Hormone-mediated dephosphorylation of specific histone H1 isoforms.

We have previously shown a connection between histone H1 phosphorylation and the transcriptional competence of the hormone inducible mouse mammary tumor virus (MMTV) promoter. Prolonged exposure of mouse cells to dexamethasone concurrently dephosphorylated histone H1 and rendered the MMTV promoter refractory to hormonal stimulation and, therefore, transcriptionally unresponsive. Using electrospray mass spectrometry, we demonstrate here that prolonged dexamethasone treatment differentially effects a subset of the six somatic H1 isoforms in mouse cells. H1 isoforms H1.0, H1.1, and H1.2 are non-responsive to hormone whereas prolonged dexamethasone treatment effectively dephosphorylated the H1.3, H1.4, and H1.5 isoforms. The protein kinase inhibitor staurosporine, shown to dephosphorylate histone H1 and down-regulate MMTV in cultured cells, appears only to completely dephosphorylate the H1.3 isoform. These results suggest that dephosphorylation of specific histone H1 isoforms may contribute to the previously observed decrease in transcriptional competence of the MMTV promoter through the modulation of chromatin structure. In a broader sense, this work advances the hypothesis that post-translational modifications of individual histone H1 isoforms directly influence the transcriptional activation/repression of specific genes.

Histone H1 phosphorylation by Cdk2 selectively modulates mouse mammary tumor virus transcription through chromatin remodeling.

Transcriptional activation of the mouse mammary tumor virus (MMTV) promoter by ligand-bound glucocorticoid receptor (GR) is transient. Previously, we demonstrated that prolonged hormone exposure results in displacement of the transcription factor nuclear factor 1 (NF1) and the basal transcription complex from the promoter, the dephosphorylation of histone H1, and the establishment of a repressive chromatin structure. We have explored the mechanistic link between histone H1 dephosphorylation and silencing of the MMTV promoter by describing the putative kinase responsible for H1 phosphorylation. Both in vitro kinase assays and in vivo protein expression studies suggest that in hormone-treated cells the ability of cdk2 to phosphorylate histone H1 is decreased and the cdk2 inhibitory p21 protein level is increased. To address the role of cdk2 and histone H1 dephosphorylation in the silencing of the MMTV promoter, we used potent cdk2 inhibitors, Roscovitine and CVT-313, to generate an MMTV promoter which is associated predominantly with the dephosphorylated form of histone H1. Both Roscovitine and CVT-313 block phosphorylation of histone H1 and, under these conditions, the GR is unable to remodel chromatin, recruit transcription factors to the promoter, or stimulate MMTV mRNA accumulation. These results suggest a model where cdk2-directed histone H1 phosphorylation is a necessary condition to permit GR-mediated chromatin remodeling and activation of the MMTV promoter in vivo.

Differential in vivo modifications of the HMGI(Y) nonhistone chromatin proteins modulate nucleosome and DNA interactions.

The HMGI(Y) family of "high mobility group" nonhistone proteins are architectural transcription factors whose overexpression is highly correlated with both cancerous transformation and increased malignancy and metastatic potential of tumors in vivo. Here we report on the types of posttranslational modifications found in vivo on the HMG-I and HMG-Y proteins isolated from two human breast epithelial cell lines, MCF-7 and MCF-7/PKC-alpha, that represent different stages of neoplastic progression. The MCF-7 cell line exhibits many characteristics of normal breast epithelial cells and does not form tumors when injected into nude mice, whereas the MCF-7/PKC-alpha cell line, a derivative of MCF-7 that expresses a transgene coding for the enzyme protein kinase C-alpha (PKC-alpha), is both malignant and highly metastatic. Using MALDI mass spectrometry, we show that the HMG-Y protein is more highly modified than the HMG-I protein in both the MCF-7 and the MCF-7/PKC-alpha cells. Significantly, the HMG-Y protein isolated from the highly metastatic MCF-7/PKC-alpha cells possesses a unique constellation of phosphorylations, methylations, and acetylations not found on the HMG-I protein isolated from either the MCF-7 or MCF-7/PKC-alpha cells. We further demonstrate that some of the same amino acid residues phosphorylated on recombinant HMGI(Y) proteins by purified PKC in vitro are also phosphorylated on the HMG-I(Y) proteins isolated from MCF-7/PKC-alpha cells, suggesting that PKC phosphorylates these proteins in vivo. Quantitative substrate binding analyses indicate that the biochemical modifications present on the HMG-I and HMG-Y proteins differentially influence the ability of these proteins to interact with both A.T-rich DNA substrates and nucleosome core particles in vitro, suggesting a similar modulation of such binding affinities in vivo. To our knowledge, this is the first demonstration of differences in the types of in vivo biochemical modifications found on the HMG-I and HMG-Y proteins in cells and also the first experimental evidence suggesting a possible linkage between such posttranslational modifications and the neoplastic potential of cells.

The HMG-I(Y) A.T-hook peptide motif confers DNA-binding specificity to a structured chimeric protein.

Chromosomal translocations involving genes coding for members of the HMG-I(Y) family of "high mobility group" non-histone chromatin proteins (HMG-I, HMG-Y, and HMG-IC) have been observed in numerous types of human tumors. Many of these gene rearrangements result in the creation of chimeric proteins in which the DNA-binding domains of the HMG-I(Y) proteins, the so-called A.T-hook motifs, have been fused to heterologous peptide sequences. Although little is known about either the structure or biophysical properties of these naturally occurring fusion proteins, the suggestion has been made that such chimeras have probably assumed an altered in vivo DNA-binding specificity due to the presence of the A.T-hook motifs. To investigate this possibility, we performed in vitro "domain-swap" experiments using a model protein fusion system in which a single A. T-hook peptide was exchanged for a corresponding length peptide in the well characterized "B-box" DNA-binding domain of the HMG-1 non-histone chromatin protein. Here we report that chimeric A. T-hook/B-box hybrids exhibit in vitro DNA-binding characteristics resembling those of wild type HMG-I(Y) protein, rather than the HMG-1 protein. These results strongly suggest that the chimeric fusion proteins produced in human tumors as a result of HMG-I(Y) gene chromosomal translocations also retain A.T-hook-imparted DNA-binding properties in vivo.