Studies of acetylation and deacetylation in high mobility group proteins. Identification of the sites of acetylation in HMG-1

Lysine acetylation and the bromodomain: a new partnership for signaling

Lysine acetylation has been shown to occur in many protein targets, including core histones, about 40 transcription factors and over 30 other proteins. This modification is reversible in vivo, with its specificity and level being largely controlled by signal-dependent association of substrates with acetyltransferases and deacetylases. Like other covalent modifications, lysine acetylation exerts its effects through "loss-of-function" and "gain-of-function" mechanisms. Among the latter, lysine acetylation generates specific docking sites for bromodomain proteins. For example, bromodomains of Gcn5, PCAF, TAF1 and CBP are able to recognize acetyllysine residues in histones, HIV Tat, p53, c-Myb or MyoD. In addition to the acetyllysine moiety, the flanking sequences also contribute to efficient recognition. The relationship between acetyllysine and bromodomains is reminiscent of the specific recognition of phosphorylated residues by phospho-specific binding modules such as SH2 domains and 14-3-3 proteins. Therefore, lysine acetylation forges a novel signaling partnership with bromodomains to govern the temporal and spatial regulation of protein functions in vivo.

Regulation of human SRY subcellular distribution by its acetylation/deacetylation

SRY, a Y chromosome-encoded DNA-binding protein, is required for testis organogenesis in mammals. Expression of the SRY gene in the genital ridge is followed by diverse early cell events leading to Sertoli cell determination/differentiation and subsequent sex cord formation. Little is known about SRY regulation and its mode of action during testis development, and direct gene targets for SRY are still lacking. In this study, we demonstrate that interaction of the human SRY with histone acetyltransferase p300 induces the acetylation of SRY both in vitro and in vivo at a single conserved lysine residue. We show that acetylation participates in the nuclear localisation of SRY by increasing SRY interaction with importin beta, while specific deacetylation by HDAC3 induces a cytoplasmic delocalisation of SRY. Finally, by analysing p300 and HDAC3 expression profiles during both human or mouse gonadal development, we suggest that acetylation and deacetylation of SRY may be important mechanisms for regulating SRY activity during mammalian sex determination.

In Vitro Acetylation of HMGB-1 and -2 Proteins by CBP: the Role of the Acidic Tail†

Histone acetyltransferases CBP, PCAF, and Tip60 have been tested for their ability to in vitro acetylate HMGB-1 and -2 proteins and their truncated forms lacking the C-terminal tail. It was found that these proteins were substrates for CBP only. Analyses of modified proteins by electrophoresis, amino acid sequencing, and mass spectrometry showed that full-length HMGB-1 and -2 were monoacetylated at Lys2. Removal of the C terminus resulted in (i) an increased incorporation of radiolabeled acetate within the proteins to a level close to that observed with histones H3/H4 and (ii) creation of a novel target site at Lys81. Acetylated and nonmodified HMGB-1 and -2 protein lacking the acidic tail were compared relative to their binding affinity to distorted DNA and the ability to bend linear DNA. Both proteins showed similar affinities to cisplatin-damaged DNA; the acetylated protein, however, was 3-fold more effective in inducing ligase-mediated circularization of a 111-bp DNA fragment. The alterations in the acetylation pattern of HMGB-1 and -2 upon removal of the C-terminal tail are regarded as a means by which the acidic domain modulates some properties of these proteins.

UV radiation-induced XPC translocation within chromatin is mediated by damaged-DNA binding protein, DDB2

The tumor suppressor p53 protein has been established as an important factor in modulating the efficiency of global genomic repair. Our recent repair studies in human cells reported that p53 regulates the recruitment of XPC and TFIIH proteins to specific DNA damage sites. Here, we have examined the influence of p53 and damaged-DNA binding complex (DDB2) proteins on the distribution of XPC within damaged chromatin in vivo and the recruitment of XPC to DNA damage sites in situ. The results show that UV irradiation causes the translocation of XPC from a loosely bound form into a tight association with chromatin in vivo. The UV radiation-induced redistribution of XPC was equally compromised in p53-deficient, as well as DDB2-deficient, human cells. Similarly, rapid recruitment of XPC to DNA damage in situ was also impaired in both cell lines. Ectopic expression of DDB2 in p53-deficient cells overcame the requirement of p53 function for UV-induced translocation of XPC in vivo. Restoration of DDB2 function also enhanced the recruitment of XPC to DNA damage sites in situ and increased the global repair of cyclobutane pyrimidine dimer from the genome. These results indicate that DDB2 is a key downstream factor of p53 for regulating the movement of XPC to DNA damage in irradiated cells.

Inhibition of histone deacetylase activity by butyrate

This article reviews the effects of the short-chain fatty acid butyrate on histone deacetylase (HDAC) activity. Sodium butyrate has multiple effects on cultured mammalian cells that include inhibition of proliferation, induction of differentiation and induction or repression of gene expression. The observation that butyrate treatment of cells results in histone hyperacetylation initiated a flurry of activity that led to the discovery that butyrate inhibits HDAC activity. Butyrate has been an essential agent for determining the role of histone acetylation in chromatin structure and function. Interestingly, inhibition of HDAC activity affects the expression of only 2% of mammalian genes. Promoters of butyrate-responsive genes have butyrate response elements, and the action of butyrate is often mediated through Sp1/Sp3 binding sites (e.g., p21(Waf1/Cip1)). We demonstrated that Sp1 and Sp3 recruit HDAC1 and HDAC2, with the latter being phosphorylated by protein kinase CK2. A model is proposed in which inhibition of Sp1/Sp3-associated HDAC activity leads to histone hyperacetylation and transcriptional activation of the p21(Waf1/Cip1) gene; p21(Waf1/Cip1) inhibits cyclin-dependent kinase 2 activity and thereby arrests cell cycling. Pending the cell background, the nonproliferating cells may enter differentiation or apoptotic pathways. The potential of butyrate and HDAC inhibitors in the prevention and treatment of cancer is presented.

