Effect of biotin on phosphorylation,acetylation, methylation of rat liver histones

Biotin deficient rat liver histones showed decreased phosphorylation and methylation, and increased acetylation rates as compared to normal rat liver histones: these alterations may be related to the observed lower stability of the interactions between histones and DNA. The modifications of the metabolic process might be the consequence of an alteration of the synthesis of the enzymes involved in histone phosphorylation, acetylation and methylation mechanisms and are presumably related to a biotin effect upon the synthesis of RNA and proteins.     

组蛋白的生物素酰化修饰

组蛋白修饰对基因表达的表观遗传学调控起着重要作用。组蛋白生物素酰化修饰是近年来新发现的一种组蛋白修饰,具有重要的生物学功能。有证据表明组蛋白生物素酰化在细胞增殖、DNA修复、维持基因组稳定等方面发挥作用。组蛋白的生物素酰化修饰是由羧化全酶合成酶与组蛋白直接相互作用的结果。本文主要介绍了组蛋白生物素酰化发现的过程,并对近年来在组蛋白生物素酰化催化机制和组蛋白生物素酰化功能方面的研究进展进行了综述,最后对组蛋白生物素酰化研究领域存在的问题进行了探讨。     

Artifactual detection of biotin on histones by streptavidin

Biotinylation is a recent addition to the list of reported posttranslational modifications made to histones. Holocarboxylase synthetase (HCS) and biotinidase have been implicated as biotinylating enzymes. However, the details of the mechanism and the regulation of biotin transfer on and off histones remains unclear. Here we report that in a cell culture system low biotin availability reduces biotinylation of carboxylases, yet apparent biotinylation of histones is unaffected. This is despite biotin depletion having detrimental effects on cell viability and proliferation. Further analysis of the widely used method for detecting biotin on histones, streptavidin blotting, revealed that streptavidin interacts with histones independently of biotin binding. Preincubation of streptavidin with free biotin reduced binding to biotinylated carboxylases but did not block binding to histones. To investigate biotinylation of histones using an alternative detection method independent of streptavidin, incorporation of 14C biotin into biotinylated proteins was analyzed. Radiolabeled biotin was readily detectable on carboxylases but not on histones, implying very low levels of biotin in the nucleus attached to histone proteins (< 0.03% biotinylation). In conclusion, we would caution against the use of streptavidin for investigating histone biotinylation.     

Stimulating effect of histones on DNA synthesis in the regenerating rat liver]

Effect of exogenous histones, nuclear globulins and acid proteins on DNA synthesis is studied in regenerating liver of rats in which the synthesis of their own proteins and thus DNA replication are inhibited by cycloheximide. In these conditions histones from regenerating rat liver are found to stimulate 3H-thymidine incorporation into DNA of hepatectomyzed rat liver. Nuclear globulins and acid proteins from regenerating liver, and histones from intact liver produced no stimulating effect on DNA sythesis.     

Biotinidase: its role in biotinidase deficiency and biotin metabolism

Renewed interest in biotinidase, the enzyme responsible for recycling the vitamin biotin, initially came from the discovery of biotinidase deficiency in 1982. Since then, the elucidation of other activities of the enzyme, alternative splicing of the biotinidase gene and differential subcellular localization of the enzyme have prompted speculation and investigations of its other possible functions. The results of these studies have implicated biotinidase in aspects of biotin metabolism, specifically the biotinylation of various proteins, such as histones. Biotinidase may have an important regulatory role(s) in chromatin/DNA function.     

THE SYNTHESIS OF ACIDIC CHROMOSOMAL PROTEINS DURING THE CELL CYCLE OF HELA S-3 CELLS : I. The Accelerated Accumulation of Acidic Residual Nuclear Protein before the Initiation of DNA Replication

The synthesis and accumulation of acidic proteins in the tightly bound residual nuclear fraction goes on throughout the cell cycle of continuously dividing populations of HeLa S-3 cells; however, during late G₁ there is an increased rate of synthesis and accumulation of these proteins which precedes the onset of DNA synthesis. Unlike that of the histones, whose synthesis is tightly coupled to DNA replication, the synthesis of acidic residual nuclear proteins is insensitive to inhibitors of DNA synthesis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of acidic residual nuclear proteins shows different profiles during the G₁, S, and G₂ phases of the cell cycle. These results suggest that, in contrast to histones whose synthesis appears to be highly regulated, the acidic residual proteins may have a regulatory function in the control of cell proliferation in continuously dividing mammalian cells.     

