Following its tyrosine phosphorylation, STAT3 is methylated on K140 by the histone methyl transferase SET9 and demethylated by LSD1 when it is bound to a subset of the promoters that it activates. Methylation of K140 is a negative regulatory event, because its blockade greatly increases the steady-state amount of activated STAT3 and the expression of many (i.e., SOCS3) but not all (i.e., CD14) STAT3 target genes. Biological relevance is shown by the observation that overexpression of SOCS3 when K140 cannot be methylated blocks the ability of cells to activate STAT3 in response to IL-6. K140 methylation does not occur with mutants of STAT3 that do not enter nuclei or bind to DNA. Following treatment with IL-6, events at the SOCS3 promoter occur in an ordered sequence, as shown by chromatin immunoprecipitations. Y705-phosphoryl-STAT3 binds first and S727 is then phosphorylated, followed by the coincident binding of SET9 and dimethylation of K140, and lastly by the binding of LSD1. We conclude that the lysine methylation of promoter-bound STAT3 leads to biologically important down-regulation of the dependent responses and that SET9, which is known to help provide an activating methylation mark to H3K4, is recruited to the newly activated SOCS3 promoter by STAT3. (2) and some of the same lysine side chains can be either methylated or acetylated. These modifications alter chromatin structure, often by providing entry sites for proteins that determine higher-order chromatin organization, leading to the activation or inactivation of specific genes. In addition, methylation and demethylation of p53 and NFκB are carried out by enzymes previously known to modify only histones. For p53, the reactions occur on K370, K372, and K382 (3). For NFκB, K37 is methylated by SET9 (4), and K218 and K221 are methylated by NSD1 and demethylated by FBXL11 (5).STAT3 is phosphorylated on tyrosine and serine residues in response to many different cytokines and growth factors, leading to the formation of dimers through reciprocal phosphotyrosine-SH2 interactions (6). Activated STAT3 dimers bind to and activate the promoters of target genes. In addition to phosphorylation, STAT3 was reported to be acetylated at K685 following cytokine stimulation, and the K685R mutation blocked its activation (7), but these observations have been disputed (8). Ray et al. (9) reported that K49 and K87 of STAT3 are acetylated by p300 and that the K-R mutations resulted in a STAT3 protein that is able to translocate into nuclei, but unable to bind to p300. Here, we show that, in response to IL-6, STAT3 is methylated on K140 by the H3K4 methyl transferase SET9 and demethylated by the H3K4 demethylase LSD1 (lysine-specific demethylase 1, also named BHC110). Prevention of methylation by mutation of K140 greatly enhances the induction of one group of genes in response to IL-6, but has little effect on a second group, and inhibits the activation of a third group. Several lines of evidence indicate that methylation takes place as STAT3 is bound to promoters in the f...
The ubiquitous inducible transcription factor NF-κB plays central roles in immune and inflammatory responses and in tumorigenesis. Complex posttranslational modifications of the p65 subunit (RelA) are a major aspect of the extremely flexible regulation of NF-κB activity. Although phosphorylation, acetylation, ubiquitination, and lysine methylation of NF-κB have been well described, arginine methylation has not yet been found. We now report that, in response to IL-1β, the p65 subunit of NF-κB is dimethylated on arginine 30 (R30) by protein-arginine methyltransferase 5 (PRMT5). Expression of the R30A and R30K mutants of p65 substantially decreased the ability of NF-κB to bind to κB elements and to drive gene expression. A model in which dimethyl R30 is placed into the crystal structure of p65 predicts new van der Waals contacts that stabilize intraprotein interactions and indirectly increase the affinity of p65 for DNA. PRMT5 was the only arginine methyltransferase that coprecipitated with p65, and its overexpression increased NF-κB activity, whereas PRMT5 knockdown had the opposite effect. Microarray analysis revealed that ∼85% of the NF-κB-inducible genes that are down-regulated by the R30A mutation are similarly down-regulated by knocking PRMT5 down. Many cytokine and chemokine genes are among these, and conditioned media from cells expressing the R30A mutant of p65 had much less NF-κB-inducing activity than media from cells expressing the wild-type protein. PRMT5 is overexpressed in many types of cancer, often to a striking degree, indicating that high levels of this enzyme may promote tumorigenesis, at least in part by facilitating NF-κB-induced gene expression.histone | mass spectrometry T he NF-κB family is comprised of two protein subfamilies: c-Rel, RelB, and RelA (p65), which include transactivation domains in their C termini, and p100 (p52) and p105 (p50), which include a number of ankyrin repeats in their C termini and have transrepressive functions. All family members include an N-terminal DNA-binding region, the Rel homology domain (1). In the absence of an activating stimulus, NF-κB is located in the cytoplasm in a complex with the inhibitory IκB protein. In the classic pathway of NF-κB activation, extracellular signals activate IκB kinase, which phosphorylates IκBα, leading to its ubiquitination and degradation by proteasomes. NF-κB, liberated from IκB, translocates to the nucleus to regulate its target genes (2). The NF-κB pathway is regulated by means of several different posttranslational modifications, including ubiquitination, phosphorylation, acetylation, sumoylation, and nitrosylation (3). The recent work of several laboratories has revealed the reversible methylation of nonhistone proteins by enzymes that were discovered on the basis of their activities toward histones. For NF-κB, we found that in response to an activating signal, such as treatment with IL-1β, the p65 subunit is reversibly methylated on two specific lysine residues by chromatin remodeling enzymes in ways that profoundly aff...