HMGN dynamics and chromatin function

Recent studies indicate that most nuclear proteins, including histone H1 and HMG are highly mobile and their interaction with chromatin is transient. These findings suggest that the structure of chromatin is dynamic and the protein composition at any particular chromatin site is not fixed. Here we discuss how the dynamic behavior of the nucleosome binding HMGN proteins affects the structure and function of chromatin. The high intranuclear mobility of HMGN insures adequate supply of protein throughout the nucleus and serves to target these proteins to their binding sites. Transient interactions of the proteins with nucleosomes destabilize the higher order chromatin, enhance the access to nucleosomal DNA, and impart flexibility to the chromatin fiber. While roaming the nucleus, the HMGN proteins encounter binding partners and form metastable multiprotein complexes, which modulate their chromatin interactions. Studies with HMGN proteins underscore the important role of protein dynamics in chromatin function.

Acetylation and level of mitochondrial transcription factor A in several organs of young and old rats

To gain further information on the role of mitochondrial transcription factor A (TFAM) in mitochondrial biogenesis, we studied the post-translational modifications of the protein in 6- and 28-month-old rat liver. Mass spectrometry and immunoblot analysis revealed that TFAM was acetylated at a single lysine residue and that the level of acetylation did not change with age. The measurement of the content of TFAM and of mitochondrial DNA (mtDNA) in several organs (cerebellum, heart, kidney, and liver) of young and old rats showed an age-related increase of mtDNA and TFAM in all the organs analyzed, except in heart. These data are discussed in the light of the multiple roles of TFAM in mitochondrial biogenesis and of the age-related change of the mitochondrial transcription.

Isolation and characterization of modified species of a mutated (Cys125 -Ala) recombinant human interleukin-2

During purification of recombinant and mutated interleukin-2 (rhIL-2A125) by reversed-phase-high-performance liquid chromatography, more and less hydrophobic fractions named MHF and LHF, respectively are discarded due to the presence of some unidentified forms of rhIL-2Ala125. Using slow and linear gradients of acetonitrile, these fractions were further purified by RP-HPLC, analyzed by automatic Edman degradation, digested with trypsin and analyzed by electrospray ionization mass spectrometry. In all fractions, partial processing of the N-terminal Met residue was observed. In the LHF the Met104 was partially oxidized as sulfoxide. Combining the selective and reversible blocking of tryptic peptides and cation-exchange chromatography, two unexpected C-terminal peptides were selectively isolated. Automatic N-terminal sequencing showed that one of these corresponded to the C-terminal peptide of rhIL-2Ala125 linked to another 11 amino acids (AANDENYALAA) and the other corresponded to the C-terminal peptide of a truncated rhIL-2Ala125 without the C-terminal threonine residue and the extension of the 11 amino acids previously mentioned. MHF contained a mixture of four species of rhIL-2A125 monoacetylated at the N-terminus and at the epsilon-amino groups of internal Lys residues: 8, 32 and 48. Cys58 was found as free cysteine and also covalently linked to Mr 69 and 77 molecules. Covalent dimers of rhIL-2A125 linked through disulfide bridges between Cys58 and Cys105 of different monomers were also found.

Dynamics of reporter gene stimulation by HMG box proteins

Overcoming local DNA rigidity is required to perform three-dimensional DNA-protein configuration at promoter regions. The abundant architectural nonhistone chromosomal HMG box proteins are nonsequence-specific; however, they have been established to specifically recognize distorted DNA. Using transient transfection to overexpress two different members of the HMGB-1/2 family of DNA architectural factors, we demonstrate that these proteins provide a general enhancement in reporter gene expression irrespective of the promoter being considered. Evidences are also provided indicating that stimulation may not be achieved by recruitment of the proteins by regulatory factors or as a consequence of major chromatin unfolding as previously suggested. Interestingly, the influence of the HMG box proteins under study was overridden when the promoters were either induced or stimulated by Trichostatin A (TSA) but recovered upon extended induction period. These results also support the concept that the architectural role of these proteins can contribute to the preinitiation complex assembly required for basal transcription, but to a much lesser extent to the poised promoter scaffolding characteristic of activated transcription.

Dual roles for HMGB1: DNA binding and cytokine

Effective therapies against overwhelming Gram-negative bacteremia, or sepsis, have eluded successful development. The discovery that tumor necrosis factor (TNF), a host-derived inflammatory mediator, was both necessary and sufficient to recapitulate Gram-negative sepsis raised cautious optimism for developing a targeted therapeutic. However, the rapid kinetics of the TNF response to infection defined an extremely narrow window of opportunity during which anti-TNF therapeutics could be successfully administered. HMGB1 was previously studied as a DNA-binding protein involved in DNA replication, repair, and transcription; and as a membrane-associated protein that mediates neurite outgrowth. A decade-long search has culminated in our identification of HMGB1 as a late mediator of endotoxemia. HMGB1 is released by macrophages upon exposure to endotoxin, activates many other pro-inflammatory mediators, and is lethal to otherwise healthy animals. Elevated levels of HMGB1 are observed in the serum of patients with sepsis, and the highest levels were found in those patients that died. The delayed kinetics of HMGB1 release indicate that it may be useful to target this toxic cytokine in the development of future therapies.

In vivo acetylation of HMG1 protein enhances its binding affinity to distorted DNA structures

The postsynthetic acetylation of HMG1 protein has been known for more than 20 years, but the effect of this modification on the properties of the protein has not been studied so far. Acetylated HMG1 was isolated from cells grown in the presence of sodium n-butyrate and identified as a monoacetylated protein, modified at lysine 2. Acetylated and parental forms of HMG1 were compared relative to their binding affinity to distorted DNA structures. By using mobility shift assay to determine the dissociation constants, we show that acetylation enhanced the ability of HMG1 to recognize UV light- or cisplatin-damaged DNA and four-way junctions. Since the modified lysine lies adjacent to the HMG1 DNA-binding domain, the results obtained were attributed to acetylation-induced conformational change in HMG1. The potential role of acetylation in modulating the interactions of HMG1 with both damaged DNA and other proteins is discussed.