Roles for nutrients in epigenetic events

The field of epigenetics is the study of modifications of DNA and DNA-binding proteins that alter the structure of chromatin without altering the nucleotide sequence of DNA; some of these modifications may be associated with heritable changes in gene function. Nutrients play essential roles in the following epigenetic events. First, folate participates in the generation of S-adenosylmethionine, which acts as a methyl donor in the methylation of cytosines in DNA; methylation of cytosines is associated with gene silencing. Second, covalent attachment of biotin to histones (DNA-binding proteins) plays a role in gene silencing and in the cellular response to DNA damage. Third, tryptophan and niacin are converted to nicotinamide adenine dinucleotide, which is a substrate for poly(ADP-ribosylation) of histones and other DNA-binding proteins; poly(ADP-ribosylation) of these proteins participates in DNA repair and apoptosis. Here we present a novel procedure to map nutrient-dependent epigenetic marks in the entire genomes of any given species: the combined use of chromatin immunoprecipitation assays and DNA microarrays. This procedure is also an excellent tool to map the enzymes that mediate modifications of DNA and DNA-binding proteins in chromatin. Given the tremendous opportunities offered by the combined use of chromatin immunoprecipitation assays and DNA microarrays, the nutrition community can expect seeing a surge of information related to roles for nutrients in epigenetic events.     

Molecular genetics of biotin metabolism: old vitamin, new science

Biotin is a water-soluble vitamin that participates as a cofactor in gluconeogenesis, fatty acid synthesis and branched chain amino acid catabolism. It functions as the carboxyl carrier for biotin-dependent carboxylases. Its covalent attachment to carboxylases is catalyzed by holocarboxylase synthetase. Our interest in biotin has been through the genetic disease, "biotin-responsive multiple carboxylase deficiency," caused by deficient activity of holocarboxylase synthetase. As part of these studies, we made the unexpected findings that the enzyme also targets to the nucleus and that it catalyzes the attachment of biotin to histones. We found that patients with holocarboxylase synthetase deficiency have a much reduced level of biotinylated histones, yet the importance of this process is unknown. The dual nature of biotin, as the carboxyl-carrier cofactor of carboxylases and as a ligand of unknown function attached to histones, is an enigma that suggests a much more involved role for biotin than anticipated. It may change our outlook on the optimal nutritional intake of biotin and its importance in biological processes such as development, cellular homeostasis and regulation.     

Synthesis of high mobility group proteins in regenerating rat liver.

Incorporation of [3H]lysine into the non-histone chromosomal proteins HMG1, HMG2, and HMG17 and into each of the five major classes of histones was measured in rat liver at various times after partial hepatectomy. Histone synthesis was closely coupled temporally to that of DNA, although a small amount of histone was shown to be produced before DNA replication began. In contrast, the incorporation curves for the high mobility group (HMG) proteins showed little correlation with that for DNA. At 4 h after partial hepatectomy, protein synthesis had virtually ceased. Thereafter, the rates of synthesis of the HMG proteins rose steadily so that by 12 h, well before the onset of DNA replication they had reached about two-thirds of the maximum rates attained during the first cell division cycle. Histones had only reached about one-sixth of their maximum rates at this time. The lack of coupling betweeen the synthesis of the HMG proteins and DNA was confirmed by experiments with inhibitors of DNA replication. Reduction of DNA synthesis to less than 10% of the uninhibited rate had little or no effect on incorporation into the HMG proteins, whereas, under similar conditions, the rate of synthesis of histones was reduced by more than 50%.     

