High mobility group proteins cHMG1a, cHMG1b, and cHMGI are distinctly distributed in chromosomes and differentially expressed during ecdysone dependent cell differentiation

Formator: Predicting Lysine Formylation Sites Based on the Most Distant Undersampling and Safe-Level Synthetic Minority Oversampling

Lysine formylation is a reversible type of protein post-translational modification and has been found to be involved in a myriad of biological processes, including modulation of chromatin conformation and gene expression in histones and other nuclear proteins. Accurate identification of lysine formylation sites is essential for elucidating the underlying molecular mechanisms of formylation. Traditional experimental methods are time-consuming and expensive. As such, it is desirable and necessary to develop computational methods for accurate prediction of formylation sites. In this study, we propose a novel predictor, termed Formator, for identifying lysine formylation sites from sequences information. Formator is developed using the ensemble learning (EL) strategy based on four individual support vector machine classifiers via a voting system. Moreover, the most distant undersampling and Safe-Level-SMOTE oversampling techniques were integrated to deal with the data imbalance problem of the training dataset. Four effective feature extraction methods, namely bi-profile Bayes (BPB), k-nearest neighbor (KNN), amino acid physicochemical properties (AAindex), and composition and transition (CTD) were employed to encode the surrounding sequence features of potential formylation sites. Extensive empirical studies show that Formator achieved the accuracy of 87.24 and 74.96 percent on jackknife test and the independent test, respectively. Performance comparison results on the independent test indicate that Formator outperforms current existing prediction tool, LFPred, suggesting that it has a great potential to serve as a useful tool in identifying novel lysine formylation sites and facilitating hypothesis-driven experimental efforts.

Homocitrullination Is a Novel Histone H1 Epigenetic Mark Dependent on Aryl Hydrocarbon Receptor Recruitment of Carbamoyl Phosphate Synthase 1

The aryl hydrocarbon receptor (AhR), a regulator of xenobiotic toxicity, is a member of the eukaryotic Per-Arnt-Sim domain protein family of transcription factors. Recent evidence identified a novel AhR DNA recognition sequence called the nonconsensus xenobiotic response element (NC-XRE). AhR binding to the NC-XRE in response to activation by the canonical ligand 2,3,7,8-tetrachlorodibenzo-p-dioxin resulted in concomitant recruitment of carbamoyl phosphate synthase 1 (CPS1) to the NC-XRE. Studies presented here demonstrate that CPS1 is a bona fide nuclear protein involved in homocitrullination (hcit), including a key lysine residue on histone H1 (H1K34hcit). H1K34hcit represents a hitherto unknown epigenetic mark implicated in enhanced gene expression of the peptidylarginine deiminase 2 gene, itself a chromatin-modifying protein. Collectively, our data suggest that AhR activation promotes CPS1 recruitment to DNA enhancer sites in the genome, resulting in a specific enzyme-independent post-translational modification of the linker histone H1 protein (H1K34hcit), pivotal in altering local chromatin structure and transcriptional activation.

Localization and functional analysis of HmgB3p, a novel protein containing high-mobility-group-box domain from Tetrahymena thermophila

The high-mobility-group (HMG)-box domain represents a very versatile protein domain that mediates the DNA-binding of non-sequence-specific and sequence-specific proteins. HMG-box proteins are involved in various nuclear functions, including modulating chromatin structure and genomic stability. In this study, we identified the gene HMGB3 in Tetrahymena thermophila. The predicted HmgB3p contained a single HMG-box, an SK-rich-repeat domain and a neutral phosphorylated C-terminal. HMGB3 was expressed in the growth and starvation stages. Furthermore, HMGB3 showed a higher expression levels during the conjugation stage. HMGB3 knockout strains showed no obvious cytological defects, although initiation of HMGB3 knockout strain mating was delayed and maximum mating was decreased. HA-HmgB3p localized on the micronucleus (MIC) during the vegetative growth and starvation stages. Furthermore, HA-HmgB3p specially decorated the meiotic and mitotic functional MIC during the conjugation stage. Truncated HMGB3 lacking the HMG box domain disappeared from MICs and diffused in the cytoplasm. Overexpressed HmgB3p was abnormally maintained in newly developing macronuclei and affected the viability of progeny. Taken together, these results show that HmgB3p is a germline micronuclear-specific marker protein. It may bind to micronucleus-specific DNA sequences or structures and is likely to have some function specific to micronuclei of T. thermophila.