Acetylation by histone acetyltransferase CREB-binding protein/p300 of STAT6 is required for transcriptional activation of the 15-lipoxygenase-1 gene

Interleukin-4 (IL-4) induces expression of reticulocyte-type 15-lipoxygenase-1 (15-LOX-1) in various mammalian cells via the Janus kinase/signal transducer and activator of transcription 6 (STAT6) signaling system. We studied the mechanism of 15-LOX-1 induction in A549 lung epithelial cells and found that genistein, a potent tyrosine kinase inhibitor, prevented phopsphorylation of STAT6, its binding to the 15-LOX-1 promoter, and the expression of catalytically active enzyme. In contrast, cycloheximide did not prevent 15-LOX-1 induction. Surprisingly, we found that IL-4 up-regulated the histone acetyltransferase activity of CREB-binding protein (CBP)/p300, which is responsible for acetylation of nuclear histones and STAT6. The acetylation of both proteins appears to be essential for the IL-4-induced signal transduction cascade, because inhibition of CBP/p300 by the viral wild-type E1A oncoprotein abrogated acetylation of both histones and STAT6 and strongly suppressed transcriptional activation of the 15-LOX-1 gene. Moreover, we found that the inhibition by sodium butyrate of histone deacetylases, which apparently suppress 15-LOX-1 gene transcription, synergistically enhanced the IL-4-stimulated 15-LOX-1 expression. These data suggest that both phosphorylation and acetylation of STAT6 as well as acetylation of nuclear histones are involved in transcriptional activation of the 15-LOX-1 gene, although these reactions follow differential kinetics. STAT6 phosphorylation proceeds within the first hour of IL-4 stimulation. In contrast, CBP/p300-mediated acetylation requires 9-11 h, and similar kinetics were observed for the expression of the active enzyme. Thus, our results suggest that in the absence of IL-4, nuclear histones may be bound to regulatory elements of the 15-LOX-1 gene, preventing its transcription. IL-4 stimulation causes rapid phosphorylation of STAT6, but its binding to the promoter appears to be prevented by nonacetylated histones. After 9-11 h, when histones become acetylated, STAT6 binding sites may be demasked so that the phosphorylated and acetylated transcription factor can bind to activate gene transcription.

The bovine herpesvirus 1 immediate-early protein (bICP0) associates with histone deacetylase 1 to activate transcription

Infected-cell protein 0 encoded by bovine herpesvirus 1 (BHV-1) (bICP0) is necessary for efficient productive infection, in large part, because it activates all 3 classes of BHV-1 genes (U. V. Wirth, C. Fraefel, B. Vogt, C. Vlcek, V. Paces, and M. Schwyzer, J. Virol. 66:2763-2772, 1992). Although bICP0 is believed to be a functional homologue of herpes simplex virus type 1-encoded ICP0, the only well-conserved domain between the proteins is a zinc ring finger located near the amino terminus of both proteins. Our previous studies demonstrated that bICP0 is toxic to transfected cells but does not appear to directly induce apoptosis (Inman, M., Y. Zhang, V. Geiser, and C. Jones, J. Gen. Virol. 82:483-492, 2001). C-terminal sequences in the last 320 amino acids of bICP0 mediate subcellular localization. Mutagenesis of the zinc ring finger within bICP0 revealed that this domain was important for transcriptional activation. In this study, we demonstrate that bICP0 interacts with histone deacetylase 1 (HDAC1), which results in activation of a simple promoter containing four consensus Myc-Max binding sites. The interaction between bICP0 and HDAC1 correlated with inhibition of Mad-dependent transcriptional repression. In resting CV-1 cells, bICP0 relieved HDAC1-mediated transcriptional repression. The zinc ring finger was required for relieving HDAC1-induced repression but not for interacting with HDAC1. In fetal bovine lung cells but not in a human epithelial cell line, bICP0 expression correlated with reduced steady-state levels of HDAC1 in crude cytoplasmic extracts. We hypothesize that the ability of bICP0 to overcome HDAC1-induced repression plays a role in promoting productive infection in highly differentiated cell types.

Mitotic phosphorylation prevents the binding of HMGN proteins to chromatin

Condensation of the chromatin fiber and transcriptional inhibition during mitosis is associated with the redistribution of many DNA- and chromatin-binding proteins, including members of the high-mobility-group N (HMGN) family. Here we study the mechanism governing the organization of HMGN proteins in mitosis. Using site-specific antibodies and quantitative gel analysis with proteins extracted from synchronized HeLa cells, we demonstrate that, during mitosis, the conserved serine residues in the nucleosomal binding domain (NBD) of this protein family are highly and specifically phosphorylated. Nucleosome mobility shift assays with both in vitro-phosphorylated proteins and with point mutants bearing negative charges in the NBD demonstrate that the negative charge abolishes the ability of the proteins to bind to nucleosomes. Fluorescence loss of photobleaching demonstrates that, in living cells, the negative charge in the NBD increases the intranuclear mobility of the protein and significantly decreases the relative time that it is bound to chromatin. Expression of wild-type and mutant proteins in HmgN1(-/-) cells indicates that the negatively charged protein is not bound to chromosomes. We conclude that during mitosis the NBD of HMGN proteins is highly phosphorylated and that this modification regulates the interaction of the proteins with chromatin.

