Nuclear role of WASp in gene transcription is uncoupled from its ARP2/3-dependent cytoplasmic role in actin polymerization (original) (raw)
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The function of actin in gene transcription
Histology and Histopathology Cellular and Molecular Biology, 2007
Recent developments in the field of gene transcription regulation have unfolded a key role for actin as an important co-factor for all three eukaryotic RNA polymerases. In this review article we discuss the latest findings on actin in transcription of protein-coding and ribosomal genes, in complex with specific hnRNP proteins and a form of myosin 1ß which is entirely localized to the cell nucleus. Based on these recent studies, we propose a general model where actin may function in basal gene transcription as an allosteric regulator, to recruit transcriptional co-activators on active genes. A future challenge will be the identification of the polymerization state of actin in gene transcription and how it is mechanistically regulated.
Actin is part of pre-initiation complexes and is necessary for transcription by RNA polymerase II
Nature Cell Biology, 2004
Actin is abundant in the nucleus and has been implicated in transcription; however, the nature of this involvement has not been established. Here we demonstrate that β-actin is critically involved in transcription because antibodies directed against βactin, but not muscle actin, inhibited transcription in vivo and in vitro. Chromatin immunoprecipitation assays demonstrated the recruitment of actin to the promoter region of the interferon-γ-inducible MHC2TA gene as well as the interferon-α-inducible G1P3 gene. Further investigation revealed that actin and RNA polymerase II co-localize in vivo and also co-purify. We employed an in vitro system with purified nuclear components to demonstrate that antibodies to β-actin block the initiation of transcription. This assay also demonstrates that β-actin stimulates transcription by RNA polymerase II. Finally, DNA-binding experiments established the presence of β-actin in pre-initiation complexes and also showed that the depletion of actin prevented the formation of pre-initiation complexes. Together, these data suggest a fundamental role for actin in the initiation of transcription by RNA polymerase II.
Nuclear Actin-Binding Proteins as Modulators of Gene Transcription
Traffic, 2005
Dynamic transformations in the organization of the cellular microfilament system are the driving force behind fundamental biological processes such as cellular motility, cytokinesis, wound healing and secretion. Eukaryotic cells express a plethora of actin-binding proteins (ABPs) allowing cells to control the organization of the actin cytoskeleton in a flexible manner. These structural proteins were, not surprisingly, originally described as (major) constituents of the cytoplasm. However, in recent years, there has been a steady flow of reports detailing not only translocation of ABPs into and out of the nucleus but also describing their role in the nuclear compartment. This review focuses on recent developments pertaining to nucleocytoplasmic transport of ABPs, including their mode of translocation and nuclear function. In particular, evidence that structurally and functionally unrelated cytoplasmic ABPs regulate transcription activation by various nuclear (steroid hormone) receptors is steadily accruing. Furthermore, the recent finding that actin is a necessary component of the RNA polymerase II-containing preinitiation complex opens up new opportunities for nuclear ABPs in gene transcription regulation.
Analysis of nuclear actin-interacting proteins and actin-regulated transcription factors
2019
Actin is best-known from its functions in the cytoplasm, where it is a key component of the cytoskeleton. Cytoskeleton is vital for cells as it enables cell movement and maintains cell shape. Nevertheless, functions of actin are not restricted to the cytoplasm, since actin is also present in the nucleus, where it has been linked to multiple functions from gene activation to chromatin remodeling. Live cell imaging with different nuclear actin probes have demonstrated the importance of actin dynamics inside the nucleus, but the molecular mechanisms by which actin operates in the nucleus are still poorly understood. This is mainly because of the lack of wellcharacterized binding partners for nuclear actin. Therefore, the aim of this thesis was to identify and characterize novel nuclear actin-binding partners and elucidate the molecular mechanisms behind actin regulated transcription factors. To identify nuclear actin-binding partners, we used two complementary mass spectrometry (MS) techniques, affinity purification combined with MS (AP-MS) and proximity dependent biotin identification with MS (BioID). AP-MS protocol was optimized to preserve complete nuclear complexes and BioID was geared towards identifying more transient interactions. We utilized different actin constructs to discriminate nuclear versus cytoplasmic interactions and to assess the requirement for actin polymerization for the putative nuclear interactions. Analysis of our interactome data revealed that actin can form stable complexes with proteins related to chromatin remodeling but seems to function in a dynamic fashion in other nuclear processes, such as transcription and DNA replication. In our experimental setup actin seemed to be monomeric when it associated with nuclear complexes. We also discovered a novel actin-containing complex, human Ada-Two-A-containing complex (hATAC). HATAC is a histone modifying complex and further studies showed that actin directly binds one of it subunits, lysine acetyltransferase 14 (KAT14). We showed that actin-binding modulates histone acetyl transferase (HAT) activity of KAT14 in vitro and in cells. We obtained numerous RNA splicing and mRNA processing factors with our BioID approach, which led us to investigate the role of actin in RNA splicing. Bimolecular fluorescent complementation (BiFC) assays demonstrated that actin associates with different splicing factors and we further showed, for the first time, that actin has a functional role in mRNA splicing, as alterations in nuclear actin levels disturbed survival motor neuron protein 2 (SMN2) alternative exon skipping. In addition, the nuclear actin interactome analysis provided new insights into nuclear processes already earlier linked to actin, such as chromatin remodeling, transcription and DNA replication, and hence this work provides a protein interaction platform for further mechanistic studies of nuclear actin-dependent functions. This thesis work has thereby broadened the knowledge of nuclear actin-binding partners as well as revealed novel regulatory properties of actin-regulated RPEL domain containing proteins.