Nepsilon-formylation of lysine is a widespread post-translational modification of nuclear proteins occurring at residues involved in regulation of chromatin function

Post-translational modification of histones and other chromosomal proteins regulates chromatin conformation and gene activity. Methylation and acetylation of lysyl residues are among the most frequently described modifications in these proteins. Whereas these modifications have been studied in detail, very little is known about a recently discovered chemical modification, the N(epsilon)-lysine formylation, in histones and other nuclear proteins. Here we mapped, for the first time, the sites of lysine formylation in histones and several other nuclear proteins. We found that core and linker histones are formylated at multiple lysyl residues located both in the tails and globular domains of histones. In core histones, formylation was found at lysyl residues known to be involved in organization of nucleosomal particles that are frequently acetylated and methylated. In linker histones and high mobility group proteins, multiple formylation sites were mapped to residues with important role in DNA binding. N(epsilon)-lysine formylation in chromosomal proteins is relatively abundant, suggesting that it may interfere with epigenetic mechanisms governing chromatin function, which could lead to deregulation of the cell and disease.

High mobility group proteins of the plant HMGB family: dynamic chromatin modulators

In plants, the chromosomal high mobility group (HMG) proteins of the HMGB family typically contain a central HMG-box DNA-binding domain that is flanked by a basic N-terminal and an acidic C-terminal domain. The HMGB proteins are abundant and highly mobile proteins in the cell nucleus that influence chromatin structure and enhance the accessibility of binding sites to regulatory factors. Due to their remarkable DNA bending activity, HMGB proteins can increase the structural flexibility of DNA, promoting the assembly of nucleoprotein complexes that control DNA-dependent processes including transcription. Therefore, members of the HMGB family act as versatile modulators of chromatin function.

Mass spectrometric mapping of linker histone H1 variants reveals multiple acetylations, methylations, and phosphorylation as well as differences between cell culture and tissue

Posttranslational modifications of histones are involved in regulation of chromatin structure and gene activity. Whereas the modifications of the core histones H2A, H2B, H3, and H4 have been extensively studied, our knowledge of H1 modifications remained mainly limited to its phosphorylation. Here we analyzed the composition of histone H1 variants and their modifications in two human cell lines and nine mouse tissues. Use of a hybrid linear ion trap-orbitrap mass spectrometer facilitated assignment of modifications by high resolution and low ppm mass accuracy for both the precursor and product mass spectra. Across different tissues we identified a range of phosphorylation, acetylation, and methylation sites. We also mapped sites of ubiquitination and report identification of formylated lysine residues. Interestingly many of the mapped modifications are located within the globular domain of the histones at sites that are thought to be involved in binding to nucleosomal DNA. Investigation of mouse tissue in addition to cell lines uncovered a number of interesting differences. For example, whereas methylation sites are frequent in tissues, this type of modification was much less abundant in cultured cells and escaped detection. Our study significantly extends the known spectrum of linker histone variability.

Fibroblast growth factor-2(23) binds directly to the survival of motoneuron protein and is associated with small nuclear RNAs

The SMN (survival of motoneuron) protein is mutated in patients with the neurodegenerative disease spinal muscular atrophy. We have shown previously that a high-molecular-mass isoform of FGF (fibroblast growth factor) 2 (FGF-2(23)) is in a complex with SMN [Claus, Doring, Gringel, Muller-Ostermeyer, Fuhlrott, Kraft and Grothe (2003) J. Biol. Chem. 278, 479-485]. FGF-2 is a neurotrophic factor for motoneurons, and is known not only as a classical extracellular growth factor, but also as a nuclear protein. In the present study, we demonstrate that SMN binds to the arginine-rich N-terminus of FGF-2(23). In turn, FGF-2(23) interacts with amino acid residues 1-90 of the human SMN protein. This sequence displays nucleic-acid-binding capacity and overlaps partially with known binding sites for Gemin2/SIP1 (SMN-interacting protein 1) and p53. Finally, as a functional consequence of FGF-2(23) binding to SMN, FGF-2(23) is in a complex with the small nuclear RNAs U2 and U4. Since SMN functions as an assembly factor for snRNPs (small nuclear ribonucleoprotein particles), these results suggest binding of FGF-2(23) to snRNPs.