NF-κB, a central coordinator of immune and inflammatory responses, must be tightly regulated. We describe a NF-κB regulatory pathway that is driven by reversible lysine methylation of the p65 subunit, carried out by a lysine methylase, the nuclear receptorbinding SET domain-containing protein 1 (NSD1), and a lysine demethylase, F-box and leucine-rich repeat protein 11 (FBXL11). Overexpression of FBXL11 inhibits NF-κB activity, and a high level of NSD1 activates NF-κB and reverses the inhibitory effect of FBXL11, whereas reduced expression of NSD1 decreases NF-κB activation. The targets are K218 and K221 of p65, which are methylated in cells with activated NF-κB. Overexpression of FBXL11 slowed the growth of HT29 cancer cells, whereas shRNA-mediated knockdown had the opposite effect, and these phenotypes were dependent on K218/K221 methylation. In mouse embryo fibroblasts, the activation of most p65-dependent genes relied on K218/K221 methylation. Importantly, expression of the FBXL11 gene is driven by NF-κB, revealing a negative regulatory feedback loop. We conclude that reversible lysine methylation of NF-κB is an important element in the complex regulation of this key transcription factor. [RelA (p65), RelB, c-Rel, NF-κB1 (p50), and NF-κB2 (p52)], the p65/p50 heterodimer functions most often in the "classical" signaling pathway (1). Constitutive NF-κB activation is frequently associated with a number of pathological conditions, including inflammation and cancer, and is well known to be involved in tumor angiogenesis and invasiveness (2). Loss of the normal regulation of NF-κB is a major contributor to the deregulated growth, resistance to apoptosis, and propensity to metastasize observed in many different cancers (3). Our data, showing NF-κB activation in many cancer-derived cell lines (4, 5), further support the strong correlation between constitutive NF-κB activation and cancer. Thus, understanding the complexity of NF-κB-dependent signaling is an important aspect of dealing with these diseases.NF-κB has a variety of functions and is regulated by hundreds of different stimuli in different cell types (6). Specialized control of NF-κB activity is critical for achieving its normal transient activation in response to stress. Regardless of the stimulus, all pathways leading to NF-κB activation depend on inducing posttranslational modifications of the IκB kinase, IκB proteins, or NF-κB subunits. These regulatory modifications, including phosphorylation, ubiquitination, acetylation, sumolation, and nitrosylation, vary depending on the specific stimulus and context (7).We have developed a lentiviral validation-based insertional (VBIM) method to create mutant cell lines in which the overexpression of specific cellular proteins, driven by inserted CMV promoters, is responsible for altered phenotypes. We used this method to identify the F-box and leucine-rich repeat protein 11 (FBXL11) as a potent negative regulator of NF-κB and to show that its demethylase activity was required for this function (8). FBXL11, previous...
USF1 and USF2 are basic helix-loop-helix transcription factors implicated in the control of cellular proliferation. In HeLa cells, the USF proteins are transcriptionally active and their overexpression causes marked growth inhibition. In contrast, USF overexpression had essentially no effect on the proliferation of the Saos-2 osteosarcoma cell line. USF1 and USF2 also lacked transcriptional activity in Saos-2 cells when assayed by transient cotransfection with USF-dependent reporter genes. Yet, there was no difference in the expression, subcellular localization, or DNA-binding activity of the USF proteins in HeLa and Saos-2 cells. Furthermore, Gal4-USF1 and Gal4-USF2 fusion proteins activated transcription similarly in both cell lines. Mutational analysis and domain swapping experiments revealed that the small, highly conserved USF-specific region (USR) was responsible for the inactivity of USF in Saos-2 cells. In HeLa, the USR serves a dual function. It acts as an autonomous transcriptional activation domain at promoters containing an initiator element and also induces a conformational change that is required for USF activity at promoters lacking an initiator. Taken together, these results suggest a model in which the transcriptional activity of the USF proteins, and consequently their antiproliferative activity, is tightly controlled by interaction with a specialized coactivator that recognizes the conserved USR domain and, in contrast to USF, is not ubiquitous. The activity of USF is therefore context dependent, and evidence for USF DNA-binding activity in particular cells is insufficient to indicate USF function in transcriptional activation and growth control.
Protein arginine methyltransferases (PRMTs) are a family of enzymes that can methylate arginine residues on histones and other proteins. PRMTs play a crucial role in influencing various cellular functions, including cellular development and tumorigenesis. Arginine methylation by PRMTs is found on both nuclear and cytoplasmic proteins. Recently, there is increasing evidence regarding post-translational modifications of non-histone proteins by PRMTs, illustrating the previously unknown importance of PRMTs in the regulation of various cellular functions by post-translational modifications. In this review, we present the recent developments in the regulation of non-histone proteins by PRMTs.
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