Actin and hnRNP U cooperate for productive transcription by RNA polymerase II
Nature Structural & Molecular Biology, 2005
To determine the role of actin-ribonucleoprotein complexes in transcription, we set out to identify novel actin-binding proteins associated with RNA polymerase II (Pol II). Using affinity chromatography on fractionated HeLa cells, we found that hnRNP U binds actin through a short amino acid sequence in its C-terminal domain. Post-transcriptional gene silencing of hnRNP U and nuclear microinjections of a short peptide encompassing the hnRNP U actin-binding sequence inhibited BrUTP incorporation in vivo. In living cells, we found that both actin and hnRNP U are associated with the phosphorylated C-terminal domain of Pol II, and antibodies to actin and hnRNP U blocked Pol II-mediated transcription. Taken together, our results indicate that a general actin-based mechanism is implicated in the transcription of most Pol II genes. Actin in complex with hnRNP U may carry out its regulatory role during the initial phases of transcription activation.
International Immunology, 2014
Mutations in the gene encoding the Wiskott–Aldrich syndrome protein (WASP) are responsible for Wiskott–Aldrich syndrome and WASP is a major actin regulator in the cytoplasm. Although rare gain-of-function mutations in the WASP gene are known to result in X-linked neutropenia (XLN), the molecular pathogenesis of XLN is not fully understood. In this study, we showed that all reported constitutively activating mutants (L270P, S272P and I294T) of WASP were hyperphosphorylated by Src family tyrosine kinases and demonstrated higher actin polymerization activities compared with wild-type (WT) WASP. Further analysis showed a tendency of activating WASP mutants to localize in the nucleus compared with WT or the Y291F mutant of WASP. In addition, we found that WASP could form a complex with nuclear RNA-binding protein, 54kDa (p54nrb) and RNA polymerase II (RNAP II). ChIP assays revealed that WASP associated with DNA, although the affinity was relatively weaker than RNAP II. To determine wheth...
Molecular and Cellular Biology, 2008
Actin is a key regulator of RNA polymerase (pol) II transcription. In complex with specific hnRNPs, it has been proposed that actin functions to recruit pol II coactivators during the elongation of nascent transcripts. Here, we show by affinity chromatography, protein-protein interaction assays, and biochemical fractionation of nuclear extracts that the histone acetyltransferase (HAT) PCAF associates with actin and hnRNP U. PCAF and the nuclear actin-associated HAT activity detected in the DNase I-bound protein fraction could be released by disruption of the actin-hnRNP U complex. In addition, actin, hnRNP U, and PCAF were found to be associated with the Ser2/5- and Ser2-phosphorylated pol II carboxy-terminal domain construct. Chromatin and RNA immunoprecipitation assays demonstrated that actin, hnRNP U, and PCAF are present at the promoters and coding regions of constitutively expressed pol II genes and that they are associated with ribonucleoprotein complexes. Finally, disruption ...
Genes & Development, 2005
In the dipteran Chironomus tentans, actin binds to hrp65, a nuclear protein associated with mRNP complexes. Disruption of the actin–hrp65 interaction in vivo by the competing peptide 65-2CTS reduces transcription drastically, which suggests that the actin–hrp65 interaction is required for transcription. We show that the inhibitory effect of the 65-2CTS peptide on transcription is counteracted by trichostatin A, a drug that inhibits histone deacetylation. We also show that actin and hrp65 are associated in vivo with p2D10, an evolutionarily conserved protein with histone acetyltransferase activity that acts on histone H3. p2D10 is recruited to class II genes in a transcription-dependent manner. We show, using the Balbiani ring genes of C. tentans as a model system, that p2D10 is cotranscriptionally associated with the growing pre-mRNA. We also show that experimental disruption of the actin–hrp65 interaction by the 65-2CTS peptide in vivo results in the release of p2D10 from the trans...