ß-actin contributes to open chromatin for activation of the adipogenic pioneer factor CEBPA during transcriptional reprograming.

Adipogenesis is regulated by a cascade of signals that drive transcriptional reprogramming in adipocytes. Here, we report that nuclear actin regulates the chromatin states that establish tissue- specific expression during adipogenesis. To study the role of ß-actin in adipocyte differentiation, we conducted RNA sequencing on wild-type and ß-actin knockout mouse embryonic fibroblasts (MEFs) after reprograming to adipocytes. We found that ß-actin depletion affects induction of several adipogenic genes during transcriptional reprograming. This impaired regulation of adipogenic genes is linked to reduced expression of the pioneer factor Cebpa and is rescued by reintroducing NLS-tagged ß-actin. ATAC-Seq in knockout MEFs revealed that actin-dependent reduction of Cebpa expression correlates with decreased chromatin accessibility and loss of chromatin association of the ATPase Brg1. This, in turn, impairs CEBPB's association with its Cebpa promoter-proximal binding site during adipogenesis. We propose a role for the nuclear ß-actin pool in maintaining open chromatin for transcriptional reprogramming during adipogenic differentiation.

SAF-A/hnRNP-U localization in interphase and metaphase.

SAF-A/hnRNP U is an abundant nuclear protein that interacts specifically with nuclear matrix attachment region DNA (MAR) and RNA as a component of hnRNPs. SAF-A/hnRNP U was also shown to specifically bind mouse major satellite DNA (satMa). Antibodies against SAF-A and GFP-fusion constructs were used in the current work in order to trace SAF-A localization. In accordance with its diverse nucleic acid binding specificity, SAF-A was found to be localized in three different domains: outside the chromosomes, on the surface of the chromosome arms (probably MARs), and in the centromere region where it apparently binds specifically to the satMa. GFP-fusion constructs with different SAF-A/hnRNP U domains confirms the functional significance of the protein's functional domains in interphase cells. In telophase cells, the anti-SAF-A antibody signal appeared as a kind of network covering unfolded chromosomes.

The glycogen synthase kinase (GSK) 3beta represses RNA polymerase I transcription.

Several oncogenic proteins and tumour suppressors target the RNA polymerase I and interfere with rRNA synthesis. Here, we show that the glycogen synthase kinase (GSK) 3beta, which phosphorylates the tumour suppressor PTEN (phosphatase and tensin homologue deleted on chromosome 10), is selectively enriched in nucleoli of RAS-transformed cells. Immunoprecipitation and chromatin immunoprecipitation assays performed on epithelial and endothelial cells transformed with oncogenic RAS show that GSK3beta and PTEN are part of the same complex and associate with promoter and coding region of the rDNA. An active GSK3beta mutant abolished nucleolar BrUTP incorporation and associated with the member of the selectivity factor 1 complex TAF(I)110. Finally, GSK3beta inhibition upregulated 45S, 18S and 28S rRNA synthesis in RAS-transformed epithelial cells as revealed by semiquantitative real-time PCR and promoted cellular proliferation. Our results underscore a repressive function for GSK3beta in rRNA biogenesis supporting its role as a tumour supressor.

The function of actin in gene transcription.

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 1beta 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 bound to the heterogeneous nuclear ribonucleoprotein hrp36 is associated with Balbiani ring mRNA from the gene to polysomes.

In the salivary glands of the dipteran Chironomus tentans, a specific messenger ribonucleoprotein (mRNP) particle, the Balbiani ring (BR) granule, can be visualized during its assembly on the gene and during its nucleocytoplasmic transport. We now show with immunoelectron microscopy that actin becomes associated with the BR particle concomitantly with transcription and is present in the particle in the nucleoplasm. DNase I affinity chromatography experiments with extracts from tissue culture cells indicate that both nuclear and cytoplasmic actin are bound to the heterogeneous RNP (hnRNP) protein hrp36, but not to the hnRNP proteins hrp23 and hrp45. The interaction is likely to be direct as purified actin binds to recombinant hrp36 in vitro. Furthermore, it is demonstrated by cross linking that nuclear as well as cytoplasmic actin are bound to hrp36 in vivo. It is known that hrp36 is added cotranscriptionally along the BR mRNA molecule and accompanies the RNA through the nuclear pores and into polysomes. We conclude that actin is likely to be bound to the BR transcript via hrp36 during the transfer of the mRNA from the gene all the way into polysomes.

Recovery of gel-separated proteins for in-solution digestion and mass spectrometry.

