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Compound
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Gene/Protein
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Target Concepts:
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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)
The
CCR4-NOT
complex (1 mDa in size), consisting of the proteins CCR4, CAF1, and NOT1 to NOT5, regulates gene expression both positively and negatively and is distinct from other large transcriptional complexes in Saccharomyces cerevisiae such as SNF/SWI, TFIID, SAGA, and
RNA polymerase II
holoenzyme. The physical and genetic interactions between the components of the
CCR4-NOT
complex were investigated in order to gain insight into how this complex affects the expression of diverse genes and processes. The CAF1 protein was found to be absolutely required for CCR4 association with the NOT proteins, and CCR4 and CAF1, in turn, physically interacted with NOT1 through its central amino acid region from positions 667 to 1152. The NOT3, NOT4, and NOT5 proteins had no significant effect on the association of CCR4, CAF1, and NOT1 with each other. In contrast, the NOT2, NOT4, and NOT5 interacted with the C-terminal region (residues 1490 to 2108) of NOT1 in which NOT2 and NOT5 physically associated in the absence of CAF1, NOT3, and NOT4. These and other data indicate that the physical ordering of these proteins in the complex is CCR4-CAF1-NOT1-(NOT2, NOT5), with NOT4 and NOT3 more peripheral to NOT2 and NOT5. The physical separation of CCR4 and CAF1 from other components of the
CCR4-NOT
complex correlated with genetic analysis indicating partially separate functions for these two groups of proteins. ccr4 or caf1 deletion suppressed the increased 3-aminotriazole resistance phenotype conferred by not mutations, resulted in opposite effects on gene expression as compared to several not mutations, and resulted in a number of synthetic phenotypes in combination with not mutations. These results define the
CCR4-NOT
complex as consisting of at least two physically and functionally separated groups of proteins.
...
PMID:The CCR4 and CAF1 proteins of the CCR4-NOT complex are physically and functionally separated from NOT2, NOT4, and NOT5. 1049 Jun 3
The yeast
CCR4-NOT
protein complex is a global regulator of
RNA polymerase II
transcription. It is comprised of yeast NOT1 to NOT5, yeast CCR4 and additional proteins like yeast CAF1. Here we report the isolation of cDNAs encoding human NOT2, NOT3, NOT4 and a CAF1-like factor, CALIF. Analysis of their mRNA levels in different human tissues reveals a common ubiquitous expression pattern. A multitude of two-hybrid interactions among the human cDNAs suggest that their encoded proteins also form a complex in mammalian cells. Functional conservation of these proteins throughout evolution is supported by the observation that the isolated human NOT3 and NOT4 cDNAs can partially com-plement corresponding not mutations in yeast. Interestingly, human CALIF is highly homologous to, although clearly different from, a recently described human CAF1 protein. Conserved interactions of this factor with both NOT and CCR4 proteins and co-immunoprecipitation experiments suggest that CALIF is a bona fide component of the human
CCR4-NOT
complex.
...
PMID:Isolation and characterization of human orthologs of yeast CCR4-NOT complex subunits. 1063 34
The
CCR4-NOT
transcriptional regulatory complex affects transcription both positively and negatively and consists of the following two complexes: a core 1 x 10(6) dalton (1 MDa) complex consisting of CCR4, CAF1, and the five NOT proteins and a larger, less defined 1.9-MDa complex. We report here the identification of two new factors that associate with the
CCR4-NOT
proteins as follows: CAF4, a WD40-containing protein, and CAF16, a putative ABC ATPase. Whereas neither CAF4 nor CAF16 was part of the core
CCR4-NOT
complex, both CAF16 and CAF4 appeared to be present in the 1.9-MDa complex. CAF4 also displayed physical interactions with multiple
CCR4-NOT
components and with DBF2, a likely component of the 1.9-MDa complex. In addition, both CAF4 and CAF16 were found to interact in a CCR4-dependent manner with SRB9, a component of the SRB complex that is part of the yeast
RNA polymerase II
holoenzyme. The three related SRB proteins, SRB9, SRB10, and SRB11, were found to interact with and to coimmunoprecipitate DBF2, CAF4, CCR4, NOT2, and NOT1. Defects in SRB9 and SRB10 also affected processes at the ADH2 locus known to be controlled by components of the
CCR4-NOT
complex; an srb9 mutation was shown to reduce ADH2 derepression and either an srb9 or srb10 allele suppressed spt10-enhanced expression of ADH2. In addition, srb9 and srb10 alleles increased ADR1(c)-dependent ADH2 expression; not4 and not5 deletions are the only other known defects that elicit this phenotype. These results suggest a close physical and functional association between components of the
CCR4-NOT
complexes and the SRB9, -10, and -11 components of the holoenzyme.
...