An avidin-based assay for histone debiotinylase activity in human cell nuclei

The covalent binding of biotin to histones participates in heterochromatin formation, cell cycle progression and cellular response to DNA breaks. Biotinylation of histones appears to be a reversible process, but the identity of enzymes that remove biotin marks is largely unknown. Our long-term goal is to identify histone debiotinylases in human cells. Here we developed an avidin-based plate assay to quantify histone debiotinylase activities in nuclear extracts. This assay is an essential first step in purifying and identifying histone debiotinylases from human cells. Using this assay, we demonstrated that debiotinylation of histones depends on temperature and pH, consistent with enzyme catalysis. Experiments with purified histones, proteases and protease inhibitors provide evidence that removal of biotin marks from histones is mediated by debiotinylases rather than by proteases. Activities of histone debiotinylases varied among human tissues: colon=lung>placenta=liver>lymphoid cells. This assay proved useful in monitoring activities of putative histone debiotinylases during their partial purification from cells. Collectively, this assay is a useful tool for investigating histone debiotinylases in human tissues.     

Biosynthesis of specific histones during meiotic prophase of mouse spermatogenesis

A kinetics study has demonstrated histone synthesis occurring at two distinct phases during meiotic prophase of mouse spermatogenesis. These two periods have been delineated by quantifying the synthesis of DNA and basic nuclear proteins in spermatogenic cells at discrete intervals following the intratesticular injection of [3H] thymidine and [14C] arginine, respectively. One phase of histone synthesis occurs coincident with DNA synthesis in preleptotene spermatocytes. By contrast, a second phase of histone synthesis occurs during midprophase of meiosis, independent of semiconservative DNA synthesis. The [14C] arginine incorporated into the basic nuclear proteins of pachytene spermatocytes is conserved during spermiogenesis and then subsequently discarded within the residual bodies, which are formed during late spermiogenesis. Fluorographic analyses of isotopically labeled basic nuclear proteins in pachytene spermatocytes has shown that only the somatic complement of histones are synthesized during the preleptotene period, whereas the second phase involves the synthesis of proteins H1t, H2S, and "A". In addition, several nonhistone basic nuclear proteins are synthesized concomitant with the germ cell-specific histones. Thus, the data clearly demonstrate that pachytene spermatocytes actively synthesize a number of novel chromatin-associated polypeptides.     

Onset of grain filling is associated with a change in properties of linker histone variants in maize kernels

In maize kernel development, the onset of grain-filling represents a major developmental switch that correlates with a massive reprogramming of gene expression. We have isolated chromosomal linker histones from developing maize kernels before (11 days after pollination, dap) and after (16 dap) initiation of storage synthesis. Six linker histone gene products were identified by MALDI-TOF mass spectrometry. A marked shift of around 4 pH units was observed for the linker histone spot pattern after 2D-gel electrophoresis when comparing the proteins of 11 and 16 dap kernels. The shift from acidic to more basic protein forms suggests a reduction in the level of post-translational modifications of linker histones during kernel development. Analysis of their DNA-binding affinity revealed that the different linker histone gene products bind double-stranded DNA with similar affinity. Interestingly, the linker histones isolated from 16 dap kernels consistently displayed a lower affinity for DNA than the proteins isolated from 11 dap kernels. These findings suggest that the affinity for DNA of the linker histones may be regulated by post-translational modification and that the reduction in DNA affinity could be involved in a more open chromatin during storage synthesis.     

