Chemical Studies of Histone Methylation

Histidine Nτ-methylation identified as a new posttranslational modification in histone H2A at His-82 and H3 at His-39

Histone posttranslational modifications play critical roles in a variety of eukaryotic cellular processes. In particular, methylation at lysine and arginine residues is an epigenetic mark that determines the chromatin state. In addition, histone "histidine" methylation was initially reported over 50 years ago; however, further studies in this area were not conducted, leaving a gap in our understanding. Here, we aimed to investigate the occurrence of histidine methylation in histone proteins using highly sensitive mass spectrometry. We found that acid hydrolysates of whole histone fraction from calf thymus contained Nτ-methylhistidine, but not Nπ-methylhistidine. Both core and linker histones carried a Nτ-methylhistidine modification, and methylation levels were relatively high in histone H3. Furthermore, through MALDI-TOF MS, we identified two histidine methylation sites at His-82 in the structured globular domain of histone H2A and His-39 in the N-terminal tail of histones H3. Importantly, these histidine methylation signals were also detected in histones purified from a human cell line HEK293T. Moreover, we revealed the overall methylation status of histone H3, suggesting that methylation is enriched primarily at lysine residues and to a lesser extent at arginine and histidine residues. Thus, our findings established histidine Nτ-methylation as a new histone modification, which may serve as a chemical flag that mediates the epigenetic mark of adjacent residues of the N-terminal tail and the conformational properties of the globular domain.

Diverse and dynamic forms of gene regulation by the S. cerevisiae histone methyltransferase Set1

Gene transcription is an essential and highly regulated process. In eukaryotic cells, the structural organization of nucleosomes with DNA wrapped around histone proteins impedes transcription. Chromatin remodelers, transcription factors, co-activators, and histone-modifying enzymes work together to make DNA accessible to RNA polymerase. Histone lysine methylation can positively or negatively regulate gene transcription. Methylation of histone 3 lysine 4 by SET-domain-containing proteins is evolutionarily conserved from yeast to humans. In higher eukaryotes, mutations in SET-domain proteins are associated with defects in the development and segmentation of embryos, skeletal and muscle development, and diseases, including several leukemias. Since histone methyltransferases are evolutionarily conserved, the mechanisms of gene regulation mediated by these enzymes are also conserved. Budding yeast Saccharomyces cerevisiae is an excellent model system to study the impact of histone 3 lysine 4 (H3K4) methylation on eukaryotic gene regulation. Unlike larger eukaryotes, yeast cells have only one enzyme that catalyzes H3K4 methylation, Set1. In this review, we summarize current knowledge about the impact of Set1-catalyzed H3K4 methylation on gene transcription in S. cerevisiae. We describe the COMPASS complex, factors that influence H3K4 methylation, and the roles of Set1 in gene silencing at telomeres and heterochromatin, as well as repression and activation at euchromatic loci. We also discuss proteins that "read" H3K4 methyl marks to regulate transcription and summarize alternate functions for Set1 beyond H3K4 methylation.

Drug discovery for epigenetics targets

Dysregulation of the epigenome is associated with the onset and progression of several diseases, including cancer, autoimmune, cardiovascular, and neurological disorders. Members from the three families of epigenetic proteins (readers, writers, and erasers) have been shown to be druggable using small-molecule inhibitors. Increasing knowledge of the role of epigenetics in disease and the reversibility of these modifications explain why pharmacological intervention is an attractive strategy for tackling epigenetic-based disease. In this review, we provide an overview of epigenetics drug targets, focus on approaches used for initial hit identification, and describe the subsequent role of structure-guided chemistry optimisation of initial hits to clinical candidates. We also highlight current challenges and future potential for epigenetics-based therapies.

The Structure, Activity, and Function of the SETD3 Protein Histidine Methyltransferase

SETD3 has been recently identified as a long sought, actin specific histidine methyltransferase that catalyzes the Nτ-methylation reaction of histidine 73 (H73) residue in human actin or its equivalent in other metazoans. Its homologs are widespread among multicellular eukaryotes and expressed in most mammalian tissues. SETD3 consists of a catalytic SET domain responsible for transferring the methyl group from S-adenosyl-L-methionine (AdoMet) to a protein substrate and a RuBisCO LSMT domain that recognizes and binds the methyl-accepting protein(s). The enzyme was initially identified as a methyltransferase that catalyzes the modification of histone H3 at K4 and K36 residues, but later studies revealed that the only bona fide substrate of SETD3 is H73, in the actin protein. The methylation of actin at H73 contributes to maintaining cytoskeleton integrity, which remains the only well characterized biological effect of SETD3. However, the discovery of numerous novel methyltransferase interactors suggests that SETD3 may regulate various biological processes, including cell cycle and apoptosis, carcinogenesis, response to hypoxic conditions, and enterovirus pathogenesis. This review summarizes the current advances in research on the SETD3 protein, its biological importance, and role in various diseases.