Searching for the magic bullet against cancer: the butyrate saga

n-Butyric acid and its "polymorphic" derivatives have been largely but somehow "blindly" studied in oncology and in red cell diseases with consistent results through decades indicating a strong maturative effect determined by enhancement of gene transcription. Although these effects have been observed mainly in vitro, the relative absence of systemic toxicity of butyrates render these compounds appealing as specific therapeutic agents. More interestingly, their specific mechanism of action, i.e. inhibition of histone deacetylase and de-repression of transcription represents at present an unique tool for diseases such as acute leukemias which are characterised by a disregulation of co-repressors and co-activators of gene transcription. More insight into specificity and modalities of action of different butyrate derivatives may be a guarantee for excellent tailored antileukemic therapy in the future.

HMG1 and 2, and related 'architectural' DNA-binding proteins

The HMG-box proteins, one of the three classes of high mobility group (HMG) chromosomal proteins, bend DNA and bind preferentially to distorted DNA structures. The proteins appear to act primarily as architectural facilitators in the assembly of nucleoprotein complexes; for example, in effecting recombination and in the initiation of transcription. HMG-box proteins might be targeted to particular DNA sites in chromatin by either protein-protein interactions or recognition of specific DNA structures.

Signal transduction and the Ets family of transcription factors

Cellular responses to environmental stimuli are controlled by a series of signaling cascades that transduce extracellular signals from ligand-activated cell surface receptors to the nucleus. Although most pathways were initially thought to be linear, it has become apparent that there is a dynamic interplay between signaling pathways that result in the complex pattern of cell-type specific responses required for proliferation, differentiation and survival. One group of nuclear effectors of these signaling pathways are the Ets family of transcription factors, directing cytoplasmic signals to the control of gene expression. This family is defined by a highly conserved DNA binding domain that binds the core consensus sequence GGAA/T. Signaling pathways such as the MAP kinases, Erk1 and 2, p38 and JNK, the PI3 kinases and Ca2+-specific signals activated by growth factors or cellular stresses, converge on the Ets family of factors, controlling their activity, protein partnerships and specification of downstream target genes. Interestingly, Ets family members can act as both upstream and downstream effectors of signaling pathways. As downstream effectors their activities are directly controlled by specific phosphorylations, resulting in their ability to activate or repress specific target genes. As upstream effectors they are responsible for the spacial and temporal expression or numerous growth factor receptors. This review provides a brief survey of what is known to date about how this family of transcription factors is regulated by cellular signaling with a special focus on Ras responsive elements (RREs), the MAP kinases (Erks, p38 and JNK) and Ca2+-specific pathways and includes a description of the multiple roles of Ets family members in the lymphoid system. Finally, we will discuss other potential mechanisms and pathways involved in the regulation of this important family of transcription factors.

Acetylation of histones and transcription-related factors

The state of chromatin (the packaging of DNA in eukaryotes) has long been recognized to have major effects on levels of gene expression, and numerous chromatin-altering strategies-including ATP-dependent remodeling and histone modification-are employed in the cell to bring about transcriptional regulation. Of these, histone acetylation is one of the best characterized, as recent years have seen the identification and further study of many histone acetyltransferase (HAT) proteins and their associated complexes. Interestingly, most of these proteins were previously shown to have coactivator or other transcription-related functions. Confirmed and putative HAT proteins have been identified from various organisms from yeast to humans, and they include Gcn5-related N-acetyltransferase (GNAT) superfamily members Gcn5, PCAF, Elp3, Hpa2, and Hat1: MYST proteins Sas2, Sas3, Esa1, MOF, Tip60, MOZ, MORF, and HBO1; global coactivators p300 and CREB-binding protein; nuclear receptor coactivators SRC-1, ACTR, and TIF2; TATA-binding protein-associated factor TAF(II)250 and its homologs; and subunits of RNA polymerase III general factor TFIIIC. The acetylation and transcriptional functions of these HATs and the native complexes containing them (such as yeast SAGA, NuA4, and possibly analogous human complexes) are discussed. In addition, some of these HATs are also known to modify certain nonhistone transcription-related proteins, including high-mobility-group chromatin proteins, activators such as p53, coactivators, and general factors. Thus, we also detail these known factor acetyltransferase (FAT) substrates and the demonstrated or potential roles of their acetylation in transcriptional processes.

Acetylation of importin-alpha nuclear import factors by CBP/p300

Histone acetylases were originally identified because of their ability to acetylate histone substrates [1] [2] [3]. Acetylases can also target other proteins such as transcription factors [4] [5] [6] [7]. We asked whether the acetylase CREB-binding protein (CBP) could acetylate proteins not directly involved in transcription. A large panel of proteins, involved in a variety of cellular processes, were tested as substrates for recombinant CBP. This screen identified two proteins involved in nuclear import, Rch1 (human importin-alpha) and importin-alpha7, as targets for CBP. The acetylation site within Rch1 was mapped to a single residue, Lys22. By comparing the context of Lys22 with the sequences of other known substrates of CBP and the closely related acetylase p300, we identified G/SK (in the single-letter amino acid code) as a consensus acetylation motif. Mutagenesis of the glycine, as well as the lysine, severely impaired Rch1 acetylation, supporting the view that GK is part of a recognition motif for acetylation by CBP/p300. Using an antibody raised against an acetylated Rch1 peptide, we show that Rch1 was acetylated at Lys22 in vivo and that CBP or p300 could mediate this reaction. Lys22 lies within the binding site for a second nuclear import factor, importin-beta. Acetylation of Lys22 promoted interaction with importin-beta in vitro. Collectively, these results demonstrate that acetylation is not unique to proteins involved in transcription. Acetylation may regulate a variety of biological processes, including nuclear import.