PMID:Characterization of CAF4 and CAF16 reveals a functional connection between the CCR4-NOT complex and a subset of SRB proteins of the RNA polymerase II holoenzyme. 1111 36
The RING finger protein
CNOT4
is a component of the
CCR4-NOT
complex. This complex is implicated in repression of
RNA polymerase II
transcription. Here we demonstrate that
CNOT4
functions as a ubiquitin-protein ligase (E3). We show that the unique C4C4 RING domain of
CNOT4
interacts with a subset of ubiquitin-conjugating enzymes (E2s). Using NMR spectroscopy, we detail the interaction of
CNOT4
with UbcH5B and characterize RING residues that are critical for this interaction.
CNOT4
acts as a potent E3 ligase in vitro. Mutations that destabilize the E2-E3 interface abolish this activity. Based on these results, we present a model of how E3 ligase function within the
CCR4-NOT
complex relates to transcriptional regulation.
...
PMID:Identification of a ubiquitin-protein ligase subunit within the CCR4-NOT transcription repressor complex. 1182 28
The human
CCR4-NOT
complex is a global regulator of
RNA polymerase II
transcription. Recently, we showed that the RING domain
CNOT4
subunit contains intrinsic ubiquitin-protein ligase (E3) activity. Here we show that binding of the
CNOT4
RING finger to the ubiquitin-conjugating enzyme (E2) UbcH5B is highly selective. To understand the basis for this interaction, we identified several basic residues of UbcH5B important for binding to
CNOT4
by mutational analysis. Subsequently, we tested pairs of UbcH5B and
CNOT4
mutants for restoration of interaction. Concomitant charge-alteration of E49 of
CNOT4
and K63 of UbcH5B restored binding and re-created a functional enzyme pair, indicative of an electrostatic interaction between these residues. The corresponding amino acids in the yeast orthologues can also be used to create a similarly designed E2-E3 enzyme pair. These are the first examples of altered-specificity E2-E3 enzyme pairs and give further insight into how E2-E3 specificity is obtained.
...
PMID:An altered-specificity ubiquitin-conjugating enzyme/ubiquitin-protein ligase pair. 1500 59
To identify new nonessential genes that affect genome integrity, we completed a screening for diploid mutant Saccharomyces cerevisiae strains that are sensitive to ionizing radiation (IR) and found 62 new genes that confer resistance. Along with those previously reported (Bennett et al., Nat. Genet. 29:426-434, 2001), these genes bring to 169 the total number of new IR resistance genes identified. Through the use of existing genetic and proteomic databases, many of these genes were found to interact in a damage response network with the transcription factor Ccr4, a core component of the
CCR4-NOT
and
RNA polymerase
-associated factor 1 (PAF1)-CDC73 transcription complexes. Deletions of individual members of these two complexes render cells sensitive to the lethal effects of IR as diploids, but not as haploids, indicating that the diploid G1 cell population is radiosensitive. Consistent with a role in G1, diploid ccr4Delta cells irradiated in G1 show enhanced lethality compared to cells exposed as a synchronous G2 population. In addition, a prolonged RAD9-dependent G1 arrest occurred following IR of ccr4Delta cells and CCR4 is a member of the RAD9 epistasis group, thus confirming a role for CCR4 in checkpoint control. Moreover, ccr4Delta cells that transit S phase in the presence of the replication inhibitor hydroxyurea (HU) undergo prolonged cell cycle arrest at G2 followed by cellular lysis. This S-phase replication defect is separate from that seen for rad52 mutants, since rad52Delta ccr4Delta cells show increased sensitivity to HU compared to rad52Delta or ccr4Delta mutants alone. These results indicate that cell cycle transition through G1 and S phases is CCR4 dependent following radiation or replication stress.
...
PMID:Cell cycle progression in G1 and S phases is CCR4 dependent following ionizing radiation or replication stress in Saccharomyces cerevisiae. 1507 73
Wild-type transcriptional activation by Gcn4p is dependent on multiple coactivators, including SAGA, SWI/SNF, Srb mediator,
CCR4-NOT
, and RSC, which are all recruited by Gcn4p to its target promoters in vivo. It was not known whether these coactivators are required for assembly of the preinitiation complex (PIC) or for subsequent steps in the initiation or elongation phase of transcription. We find that mutations in subunits of these coactivators reduce the recruitment of TATA binding protein (TBP) and
RNA polymerase II
(Pol II) by Gcn4p at ARG1, ARG4, and SNZ1, implicating all five coactivators in PIC assembly at Gcn4p target genes. Recruitment of Pol II at SNZ1 and ARG1 was eliminated by mutations in TBP or by deletion of the TATA box, indicating that TBP binding is a prerequisite for Pol II recruitment by Gcn4p. However, several mutations in SAGA subunits and deletion of SRB10 had a greater impact on promoter occupancy of Pol II versus TBP, suggesting that SAGA and Srb mediator can promote Pol II binding independently of their stimulatory effects on TBP recruitment. Our results reveal an unexpected complexity in the cofactor requirements for the enhancement of PIC assembly by a single activator protein.
...
