled repair (TCR) of UV-induced DNA damage. However, deficiency in TCR enhances UV-induced Rpb1 sumoylation, presumably due to the persistence of transcription-blocking DNA lesions in the transcribed strand of a gene. Remarkably, abolishment of Rpb1 sumoylation at K1487 causes enhanced and prolonged UV-induced phosphorylation of Rad53, especially in TCR-deficient cells, suggesting that the sumoylation plays a role in restraining the DNA damage checkpoint response caused by transcription-blocking lesions. Our results demonstrate a novel covalent modification of Rpb1 in response to UV induced DNA damage or transcriptional impairment, and unravel an important link between the modification and the DNA damage checkpoint response.
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PMID:Rpb1 sumoylation in response to UV radiation or transcriptional impairment in yeast. 1938 8

Ubiquitin-specific peptidase 42 (USP42) is a deubiquitylating enzyme that can target p53 and contribute to the stabilization of p53 in response to stress. We now show that USP42 can also regulate transcription independently of p53. USP42 co-localized with RNA polymerase II (RNA Pol II) in nuclear foci, bound to histone H2B, and deubiquitylated H2B. Depletion of USP42 increased H2B ubiquitylation at a model promoter and decreased both basal and induced transcription from a number of promoters. These results are consistent with a role for USP42 in regulating transcription by deubiquitylating histones.
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PMID:Ubiquitin-specific peptidase 42 (USP42) functions to deubiquitylate histones and regulate transcriptional activity. 2533 40

Ubiquitin, and components of the ubiquitin-proteasome system, feature extensively in the regulation of gene transcription. Although there are many examples of how ubiquitin controls the activity of transcriptional regulators and coregulators, there are few examples of core components of the transcriptional machinery that are directly controlled by ubiquitin-dependent processes. The budding yeast protein Asr1 is the prototypical member of the RPC (RING, PHD, CBD) family of ubiquitin-ligases, characterized by the presence of amino-terminal RING (really interesting new gene) and PHD (plant homeo domain) fingers and a carboxyl-terminal domain that directly binds the largest subunit of RNA polymerase II (pol II), Rpb1, in response to phosphorylation events tied to the initiation of transcription. Asr1-mediated oligo-ubiquitylation of pol II leads to ejection of two core subunits of the enzyme and is associated with inhibition of polymerase function. Here, we present evidence that Asr1-mediated ubiquitylation of pol II is required for silencing of subtelomeric gene transcription. We show that Asr1 associates with telomere-proximal chromatin and that disruption of the ubiquitin-ligase activity of Asr1--or mutation of ubiquitylation sites within Rpb1--induces transcription of silenced gene sequences. In addition, we report that Asr1 associates with the Ubp3 deubiquitylase and that Asr1 and Ubp3 play antagonistic roles in setting transcription levels from silenced genes. We suggest that control of pol II by nonproteolytic ubiquitylation provides a mechanism to enforce silencing by transient and reversible inhibition of pol II activity at subtelomeric chromatin.
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PMID:Antagonistic roles for the ubiquitin ligase Asr1 and the ubiquitin-specific protease Ubp3 in subtelomeric gene silencing. 2678 77

Transcription complexes that assemble at the HIV-1 promoter efficiently initiate transcription but generate paused RNA polymerase II downstream from the start site. The virally encoded Tat protein hijacks positive transcription elongation factor b (P-TEFb) to phosphorylate and activate this paused polymerase. In addition, Tat undergoes a series of reversible post-translational modifications that regulate distinct steps of the transcription cycle. To identify additional functionally important Tat cofactors, we performed RNAi knockdowns of sixteen previously identified Tat interactors and found that a novel E3 ligase, PJA2, ubiquitinates Tat in a non-degradative manner and specifically regulates the step of HIV transcription elongation. Interestingly, several different lysine residues in Tat can function as ubiquitin acceptor sites, and variable combinations of these lysines support both full transcriptional activity and viral replication. Further, the polyubiquitin chain conjugated to Tat by PJA2 can itself be assembled through variable ubiquitin lysine linkages. Importantly, proper ubiquitin chain assembly by PJA2 requires that Tat first binds its P-TEFb cofactor. These results highlight that both the Tat substrate and ubiquitin modification have plastic site usage, and this plasticity is likely another way in which the virus exploits the host molecular machinery to expand its limited genetic repertoire.
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PMID:PJA2 ubiquitinates the HIV-1 Tat protein with atypical chain linkages to activate viral transcription. 2834 3

DNA repair is essential to prevent the cytotoxic or mutagenic effects of various types of DNA lesions, which are sensed by distinct pathways to recruit repair factors specific to the damage type. Although biochemical mechanisms for repairing several forms of genomic insults are well understood, the upstream signalling pathways that trigger repair are established for only certain types of damage, such as double-stranded breaks and interstrand crosslinks. Understanding the upstream signalling events that mediate recognition and repair of DNA alkylation damage is particularly important, since alkylation chemotherapy is one of the most widely used systemic modalities for cancer treatment and because environmental chemicals may trigger DNA alkylation. Here we demonstrate that human cells have a previously unrecognized signalling mechanism for sensing damage induced by alkylation. We find that the alkylation repair complex ASCC (activating signal cointegrator complex) relocalizes to distinct nuclear foci specifically upon exposure of cells to alkylating agents. These foci associate with alkylated nucleotides, and coincide spatially with elongating RNA polymerase II and splicing components. Proper recruitment of the repair complex requires recognition of K63-linked polyubiquitin by the CUE (coupling of ubiquitin conjugation to ER degradation) domain of the subunit ASCC2. Loss of this subunit impedes alkylation adduct repair kinetics and increases sensitivity to alkylating agents, but not other forms of DNA damage. We identify RING finger protein 113A (RNF113A) as the E3 ligase responsible for upstream ubiquitin signalling in the ASCC pathway. Cells from patients with X-linked trichothiodystrophy, which harbour a mutation in RNF113A, are defective in ASCC foci formation and are hypersensitive to alkylating agents. Together, our work reveals a previously unrecognized ubiquitin-dependent pathway induced specifically to repair alkylation damage, shedding light on the molecular mechanism of X-linked trichothiodystrophy.
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PMID:A ubiquitin-dependent signalling axis specific for ALKBH-mediated DNA dealkylation repair. 2914 57


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