Reexamination of the high mobility group-1 protein for self-association and characterization of hydrodynamic properties

Previous studies of the 25 kDa high mobility group-1 (HMG-1) protein have generated conflicting results regarding whether HMG-1 exists as a monomer or is capable of oligomerizing to (functional) tetramers. To resolve this question, sedimentation velocity analysis yielded a s20,w value of 2.59S, which is consistent with a monomeric protein. Equilibrium sedimentation data were obtained for three HMG-1 concentrations at two rotor speeds. The six sets of data were fit to both an ideal single component and monomer-dimer equilibrium model, with essentially identical fits produced for both models, with the latter indicating a low extent (7%) of dimerization. Reaction of HMG-1 with glutaraldehyde produced a small population of oligomers consistent with a low level of dimers. This supported the monomer-dimer equilibrium model. Surprisingly, gel permeation chromatography yielded an apparent molecular mass of approx. 55 kDa for both HMG-1 and HMG-2. This finding is considered anomalous and presumably due to the high negative charge density in the C terminus of HMG-1. The sedimentation data also permit one to model HMG-1 as a hydrated prolate ellipsoid with a major axis/minor axis ratio of 2. 79. The collective evidence from the sedimentation and chemical cross-linking studies strongly supports a moderately asymmetric monomer in solution and unequivocally eliminates the possibility of a highly extended shape for HMG-1 or the existence of any extensive oligomerization.

Specific acetylation of chromosomal protein HMG-17 by PCAF alters its interaction with nucleosomes

Nonhistone chromosomal proteins HMG-14 and HMG-17 are closely related nucleosomal binding proteins that unfold the higher-order chromatin structure, thereby enhancing the transcription and replication potential of chromatin. Here we report that PCAF, a transcription coactivator with intrinsic histone acetyltransferase activity, specifically acetylates HMG-17 but not HMG-14. Using mass spectrum sequence analysis, we identified the lysine at position 2 as the predominant site acetylated by PCAF. Lysine 2 is a prominent acetylation site in vivo, suggesting that this PCAF-mediated acetylation is physiologically relevant. Experiments with HMG-17 deletion mutants and competition studies with various protein fragments indicate that the specific acetylation of HMG-17 is not determined solely by the primary sequence near the acetylation site. By equilibrium dialysis we demonstrated that acetylation reduces the affinity of HMG-17 to nucleosome cores. In addition, we found that the binding of HMG-14 and HMG-17 to nucleosome cores inhibits the PCAF-mediated acetylation of histone H3. Thus, the presence of HMG-14 and HMG-17 affects the ability of PCAF to acetylate chromatin, while the acetylation of HMG-17 reduces its binding affinity to chromatin. Conceivably, in HMG-17-containing chromatin, acetylation of HMG-17 precedes the acetylation of histones.

Calf thymus high mobility group proteins are nonenzymatically glycated but not significantly glycosylated

Over the past decade, there have been many reports suggesting the presence of complex carbohydrates on nuclear and cytoplasmic proteins in mammalian cells. Some of the most often cited of these reports deal with the glycosylation of the high mobility group (HMG) proteins. These are relatively abundant chromosomal proteins that are known to be associated with nucleosomes and actively transcribed regions of chromatin. The original report describing HMG protein glycosylation presented several lines of evidence suggesting that these proteins are glycosylated, including carbohydrate compositional analysis and periodic-acid Schiff staining. We have attempted to repeat these observations with more highly purified protein than was utilized in the original study. Using carbohydrate compositional analysis performed by high pH anion exchange chromatography coupled to pulsed-amperometric detection, we saw no evidence for significant glycosylation of these proteins. In addition, we found no evidence for the presence of O-GlcNAc, a well known form of nuclear glycosylation. The HMG proteins did react with periodate, suggesting the presence of a modification containing cis-diols on the protein. Several tryptic peptides isolated from HMG 14 and 17 which retained the periodate reactivity had in common lysine residues, suggesting a potential modification of the straightepsilon-amino groups of lysines such as nonenzymatic glycation. Western blot analysis of the HMG proteins using anti-advanced glycation endproducts (AGE) antibodies confirmed the presence of glycation products on the HMG proteins.

Histone hyperacetylating agents stimulate promoter activity of human choline acetyltransferase gene in transfection experiment

Butyrate (5 mM), Trichostatin A (1 microM) or Trapoxin A (30 nM) increased choline acetyltransferase (ChAT) activity in cultured rat sympathetic neurons 3- to 8-fold in 2 days. On the contrary, the three drugs decreased ChAT activity in human CHP126 cells. Butyrate had little effect on ChAT mRNA level in these cells, suggesting post-transcriptional mechanisms for the decrease in ChAT activity. However, transient transfection experiments using CHP126 cells revealed that the M promoter, but not the R promoter, of human ChAT gene was activated 20- to 130-fold by the three hyperacetylating agents. A butyrate-responsive element was localized in the 1 kbp region upstream of exon M. Constructs containing in addition the genomic segment between exons M and 1 displayed maximal basal activity and inducibility by butyrate, suggesting the presence of butyrate-activated promoter/enhancer elements in this region. The stimulatory effects of butyrate and Trichostatin A were also observed in stably transfected CHP126 clones, suggesting that the chromatin environment was not preventing the induction of the endogenous ChAT gene by butyrate. Rather, the data suggest different chromatin organizations for the stable transgene and the endogenous ChAT gene.

The nuclear matrix and the regulation of chromatin organization and function

Nuclear DNA is organized into loop domains, with the base of the loop being bound to the nuclear matrix. Loops with transcriptionally active and/or potentially active genes have a DNase I-sensitive chromatin structure, while repressed chromatin loops have a condensed configuration that is essentially invisible to the transcription machinery. Core histone acetylation and torsional stress appear to be responsible for the generation and/or maintenance of the open potentially active chromatin loops. The transcriptionally active region of the loop makes several dynamic attachments with the nuclear matrix and is associated with core histones that are dynamically acetylated. Histone acetyltransferase and deacetylase, which catalyze this rapid acetylation and deacetylation, are bound to the nuclear matrix. Several transcription factors are components of the nuclear matrix. Histone acetyltransferase, deacetylase, and transcription factors may contribute to the dynamic attachment of the active chromatin domains with the nuclear matrix at sites of ongoing transcription.