PMID:An array of coactivators is required for optimal recruitment of TATA binding protein and RNA polymerase II by promoter-bound Gcn4p. 1512 33
Genetic experiments have indicated a role for the Ccr4-Not complex in the response to hydroxyurea (HU) induced replication stress and ionizing radiation in yeast. This response includes transcriptional induction of the four genes constituting the ribonucleotide reductase (RNR) enzymatic complex, RNR1-4 and degradation of its inhibitor, Sml1p. The Ccr4-Not complex has originally been described as a negative regulator of
RNA polymerase II
(pol II) transcription, but it has also been implicated in mRNA turnover and protein ubiquitination. We investigated the mechanism of the HU sensitivity conferred by mutation of
CCR4-NOT
genes. We found that the ubiquitin protein ligase activity of Not4p does not play a role in HU induced Sml1p degradation. We show, however, that the HU sensitivity of ccr4-not mutant strains correlated very well with a defect in accumulation of RNR2, RNR3 and RNR4 mRNA after HU or methyl-methane sulfonate (MMS) treatment. Chromatin immunoprecipitation (ChIP) experiments show that TBP, pol II and Set1p recruitment to the activated RNR3 locus is defective in cells lacking NOT4. Moreover, RNR3-promoter activity is not induced by HU in these cells. Our experiments show that induction of RNR gene transcription is defective in ccr4-not mutant strains, providing an explanation for their sensitivity to HU.
...
PMID:DNA damage and replication stress induced transcription of RNR genes is dependent on the Ccr4-Not complex. 1627 85
Influenza A virus (IAV) RNA segments are individually packaged with viral nucleoprotein (NP) and RNA polymerases to form a viral ribonucleoprotein (vRNP) complex. We previously reported that NP is a monoubiquitinated protein which can be deubiquitinated by a cellular ubiquitin protease, USP11. In this study, we identified an E3 ubiquitin ligase,
CNOT4
(Ccr4-Not transcription complex subunit 4), which can ubiquitinate NP. We found that the levels of viral RNA, protein, viral particles, and
RNA polymerase
activity in
CNOT4
knockdown cells were lower than those in the control cells upon IAV infection. Conversely, overexpression of
CNOT4
rescued viral RNP activity. In addition,
CNOT4
interacted with the NP in the cell. An
in vitro
ubiquitination assay also showed that NP could be ubiquitinated by
in vitro
-translated
CNOT4
, but ubiquitination did not affect the protein stability of NP. Significantly,
CNOT4
increased NP ubiquitination, whereas USP11 decreased it. Mass spectrometry analysis of ubiquitinated NP revealed multiple ubiquitination sites on the various lysine residues of NP. Three of these, K184, K227, and K273, are located on the RNA-binding groove of NP. Mutations of these sites to arginine reduced viral RNA replication. These results indicate that
CNOT4
is a ubiquitin ligase of NP, and ubiquitination of NP plays a positive role in viral RNA replication.
IMPORTANCE
Influenza virus, particularly influenza A virus, causes severe and frequent outbreaks among human and avian species. Finding potential target sites for antiviral agents is of utmost importance from the public health point of view. We previously found that viral nucleoprotein (NP) is ubiquitinated, and ubiquitination enhances viral RNA replication. In this study, we found a cellular ubiquitin ligase,
CNOT4
, capable of ubiquitinating NP. The ubiquitination sites are scattered on the surface of the NP molecule, which is critical for RNA replication.
CNOT4
and a ubiquitin protease, USP11, together regulate the extent of NP ubiquitination and thereby the efficiency of RNA replication. This study thus identifies a potential antiviral target site and reveals a novel posttranslational mechanism for regulating viral replication. This represents a novel finding in the literature of influenza virus research.
...
PMID:CNOT4-Mediated Ubiquitination of Influenza A Virus Nucleoprotein Promotes Viral RNA Replication. 2853 88
The biological significance of deadenylation in global gene expression is not fully understood. Here, we show that the
CCR4-NOT
deadenylase complex maintains expression of mRNAs, such as those encoding transcription factors, cell cycle regulators, DNA damage response-related proteins, and metabolic enzymes, at appropriate levels in the liver. Liver-specific disruption of
Cnot1
, encoding a scaffold subunit of the
CCR4-NOT
complex, leads to increased levels of mRNAs for transcription factors, cell cycle regulators, and DNA damage response-related proteins because of reduced deadenylation and stabilization of these mRNAs. CNOT1 suppression also results in an increase of immature, unspliced mRNAs (pre-mRNAs) for apoptosis-related and inflammation-related genes and promotes
RNA polymerase II
loading on their promoter regions. In contrast, mRNAs encoding metabolic enzymes become less abundant, concomitant with decreased levels of these pre-mRNAs. Lethal hepatitis develops concomitantly with abnormal mRNA expression. Mechanistically, the
CCR4-NOT
complex targets and destabilizes mRNAs mainly through its association with Argonaute 2 (AGO2) and butyrate response factor 1 (BRF1) in the liver. Therefore, the
CCR4-NOT
complex contributes to liver homeostasis by modulating the liver transcriptome through mRNA deadenylation.
...
PMID:The CCR4-NOT complex maintains liver homeostasis through mRNA deadenylation. 3223 56
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