Enzymology and significance of protein histidine methylation

Cells synthesize proteins using 20 standard amino acids and expand their biochemical repertoire through intricate enzyme-mediated post-translational modifications (PTMs). PTMs can either be static and represent protein editing events or be dynamically regulated as a part of a cellular response to specific stimuli. Protein histidine methylation (Hme) was an elusive PTM for over 5 decades and has only recently attracted considerable attention through discoveries concerning its enzymology, extent, and function. Here, we review the status of the Hme field and discuss the implications of Hme in physiological and cellular processes. We also review the experimental toolbox for analysis of Hme and discuss the strengths and weaknesses of different experimental approaches. The findings discussed in this review demonstrate that Hme is widespread across cells and tissues and functionally regulates key cellular processes such as cytoskeletal dynamics and protein translation. Collectively, the findings discussed here showcase Hme as a regulator of key cellular functions and highlight the regulation of this modification as an emerging field of biological research.

Metabolic enzymes function as epigenetic modulators: A Trojan Horse for chromatin regulation and gene expression

Epigenetic modification is a fundamental biological process in living organisms, which has significant impact on health and behavior. Metabolism refers to a set of life-sustaining chemical reactions, including the uptake of nutrients, the subsequent conversion of nutrients into energy or building blocks for organism growth, and finally the clearance of redundant or toxic substances. It is well established that epigenetic modifications govern the metabolic profile of a cell by modulating the expression of metabolic enzymes. Strikingly, almost all the epigenetic modifications require substrates produced by cellular metabolism, and a large proportion of metabolic enzymes can transfer into nucleus to locally produce substrates for epigenetic modification, thereby providing an alternative link between metabolism, epigenetic modification and gene expression. Here, we summarize the recent literature pertinent to metabolic enzymes functioning as epigenetic modulators in the regulation of chromatin architecture and gene expression.

Protein Histidine Methylation

Protein histidine methylation is a rarely studied posttranslational modification in eukaryotes. Although the presence of N-methylhistidine was demonstrated in actin in the early 1960s, so far, only a limited number of proteins containing N-methylhistidine have been reported, including S100A9, myosin, skeletal muscle myosin light chain kinase (MLCK 2), and ribosomal protein Rpl3. Furthermore, the role of histidine methylation in the functioning of the protein and in cell physiology remains unclear due to a shortage of studies focusing on this topic. However, the molecular identification of the first two distinct histidine-specific protein methyltransferases has been established in yeast (Hpm1) and in metazoan species (actin-histidine N-methyltransferase), giving new insights into the phenomenon of protein methylation at histidine sites. As a result, we are now beginning to recognize protein histidine methylation as an important regulatory mechanism of protein functioning whose loss may have deleterious consequences in both cells and in organisms. In this review, we aim to summarize the recent advances in the understanding of the chemical, enzymological, and physiological aspects of protein histidine methylation.

Chromatin and Aging

Recent studies from a number of model organisms have indicated chromatin structure and its remodeling as a major contributory agent for aging. Few recent experiments also demonstrate that modulation in the chromatin modifying agents also affect the life span of an organism and even in some cases the change is inherited epigenetically to subsequent generations. Hence, in the present report we discuss the chromatin organization and its changes during aging.

Epigenetic regulatory mechanisms in stress-induced behavior

Stress response is considered to have adaptive value for organisms faced with stressful condition. Chronic stress however adversely affects the physiology and may lead to neuropsychiatric disorders. Repeated stressful events in animal models have been shown to cause long-lasting changes in neural circuitries at molecular, cellular, and physiological level, leading to disorders of mood as well as cognition. Molecular studies in recent years have implicated diverse epigenetic mechanisms, including histone modifications, DNA methylation, and noncoding RNAs, that underlie dysregulation of genes in the affected neural circuitries in chronic stress-induced pathophysiology. A review of the myriad epigenetic regulatory mechanisms associated with neural and behavioral responses in animal models of stress-induced neuropsychiatric disorders is presented here. The review also deals with clinical evidence of the epigenetic dysregulation of genes in psychiatric disorders where chronic stress appears to underlie the etiopathology.