Fate of newly synthesized histones shortly after interruption of DNA replication

The synthesis and association of histones with chromatin were studied using MH-134SC cells in suspension culture. Cultures containing approximately equal numbers of cells were pulse-labeled with [3H]lysine at various times after the interruption of DNA synthesis with hydroxyurea. Each culture was mixed with a fixed volume of a culture generally labeled with [14C]lysine at the time of harvesting. Acid-soluble proteins extracted from different subcellular fractions of cells labeled under various conditions were compared by electrophoresis on polyacrylamide gels containing acetic acid and urea. All types of chromatin histones were labeled nearly equally as [14C]marker histones by a 15 min pulse under normal conditions, except that a considerable portion of pulse-labeled H4 was in highly acetylated forms. Addition of hydroxyurea at the start of the pulse markedly reduced the labeling of H3 and H4, but affected the labeling of the other histones only slightly. When DNA synthesis was inhibited before the start of the pulse, labeling of all histones decreased significantly. The addition of hydroxyurea was found to cause transient accumulation of newly synthesized proteins in the cytoplasmic soluble fraction; these were characterized as H3 and H4 from their metabolic properties and their electrophoretic mobilities on sodium dodecyl sulfate-polyacrylamide gels. The results suggest that association of newly synthesized H3 and H4 histones is closely coupled with ongoing DNA replication. The implications of the results for the mechanism of formation of new nucleosomes are discussed.     

Effect of X-radiation on DNA and histone synthesis in ataxia telangiectasia and normal lymphoblastoid cells

The possibility that the radiosensitivity of lymphoblastoid cell lines from patients with ataxia telangiectasia (A-T) is due to an aberrant content of histones has been examined. The histone pattern of lymphoblastoid cell lines derived from A-T patients was found to be indistinguishable from that obtained from normal individuals. X-ray irradiation led to a greater decrease in cell growth rate in the A-T cells than in the normal cells but was accompanied by a greater decrease of DNA synthesis rate in the normal cells. This difference in radiosensitivity was not reflected in differences in the content or rates of synthesis of histones or of major non-histone proteins in these cells. Reduction in the rate of DNA synthesis was not associated with the appearance of the lysine-rich histone variant H1. We conclude that the hypersensitivity to ionizing radiation in A-T cells is not due to fundamental differences in the composition or synthesis of the major chromosomal proteins.     

Synthesis of the acid-soluble proteins in early cleaving embryos of the sea urchin. Cyclic synthesis of histones.

Synthesis of the acid-soluble proteins in the early cleavage stage of the sea urichin, Hemicentrotus pulcherrimus, was investigated. As detected by the incorporation of lysine, the acid-soluble proteins were synthesized periodically even before the first cleavage, differing from the pattern of incorporation of tryptophan into the fraction. Cyclic synthesis occurred almost in parallel with DNA synthesis. However, the phase and periodicity of cyclic synthesis of the acid-soluble protein fraction were quite different from those found in the hot TCA-insoluble (acid-insoluble) protein fraction. The acid-soluble proteins were adsorbed on cation exchange resin, Amberlite CG-50, and gave an elution profile similar to that found for calf thymus histones. The migration pattern of these proteins on acrylamide gel also resembled that of histones.     

Structural alterations of acidic proteins by acid treatment of chromatin

Summary Recent studies into the properties and biological function of the acidic (non-histone) chromatin proteins have utilized inorganic or organic acids to first remove the histones prior to analysis of the acidic proteins. Examination of the effects of the acid treatment on the DNA and acidic proteins by immunochemistry, circular dichroism, and the ability of the DNA to serve as a template in thein vitro DNA-dependent RNA synthesis, has demonstrated a marked structural change (denaturation) in the proteins and DNA after the acid treatment. Other methods of removing histones, e.g., by high salt or salt and urea, are recommended for studies, especially for those of the biological functions, of the DNA and acidic proteins.     

Histone segregation on replicating chromatin

We have reinvestigated the mode of segregation of preexisting histones onto replicating chromosomes. Since our previous data have indicated that only histones H3 and H4 do not appear to move from their association with the DNA strand with which they are bound until the next round of replication, we have concentrated our attention on these two histones. The strategy we have employed involved density labeling of DNA and radiolabeling of the histones of interest. Subsequently, we followed the association of histones and DNA during further rounds of DNA replication. One can make predictions concerning the nature of the association between specific histones and particular DNA strands depending on the mode of deposition. The results have confirmed our previous findings that histones segregate randomly. The possibility that such a result is a consequence of turnover of radiolabel in non-histone proteins and subsequent reutilization for histone synthesis has been tested directly. This process appears to be occurring to only a very limited extent. The implications of these conclusions for chromatin structure and gene control are discussed.