High mobility group protein, HMG-1, contains insignificant glycosyl modification

High mobility group protein-1 (HMG-1) is a ubiquitous, highly conserved, and abundant nuclear protein. Recent findings suggest that HMG-1 may serve as a DNA chaperone protein and play a role in the regulation of transcription. There is a mounting interest in elucidating the mechanism by which HMG-1 protein takes part in these activities. HMG-1 has been reported to undergo an extensive array of posttranslational modifications, including glycosylation. We extend the earlier findings on the glycosylation of HMG-1 by quantitating the amount of carbohydrate on HMG-1 from calf thymus and chicken erythrocytes isolated by 2 different purification procedures. In addition, 2 different developmental stages (embryonic and adult) were examined in the chicken erythrocytes. The glycosyl composition was quantitated using the Dionex HPAE-PAD II system. Furthermore, the presence of O-linked GlcNAc on HMG-1 was determined by the enzymatic incorporation of 3H-galactose into HMG-1 protein. Contrary to earlier reports, less than 0.5 mol of total monosaccharides (Fuc, Man, GalNH2, GlcNH2, Gal) were detected per mole of HMG-1 protein, regardless of the source of the protein or the method of isolation. In addition, less than 0.002 mol of O-linked GlcNAc per mole of HMG-1 protein was detected. Thus, insignificant amount of glycosylation was found on HMG-1 protein. Because O-linked GlcNAc modification of proteins is believed to be a reversible posttranslational event, more definitive studies will need to be conducted before ruling out that the function of HMG-1 protein is not regulated by glycosylation.

Isolation of Escherichia coli synthesized recombinant eukaryotic proteins that contain epsilon-N-acetyllysine

Recombinant porcine (rpST) and bovine somatotropins (rbST) synthesized in Escherichia coli contain the amino acid, epsilon-N-acetyllysine. This amino acid was initially discovered in place of the normal lysine144 in a modified reversed-phase HPLC (RP-HPLC) species of rpST. Mass spectrometry and amino acid sequencing of a tryptic peptide isolated from this RP-HPLC purified protein were used to identify this altered residue as epsilon-N-acetyllysine. Ion-exchange chromatography was utilized to prepare low isoelectric point (pI) forms of rpST and rbST, which are enriched in epsilon-N-acetyllysine. Electrospray mass spectrometry demonstrated that the majority of the protein in these low pI fractions contained species 42 Da larger than normal. Immobilized pH gradient electrophoresis (IPG) of the ion-exchange purified low pI proteins was used to isolate several monoacetylated species of rpST and rbST. The location of the acetylated lysine in each IPG-purified protein was determined by tryptic peptide mapping and amino acid sequencing of the altered tryptic peptides. Amino acid analyses of enzymatic digests of rpST and rbST were also used to confirm the presence of epsilon-N-acetyllysine in these recombinant proteins. These data demonstrate that a significant portion of rpST and rbST produced in E. coli contain this unusual amino acid.

The specific interactions of HMG 1 and 2 with negatively supercoiled DNA are modulated by their acidic C-terminal domains and involve cysteine residues in their HMG 1/2 boxes

Sedimentation and gel retardation studies show a stronger interaction of HMG 1 and 2 with negatively supercoiled DNA than with linear, nicked-circular, or positively supercoiled ds-DNA. An apparent unwinding angle of 58 degrees was obtained for HMG 1 and 2 when assayed by protection of negatively supercoiled DNA from topoisomerase I relaxation or when assayed by the supercoiling of nicked-circular DNA with T4 DNA ligase. The protection of negatively supercoiled DNA was linear up to molar ratios of about 250:1. There was little change in binding reactions or in the protection of supercoiled DNA at ratios above 250:1, indicating that both activities saturate and that HMG 1 and 2 have binding site sizes of about 20 bp. P1, the major tryptic fragment of HMG 1 or 2 which retains the two DNA binding HMG 1/2 boxes, displays a 2-fold increase in binding to all types of ds-DNA compared to intact HMG 1 or 2. However P1 protects negatively supercoiled DNA from topoisomerase I relaxation about 5-fold less than intact HMG 1 or 2. Complete protection with P1 occurs at a molar ratio 1040:1, indicating a DNA binding site size of about 4 bp and an apparent unwinding angle of 10 degrees. P1 binding to closed-circular ss-DNA also involves a binding site of about 4 bp. Adding the acidic C-terminal fragment to P1 reversed its binding and allowed topoisomerase I to relax supercoiled DNA. These findings highlight the importance of the acidic C-terminal domains of HMG 1 and 2 in limiting electrostatic interactions of the HMG 1/2 boxes with ds- or ss-DNA. N-Ethylmaleimide inhibited the binding of intact HMG 1 or 2 to negatively supercoiled DNA, but did not inhibit the electrostatic binding of HMG 1 or 2 to ss-DNA, or of P1 to any form of DNA (ds or ss). These results suggest that cysteine residues are involved in the specific interaction of HMG 1 or 2 with negatively supercoiled DNA and that the acidic C-terminal domains modulate an intramolecular conformational change involving sulfhydryls within the HMG 1/2 boxes.

Tissue-specific pattern of nonhistone high mobility group proteins in various organs of the chicken

Electrophoretic analysis of tissue-specific differences of nonhistone high mobility group (HMG) proteins from nuclei of various organs of the chicken revealed that in organs with a higher proportion of replicating cells (thymus, Bursa Fabricii, spleen) the relative amount of HMG-17 is considerably higher than that of HMG-14; however, in transcriptionally active organs with a very small proportion of replicating cells (glandular stomach, liver) HMG-14 and HMG-17 are present at roughly equal and low amounts. In glandular stomach, liver and spleen, the relative contents of both HMG-1 and HMG-2 are markedly lower than in thymus and Bursa Fabricii. Moreover, the total amount of HMG proteins is higher in those organs which contain replicating lymphocytes.