A protocol for mass spectrometry of gel-separated proteins resulting in significantly increased sequence coverage and in improved possibilities for detection and identification of posttranslational modifications was developed. In relation to the standard in-gel digestion procedure, the sequence coverage using a combination of matrix-assisted laser desorption/ionization and electrospray ionization mass spectrometry was on the average increased by 30%. The method involves electroblotting of the gel-separated proteins to a poly(vinylidene difluoride) membrane. The proteins are extracted from the membrane using a solution of 1% trifluoroacetic acid in 70% acetonitrile and lyophilized. After reconstitution of the protein extract in digestion buffer, proteolytic cleavage is carried out in-solution as opposed to the standard in-gel digestion procedure. This allows recovery of large and hydrophobic peptides for mass spectrometry and reduces the risk for entrapment of proteolytic peptides in the gel matrix. The method was applied to proteins in the 30-40-kDa range with highly different structural properties. The improved ability to localize and determine protein modifications is shown for N-terminal acetylation and methylation of a histidine residue. Furthermore, the method enables fast screening of homologous protein sequences.

Nuclear localization signal recognition causes release of importin-alpha from aggregates in the cytosol.

Importin-alpha is a cytosolic receptor that recognizes classical Nuclear Localization Signals (NLSs) and mediates import into the nucleus. We have used a number of methods to investigate the aggregation state of Xenopus importin-alpha both as a recombinant, purified protein and in cytosolic extracts. We have found that recombinant importin-alpha aggregates at a protein concentration similar to that estimated to be present in the Xenopus cytoplasm, and that the importin-alpha aggregation is relieved by NLS peptide binding, with the importin-alpha then binding the NLS as a monomer. We have also found that in HeLa cytosolic extracts, importin-alpha is present in an aggregated form. Similarly to the purified importin-alpha aggregation, NLS peptides relieve the aggregation of importin-alpha in the cytosol. These observations indicate that aggregation of importin-alpha in the cytosol may be an intrinsic property of the import receptor and may be functionally related to NLS binding.Our results suggest a novel mechanism for NLS recognition, whereby NLSs mediate disassembly of importin-alpha aggregates in the cytosol.

Molecular interactions between the importin alpha/beta heterodimer and proteins involved in vertebrate nuclear protein import.

We have used in vitro binding assays to examine specific interactions between a number of cytoplasmic and nuclear pore proteins involved in nuclear protein import in vertebrates. We demonstrate that nuclear transport factor 2 (NTF2), nucleoporin p62 and the Ras-like GTPase Ran bind to the importin heterodimer via its beta subunit. The binding behaviour of p62 truncation mutants indicated that importin-beta interacts primarily with the alpha-helical coiled-coil rod domain of nucleoporin p62 and not with the N-terminal domain that contains a number of degenerate repeats based on the xFxFG sequence motif. The binding of Ran to importin-beta was sensitive to its nucleotide state, with RanGTP binding strongly, whereas RanGDP binding could not be detected using our assay conditions. RanGTP, but not RanGDP, was able to displace p62 bound to the importin alpha/beta complex, suggesting that the binding sites for p62 and RanGTP on importin-beta overlap. Moreover, RanGTP, but not RanGDP, weakened the interaction between importin-alpha and importin-beta in a concentration-dependent manner. NTF2 bound to the importin heterodimer but did not displace p62, suggesting that the NTF2 and p62 binding sites on importin-beta do not overlap. The set of interactions we observed was not altered by the binding of NLS-containing substrates such as transcription factor IIIA to the importin heterodimer. Our results are consistent with models for nuclear protein import in which Ran nucleotide exchange modulates the binding of the importin-substrate complexes during translocation through nuclear pore complexes.

Single-chain repressors containing engineered DNA-binding domains of the phage 434 repressor recognize symmetric or asymmetric DNA operators.