Interaction of maize chromatin-associated HMG proteins with mononucleosomes: role of core and linker histones

Two groups of plant chromatin-associated high mobility group (HMG) proteins, namely the HMGA family, typically containing four A/T-hook DNA-binding motifs, and the HMGB family, containing a single HMG-box DNA-binding domain, have been identified. We have examined the interaction of recombinant maize HMGA and five different HMGB proteins with mononucleosomes (containing approx. 165 bp of DNA) purified from micrococcal nuclease-digested maize chromatin. The HMGB proteins interacted with the nucleosomes independent of the presence of the linker histone H1, while the binding of HMGA in the presence of H1 differed from that observed in the absence of H1. HMGA and the HMGB proteins bound H1-containing nucleosome particles with similar affinity. The plant HMG proteins could also bind nucleosomes that were briefly treated with trypsin (removing the N-terminal domains of the core histones), suggesting that the histone N-termini are dispensable for HMG protein binding. In the presence of untreated nucleosomes and trypsinised nucleosomes, HMGB1 could be chemically crosslinked with a core histone, which indicates that the trypsin-resistant part of the histones within the nucleosome is the main interaction partner of HMGB1 rather than the histone N-termini. In conclusion, these results indicate that specific nucleosome binding of the plant HMGB proteins requires simultaneous DNA and histone contacts.

Consecutive steps of phosphorylation affect conformation and DNA binding of the chironomus high mobility group A protein

The high mobility group (HMG) proteins of the AT-hook family (HMGA) lie downstream in regulatory networks with protein kinase C, Cdc2 kinase, MAP kinase, and casein kinase 2 (CK2) as final effectors. In the cells of the midge Chironomus, almost all of the HMGA protein (cHMGA) is phosphorylated by CK2 at two adjacent sites. 40% of the protein population is additionally modified by MAP kinase. Using spectroscopic and protein footprinting techniques, we analyzed how individual and consecutive steps of phosphorylation change the conformation of an HMGA protein and affect its contacts with poly(dA-dT).poly(dA-dT) and a fragment of the interferon-beta promoter. We demonstrate that phosphorylation of cHMGA by CK2 alters its conformation and modulates its DNA binding properties such that a subsequent phosphorylation by Cdc2 kinase changes the organization of the protein-DNA complex. In contrast, consecutive phosphorylation by MAP kinase, which results in a dramatic change in cHMGA conformation, has no direct effect on the complex. Because the phosphorylation of the HMGA proteins attenuates binding affinity and reduces the extent of contacts between the DNA and protein, it is likely that this process mirrors the dynamics and diversity of regulatory processes in chromatin.

In vivo expression and localization of the fibroblast growth factor system in the intact and lesioned rat peripheral nerve and spinal ganglia

Basic fibroblast growth factor (FGF-2) is involved in several cellular processes of the nervous system during development, maintenance, and regeneration. In the central nervous system, FGF-2 has been shown to be expressed in neurons and glial cells, depending on the developmental stage and brain area. In the present study, a comprehensive analysis was performed of the cellular distribution of the transcripts of FGF-2 and of the FGF high-affinity receptors (R) 1-4 in intact and lesioned sciatic nerve and spinal ganglia. In the adult rat sciatic nerve FGF-2, FGFR1-3 were expressed at low levels as revealed by reverse transcriptase-polymerase chain reaction (RT-PCR). Sciatic nerve crush resulted in an increase of these transcript levels. FGFR4 expression was not detected in the intact and crushed nerve as revealed by RT-PCR and RNase protection assay. In situ hybridization using riboprobes for FGF-2, FGFR1-3 displayed staining in diverse cell types. Immunocytochemical staining of consecutive sections with cell markers for myelin, macrophages, and neurons revealed colocalization of the transcripts with Schwann cells and macrophages. In addition to FGF-2 and FGFR1, the transcripts of FGFR2-4 were expressed in neurons of spinal ganglia. Crush lesion of the sciatic nerve resulted in no alterations of the FGFR1-4 transcripts, whereas FGF-2 and FGFR3 mRNAs were up-regulated in spinal ganglia. The expression of FGFRs and FGF-2 in Schwann cells and macrophages at the lesion site of the sciatic nerve and in sensory neurons suggests that FGF-2 is involved in specific functions of these cells during regeneration.