High-mobility group and other nonhistone substrates for nuclear histone N-acetyltransferase

A variety of nonhistone proteins and polyamines has been studied for their substrate activity for nuclear histone N-acetyltransferase. Nonhistone chromatin high-mobility group (HMG) proteins are found to be as good a substrate for the enzyme as histones. The enzyme also acetylates spermidine and spermine. However, protamine, bovine serum albumin, and ubiquitin are not substrates. Chymotryptic peptides of histone and HMGs retained about 64% of the substrate activity, but trypsin treatment reduced the substrate activity by more than 85%. Both N-acetyltransferase activities for HMGs and histones are copurified through salt extraction, polyethylene glycol fractionation, and chromatography on DEAE-cellulose, phosphocellulose columns, and a HPLC anionic-exchange column. The highly purified nuclear histone acetyltransferase shows similar optimal pH and ping-pong kinetics for both HMGs and histones. The Km for HMG is 0.25 mg/ml. HMGs are able to accept the acetyl group from isolated acetyl-enzyme intermediate. Denatured gel analysis shows that HMG 1 and HMG 2 are the major proteins acetylated. High salt concentrations, mononucleotides, and DNA, which inhibit histone substrate activity of the enzyme, also inhibit HMG substrate activity. These observations suggest that there is a major nuclear N-acetyltransferase which is responsible for the acetylation of both histones and HMGs and perhaps also of spermine and spermidine. Thus the regulation of the structure and function of chromatin through postsynthetic acetylation can be achieved by a single nuclear N-acetyltransferase.

Antagonistic effect of the antiestrogen 4-hydroxytamoxifen on estradiol-stimulated acetylation of nuclear high mobility group (HMG) proteins in the uterus of newborn guinea-pigs

The effect of the antiestrogen 4-hydroxytamoxifen on the estradiol-stimulated acetylation of nuclear high mobility group (HMG) proteins was studied in the uterus of newborn (3-day-old) guinea-pig. 4-Hydroxytamoxifen (10(-6) M) selectively inhibits the stimulatory effect of estradiol (5 x 10(-8) M) on the acetylation of HMG-14 proteins 30 min after incubation with uterine tissue slices. No effect of 4-hydroxytamoxifen was observed on HMG-1 + HMG-2 or HMG-17 proteins. The data suggest that the blockage of HMG-14 acetylation is an early event in gene expression which is in relation to the antagonistic effect of the antiestrogen.

Estradiol enhanced acetylation of nuclear high mobility group proteins of the uterus of newborn guinea pigs

The effect of estradiol on the acetylation of nuclear high mobility group (HMG) proteins in the uterus of newborn (3 days old) guinea pigs was studied "in vivo" and in tissue slices. In the "in vivo" studies after subcutaneous injection of 5 mCi [3H]-acetate there is a rapid (20 min) uptake of radioactive acetate in the HMG-1, HMG-2, HMG-14 and HMG-17 high mobility group proteins. In parallel studies, after administration of the same quantity of [3H]-acetate plus 20 micrograms of estradiol (E2), a selective increase in the acetylation of HMG-14 protein is observed. The preferential acetylation of HMG-14 can also be demonstrated in uterine tissue slices 20 minutes after exposure to the hormone (5 x 10(-8)M). In conclusion, the present data suggest that the acetylation of HMG proteins, in particular HMG-14, and like that of nucleosomal "core" histones, is an early event in gene activation by estradiol.

Acetylated HMG1 protein interacts specifically with homologous DNA polymerase alpha in vitro

The acetylated, deacetylated and nonacetylated forms of HMG1 proteins from Guerin ascites tumour cells and calf thymus were separated and their in vitro interactions with homologous and heterologous DNA polymerases were studied. It has been found that only the acetylated form of HMG1 proteins forms a specific complex with homologous DNA polymerase alpha and stimulates its activity in vitro. The acetylation therefore is necessary for their possible function in DNA replication. This finding represents an evidence for a relationship between the acetylation of HMG1 proteins and their biological role.

Differences between HMG1 proteins isolated from normal and tumour cells

The properties of the non-histone chromosomal high-mobility-group 1 (HMG1) proteins from rat liver and Guerin ascites tumour cells (GAT cells) were compared and showed the following differences: (1) five spots were missing in the peptide map of HMG1 from GAT cells in comparison with that of HMG1 from rat liver; (2) HMG1 from GAT cells was about 5-times more poly(ADP)-ribosylated; (3) HMG1 from GAT cells which was found acetylated in vivo and incorporated [14C]acetate in vitro, whereas no incorporation of the label was detected in HMG1 from rat liver; (4) HMG1 from GAT cells exhibited pronounced ability to form oligomers at physiological ionic strength, while HMG1 from rat liver was predominantly in monomeric form. This property of HMG1 from GAT cells was lost upon deacetylation.

Chlamydomonas alpha-tubulin is posttranslationally modified by acetylation on the epsilon-amino group of a lysine

Previous work has shown that the principal alpha-tubulin within Chlamydomonas reinhardtii flagellar axonemes differs from the major alpha-tubulin in the cell body. These two variants of alpha-tubulin are related to one another since posttranslational modification of the cell body form converts it to the axonemal form. When flagella are induced to assemble in the absence of de novo protein synthesis, tritiated acetate can be used to posttranslationally label alpha-tubulin in vivo, and under these conditions, no other flagellar polypeptides exhibit detectable labeling [L'Hernault, S. W., & Rosenbaum, J. L. (1983) J. Cell Biol. 97, 258-263]. In the present report, this labeling method has been used to provide material for chemical analysis of the tritiated moiety that is posttranslationally added to flagellar alpha-tubulin. This radioactivity was volatile after acid hydrolysis, suggesting that the posttranslational modification is the addition of neither an amino acid nor carbohydrate. Treatment of posttranslationally 3H-labeled alpha-tubulin with hydrazine yields radioactive acetylhydrazine, indicating that the moiety involved in posttranslational modification is an acetyl group. Analysis of complete proteolytic digests by thin-layer chromatography has revealed that this acetyl group is located on the epsilon-amino group of a flagellar alpha-tubulin lysine residue.