Single-chain (sc) DNA-binding proteins containing covalently dimerized N-terminal domains of the bacteriophage 434 repressor cI have been constructed. The DNA-binding domains (amino acid residues 1 to 69) were connected in a head-to-tail arrangement with a part of the natural linker sequence that connects the N and C-terminal domains of the intact repressor. Compared to the isolated N-terminal DNA-binding domain, the sc molecule showed at least 100-fold higher binding affinity in vitro and a slightly stronger repression in vivo. The recognition of the symmetric O(R)1 operator sequence by this sc homodimer was indistinguishable from that of the naturally dimerized repressor in terms of binding affinity, DNase I protection pattern and in vivo repressor function. Using the new, sc framework, mutant proteins with altered DNA-binding specificity have also been constructed. Substitution of the DNA-contacting amino acid residues of the recognition helix in one of the domains with the corresponding residues of the Salmonella phage P22 repressor c2 resulted in a sc heterodimer of altered specificity. This new heterodimeric molecule recognized an asymmetric, artificial 434-P22 chimeric operator with high affinity. Similar substitutions in both 434 domains have led to a new sc homodimer which showed high affinity binding to a natural, symmetric P22 operator. These findings, supported by both in vitro and in vivo experiments, show that the sc architecture allows for the introduction of independent changes in the binding domains and suggest that this new protein framework could be used to generate new specificities in protein-DNA interaction.

Interactions between HIV Rev and nuclear import and export factors: the Rev nuclear localisation signal mediates specific binding to human importin-beta.

The human immunodeficiency virus type 1 (HIV-1) Rev protein binds to unspliced HIV-1 pre-mRNA and exports it from the nucleus. Rev itself can "shuttle" between the nucleus and cytoplasm. This bi-directional transport is mediated by two specific Rev sequences: a nuclear localisation signal (NLS), which overlaps the RNA-binding domain, and a distinct nuclear export signal (NES). In this study we characterised new monoclonal antibodies that bind different epitopes of Rev, including the import and export sequences. In RNA bandshift assays, we observed that formation of a multimeric complex between Rev and its target RNA completely masks the Rev NLS, whereas the NES remains readily accessible. We then tested for signal-mediated interactions between Rev and different nuclear transport receptors, using mutations in the Rev NES or NLS to control for specificity. Extensive biochemical analyses did not reveal any direct NES-dependent interaction between Rev (free or RNA-bound) and the previously proposed export co-factors, human RIP/Rab and eIF-5A. By contrast, similar tests showed that Rev binds directly via its arginine-rich NLS to the human nuclear import receptor, importin-beta. This interaction was highly specific and was abolished by mutation in the Rev NLS. Importin-beta did not bind to the RNA-bound form of Rev, providing a mechanism to ensure that Rev is imported only following release of its RNA cargo. Unlike many NLS-containing proteins that bind stably to an importin-alpha/beta heterodimer, the binding of Rev to importin-beta was actually blocked by importin-alpha receptor. Our findings suggest that Rev and importin-alpha bind (via an arginine-rich sequence) to a similar region on importin-beta. In addition, we show that the complex between Rev and importin-beta can be dissociated by the nuclear Ran GTPase, but only when Ran is in the GTP-bound form. The series of interactions we describe provide a novel pathway for the import of Rev across the nuclear pore complex, and a mechanism for its release into the nucleoplasm.

Rationally designed helix-turn-helix proteins and their conformational changes upon DNA binding.

Circular dichroism and electrophoretic mobility shift studies were performed to confirm that dimerized N-terminal domains of bacterial repressors containing helix-turn-helix motifs are capable of high-affinity and specific DNA recognition as opposed to the monomeric N-terminal domains. Specific, high-affinity DNA binding proteins were designed and produced in which two copies of the N-terminal 1-62 domain of the bacteriophage 434 repressor are connected either in a dyad-symmetric fashion, with a synthetic linker attached to the C-termini, or as direct sequence repeats. Both molecules bound to their presumptive cognate nearly as tightly as does the natural (full-length and non-covalently dimerized) 434 repressor, showing that covalent dimerization can be used to greatly enhance the binding activity of individual protein segments. Circular dichroism spectroscopy showed a pronounced increase in the alpha-helix content when these new proteins interacted with their cognate DNA and a similar, although 30% lower, increase was also seen upon their interaction with non-cognate DNA. These results imply that a gradual conformational change may occur when helix-turn-helix motifs bind to DNA, and that a scanning mechanism is just as plausible for this motif class as that which is proposed for the more flexible basic-leucine zipper and basic-helix-loop-helix motifs.

Structural characterization of synthetic model peptides of the DNA-binding cI434 repressor by electrospray ionization and fast atom bombardment mass spectrometry.

The structural characterization of two synthetic model peptides of the cI434 repressor is described. Unequivocal determination of the structure was achieved by means of electrospray ionization mass spectrometry of the intact peptides and by fast atom bombardment mass spectrometric identification of complementary peptide fragments obtained by tryptic and chymotrypic digestion and partial separation by reversed-phase high-performance liquid chromatography. The results show the potential of this approach for characterizing synthetic peptides of relatively high molecular weight.