Distinctive effects of rat fibroblast growth factor-2 isoforms on PC12 and Schwann cells

Fibroblast growth factor-2 (FGF-2) is an important modulator of cell growth and differentiation and stimulates cell survival of various cells including neurons. Rat FGF-2 occurs in three isoforms, a low molecular weight 18 kD and two high molecular weight forms (21, 23 kD), representing alternative translation products from a single mRNA. The 18 kD isoform shows mainly cytoplasmatic localization, whereas the 21/23 kD FGF-2 are localized in the nucleus. In addition, the FGF-2 isoforms are differentially regulated in the sensory ganglia and peripheral nerve following nerve injury and in the adrenal medulla during post-natal development and after hormonal stimuli. The distinct intracellular distribution and differential regulation of the different FGF-2 isoforms indicate that they have unique biological roles, however, little is known about the biological effects of the high molecular weight FGF-2 isoforms. Immortalized Schwann cells and PC12 cells, which stably overexpress the different FGF-2 isoforms, showed that the different endogenous-overexpressed FGF-2 isoforms lead to dramatic modifications in cell proliferation and survival, when tested in serum-free and serum-containing medium. In contrast, application of recombinant FGF-2 isoforms on normal PC12 and immortalized Schwann cells results in similar biological effects on the proliferation and survival of the cells. Furthermore, we investigated the potential regulatory effects of endogenous-overexpressed and exogenous-applied FGF-2 isoforms on the mRNA level of the FGF-2 receptors and, additionally, on the tyrosin hydroxylase mRNA expression in PC12 cells.

Alterations in titer and distribution of high mobility group proteins during embryonic development of Drosophila melanogaster

High mobility group proteins are thought to have an architectural function in chromatin. Here we describe changes in titers, extent of phosphorylation, and cellular distribution of the three abundant HMG proteins during embryonic development of Drosophila. The titers of the HMG proteins HMGD, HMGZ, and D1 are highest in ovaries and at the beginning of embryonic development. They decrease continuously until cellularization of the embryo. Relative to the histone H1 titer, the levels of HMGD and D1 remain almost constant during gastrulation and organogenesis, whereas the titer of HMGZ increases during late organogenesis. Up to gastrulation, the development is accompanied by dephosphorylation of D1. In contrast, HMGD and HMGZ appear to be constitutively phosphorylated. As the high extent of phosphorylation of D1 is also characteristic in ovaries, it is likely that the posttranslational modifications of this protein observed in early embryonic stages are of maternal origin. Using site specific antibodies against helices I and III of HMGD and HMGZ and against the AT-hook motif of D1, protein-specific staining patterns have been observed during embryonic development. Despite high levels of HMG proteins at the beginning of embryonic development, we were unable to detect any of these proteins in nuclei of stage 2 embryos. The accumulation of the HMG proteins correlates with the onset of transcription in stage 3. Our results argue against a proposal of a shared role of HMGD and histone H1 in Drosophila chromatin.

Architecture of high mobility group protein I-C.DNA complex and its perturbation upon phosphorylation by Cdc2 kinase

The high mobility group I-C (HMGI-C) protein is an abundant component of rapidly proliferating undifferentiated cells. High level expression of this protein is characteristic for early embryonic tissue and diverse tumors. HMGI-C can function as an architectural factor enhancing the activity of transcription factor NF-kappaB on the beta-interferon promoter. The protein has three minor groove DNA-binding domains (AT-hooks). Here, we describe the complex of HMGI-C with a fragment of the beta-interferon promoter. We show that the protein binds to NRDI and PRDII elements of the promoter with its first and second AT-hook, respectively. Phosphorylation by Cdc2 kinase leads to a partial derailing of the AT-hooks from the minor groove, affecting mainly the second binding domain. In contrast, binding to long AT stretches of DNA involves contacts with all three AT-hooks and is marginally sensitive to phosphorylation. Our data stress the importance of conformation of the DNA binding site and protein phosphorylation for its function.