Covalent modifications of chromosomal proteins during aging

Covalent modifications of proteins introduce negative or positive charges into the molecules and thereby cause alterations in the ionic interactions of protein-protein or DNA-protein complexes. Whereas modifications of histones largely affect the organization of chromatin, those of non-histone proteins are believed to be involved in the expression of genes. These modifications during aging have been reviewed here. The available data suggest that the extent of covalent modifications of histones and non-histone chromosomal (NHC) proteins change during aging and such modifications may have an important role in the differential expression of genes at different phases of life span of an organism.

High mobility group nonhistone chromosomal proteins of the developing sea urchin embryo

The high mobility group or HMG proteins are nonhistone chromosomal proteins that have been found in relatively high amounts in nuclei of many tissues. A number of studies have shown that some of these proteins are preferentially associated with actively transcribed regions of the genome and may play a role in maintaining these regions in an active state. In this study, we undertook an investigation of the high mobility group proteins from the sea urchin, Stronglyocentrotus purpuratus. Initially the putative sea urchin HMGs were extracted from isolated nuclei of hatching blastula-stage embryos with 5% perchloric acid (PCA). The major proteins in this extract were characterized according to their electrophoretic mobility, amino acid composition, and association with isolated deoxyribonucleoprotein particles. The results indicate there is only one "major" sea urchin HMG protein, termed P2 in this paper. An estimate of the amount of P2 in relation to the inner histones, however, was low compared to what has been found for other HMG proteins. Of the other major 5% PCA-extractable proteins, one was identified as the cleavage stage H1. Another protein apparently resulted from H3 contamination in the 5% PCA extract, and the fourth major protein did not have all the characteristics of an HMG. In particular, it was not found associated with nucleosomal particles. The HMG proteins from other developmental stages were then examined. Five percent PCA extracts of nuclei from unfertilized eggs, 2-cell, 16-cell, hatching blastula, gastrula, and pluteus stages were analyzed on SDS- and acetic acid-urea gels. This analysis indicated that P2 exists in two different forms differing slightly in charge. The less basic form was found in the egg, 2-cell and 16-cell extracts. At the hatching blastula stage, both forms were present and by pluteus stage, the more basic form predominated. It appears that P2 is undergoing a developmental change from a less to more basic form. The presence of P2 in the 5% PCA extract of egg nuclei is proof that P2 does not initially appear sometime during embryogenesis but is already in the egg nucleus prior to fertilization.

Isolation, characterization, and postsynthetic modifications of tetrahymena high mobility group proteins

We have isolated four major high mobility group (HMG) proteins designated A, B, C, and D, together with ubiquitin from the ciliate protozoan Tetrahymena. These four HMG proteins are integral structural components of macronuclear nucleosomes. The proteins exhibit solubility properties, chromatographic behavior on carboxymethylcellulose, electrophoretic mobilities on various gel systems, and amino acid compositions similar to those of their mammalian counterparts. HMG-A is the largest, most acidic protein of the group and is phosphorylated in vivo at specific serine residues. HMG-B is both phosphorylated at serine residues and ADP ribosylated. HMG-C is not phosphorylated but is ADP ribosylated. HMG-D, the smallest, most basic protein of the group possesses an unusually high content of serine and threonine residues, and it is highly phosphorylated at both serine and threonine positions in the polypeptide chain.

Conformation and domain structure of the non-histone chromosomal proteins, HMG 1 and 2. Isolation of two folded fragments from HMG 1 and 2

Proteins HMG 1 and 2 have been digested with trypsin and two major products, stable to further digestion between 8 min and 2 h, have been purified (peptides A and B). Peptide B from HMG 1 has been identified as residues 12-75 and peptide A as residues 94/96-169 by amino acid analyses and Edman degradations. Peptide B spontaneously folds with the formation of 51% helix and exhibits the majority of the perturbed NMR resonances characteristic of folded intact HMG 1. Peptide B is stably folded in the presence of 150 mM NaCl between pH 3 and 10, like intact HMG 1. Peptide A forms 30% alpha-helix and also exhibits tertiary folding but is denatured by pH 10. The 11 N-terminal residues removed by trypsin contain both sites of post-synthetic acetylation (residues 2 and 11), a situation very similar to that found with core histones. It is proposed that HMG 1 and 2 consist of four structural domains, viz: (a) residues 1-11, (b) residues 12 to approximately 75, (c) residues 94-169 and (d) the very acidic region beyond residue 169. The instability of peptide A may mean that it is not a truly independent domain. No structural similarities to histone H1 are therefore observed in HMG 1 and 2.

The extent of histone acetylation induced by butyrate and the turnover of acetyl groups depend on the nature of the cell line

Cells possessing widely different physiological and morphological features have been treated with substances known to stimulate the differentiation of erythroleukemia cells. Only short fatty acids are capable of causing a hyperacetylation of the core histones and of enhancing the level of an H1-like protein in Chinese hamster ovary cells. While the time courses of a butyrate-mediated acetylation are similar for all cells, the maximum histone acetyl contents are much higher for the transformed cell of a given type. A withdrawal of butyrate rapidly (within 45 min) gives rise to a 'hypoacetylated state' for fibroblasts and transformed fibroblast (epithelial) cells from which there is a slow recovery. Lymphoid cells, on the other hand, display a marked persistance of the highly acetylated forms of histone H4.