HMG1 proteins from evolutionary distant organisms distort B-DNA conformation in similar way

The abundant high-mobility group proteins 1/2 (HMG1/2) represent a group of potent architectural elements of chromatin. They are able to induce strong bends and untwist DNA. Here, we compared the abilities of diverse HMG1 proteins to distort the B-DNA conformation of 30-base pair DNA fragment. The DNA bending was measured in solution by monitoring fluorescence resonance energy transfer between fluorescence probes attached to opposite ends of the DNA fragment. Various insect and plant proteins which differ in size, in composition of their HMG1-box domains (HMG1-BD), and in composition of the N- and the C-terminally flanking regions were analyzed in these experiments. Despite these structural differences the extent of the induced changes in DNA conformation upon binding to various proteins was similar, as the estimated bend angle was 150+/-20 degrees for all the tested proteins. Our results suggest that a set of highly conserved residues stabilizing the tertiary structure of the HMG1-BD mainly determines the extent of DNA bending in the complex. Even extended positively charged regions flanking the HMG1-BD are apparently not able to influence this conformational distortion of DNA.

Protein footprinting reveals specific binding modes of a high mobility group protein I to DNAs of different conformation

The high mobility group proteins I and Y (HMGI/Y) are abundant components of chromatin. They are thought to derepress chromatin, affect the assembly and activity of the transcriptional machinery, and associate with constitutive heterochromatin during mitosis. HMGI/Y protein molecules contain three potential DNA-binding motifs (AT-hooks), but the extent of contacts between DNA and the entire protein has not been determined. We have used a protein-footprinting procedure to map regions of the Chironomus HMGI protein molecule that are involved in contacts with DNA. We find that in the presence of double-stranded DNA all AT-hook motifs are protected against hydroxyl radical proteolysis. In contrast, only two motifs were protected in the presence of four-way junction DNA. Large regions that flank the AT-hook motifs were found to be strongly protected against proteolysis in complexes with interferon-beta promoter DNA, suggesting amino acid residues outside the AT-hooks considerably contribute to DNA binding.

Cdc2 and mitogen-activated protein kinases modulate DNA binding properties of the putative transcriptional regulator Chironomus high mobility group protein I

Cells of the dipteran insect Chironomus contain a high mobility group protein that is homologous to the mammalian high mobility group proteins I/Y (HMGI/Y). These proteins facilitate the assembly of higher order nucleoprotein complexes. In proliferating cells, >30% of Chironomus HMGI was found to be phosphorylated. The phosphorylation sites were mapped to Ser3, Ser22, and Ser72 and were found to be substrates for the kinases Cdc2 (and mitogen-activated protein (MAP)), MAP, and Ca2+/phospholipid-dependent protein kinase, respectively. In mitotically arrested cells, the extent of phosphorylation at Ser3 increased, whereas phosphorylation at Ser22 remained unchanged. In nondividing cells, phosphorylation at Ser3 and Ser22 was strongly reduced. The DNA binding affinity of Chironomus HMGI was not influenced by single phosphorylation at Ser3 or Ser22. In contrast, phosphorylation at both of these sites resulted in a 10-fold weakening of the binding activity and altered the mode of protein-DNA interaction. Since both human and murine HMGI/Y proteins, similarly to the insect HMGI protein, possess phosphorylation sites for Cdc2 and MAP kinases that intersperse the AT-hook DNA-binding motifs, our results may reflect a general mechanism that regulates the properties and function of this class of putative transcriptional regulators.

Conformational changes of DNA induced by binding of Chironomus high mobility group protein 1a (cHMG1a). Regions flanking an HMG1 box domain do not influence the bend angle of the DNA

High mobility group (HMG) proteins are thought to facilitate assembly of higher order chromatin structure through modulation of DNA conformation. In this work we investigate the bending of a 30-base pair DNA fragment induced by Chironomus HMG1 (cHMG1a), and HMGI (cHMGI) proteins. The DNA bending was measured in solution by monitoring the end-to-end distance between fluorescence probes attached to opposite ends of the DNA fragment. The distance was measured by fluorescence energy transfer using a novel europium chelate as a fluorescence donor. These measurements revealed that the end-to-end distance in the 30-base pair DNA was decreased from approximately 100 A in free DNA to approximately 50.5 A in cHMG1a. DNA complex. The most probable DNA bending angle consistent with these distance measurements is about 150 degrees. The deletion of the charged regulatory domains located close to the C terminus of the HMG1 box domain of cHMG1a protein had no effect on the induced bend angle. The ability to induce a large DNA bend distinguishes the cHMG1 from the cHMGI protein. Only small perturbation of the DNA conformation was observed upon binding of the cHMGI protein. A strong DNA bending activity of cHMG1a and its relative abundance in the cell suggests that this protein plays a very important role in modulation of chromatin structure.