The promise and failures of epigenetic therapies for cancer treatment

Genetic mutations and gross structural defects in the DNA sequence permanently alter genetic loci in ways that significantly disrupt gene function. In sharp contrast, genes modified by aberrant epigenetic modifications remain structurally intact and are subject to partial or complete reversal of modifications that restore the original (i.e. non-diseased) state. Such reversibility makes epigenetic modifications ideal targets for therapeutic intervention. The epigenome of cancer cells is extensively modified by specific hypermethylation of the promoters of tumor suppressor genes relative to the extensive hypomethylation of repetitive sequences, overall loss of acetylation, and loss of repressive marks at microsatellite/repeat regions. In this review, we discuss emerging therapies targeting specific epigenetic modifications or epigenetic modifying enzymes either alone or in combination with other treatment regimens. The limitations posed by cancer treatments elicit unintended epigenetic modifications that result in exacerbation of tumor progression are also discussed. Lastly, a brief discussion of the specificity restrictions posed by epigenetic therapies and ways to address such limitations is presented.

One, two, three: how histone methylation is read

Methylation of histone lysine and arginine residues constitutes a highly complex control system directing diverse functions of the genome. Owing to their immense signaling potential with distinct sites of methylation and defined methylation states of mono-, di- or trimethylation as well as their higher biochemical stability compared with other histone modifications, these marks are thought to be part of epigenetic regulatory networks. Biological principles of how histone methylation is read and translated have emerged over the last few years. Only very few methyl marks directly impact chromatin. Conversely, a large number of histone methylation binding proteins has been identified. These contain specialized modules that are recruited to chromatin in a methylation site- and state-specific manner. Besides the molecular mechanisms of interaction, patterns of regulation of the binding proteins are becoming evident.

Histone methylation: a dynamic mark in health, disease and inheritance

Organisms require an appropriate balance of stability and reversibility in gene expression programmes to maintain cell identity or to enable responses to stimuli; epigenetic regulation is integral to this dynamic control. Post-translational modification of histones by methylation is an important and widespread type of chromatin modification that is known to influence biological processes in the context of development and cellular responses. To evaluate how histone methylation contributes to stable or reversible control, we provide a broad overview of how histone methylation is regulated and leads to biological outcomes. The importance of appropriately maintaining or reprogramming histone methylation is illustrated by its links to disease and ageing and possibly to transmission of traits across generations.

Protein metabolism of rats treated with trienbolone acetate

(1) Both the anabolic agent trienbolone acetate (3-oxo-17-β-hydroxy- 4,9,11-estratriene acetate) and testosterone subcutaneously injected into entire female rats caused an increase in growth rate compared with placebo controls (P<0·01 and P<0·001 respectively). The trienbolone acetate rats grew slower than the testosterone-treated animals (P < 0·01). This may reflect differences in the mode of action of the steroids.

(2) In castrate males there were no significant differences in growth rate between the trienbolone acetate, testosterone or placebo control rats (P>0·05).

(3) Trienbolone acetate reduced the rate of myofibrillar protein degradation in female rats, within 3 days of treatment, at least as judged by Nt-methylhistidine excretion. The treated rats had superior nitrogen retentions (P<0·01) and feed conversions (P< 0·001).

(4) The data suggest that the rat is a suitable model on which to test the mode of action of trienbolone acetate.

Chromatin modifications by methylation and ubiquitination: implications in the regulation of gene expression

It is more evident now than ever that nucleosomes can transmit epigenetic information from one cell generation to the next. It has been demonstrated during the past decade that the posttranslational modifications of histone proteins within the chromosome impact chromatin structure, gene transcription, and epigenetic information. Multiple modifications decorate each histone tail within the nucleosome, including some amino acids that can be modified in several different ways. Covalent modifications of histone tails known thus far include acetylation, phosphorylation, sumoylation, ubiquitination, and methylation. A large body of experimental evidence compiled during the past several years has demonstrated the impact of histone acetylation on transcriptional control. Although histone modification by methylation and ubiquitination was discovered long ago, it was only recently that functional roles for these modifications in transcriptional regulation began to surface. Highlighted in this review are the recent biochemical, molecular, cellular, and physiological functions of histone methylation and ubiquitination involved in the regulation of gene expression as determined by a combination of enzymological, structural, and genetic methodologies.

N-formylation of lysine in histone proteins as a secondary modification arising from oxidative DNA damage

The posttranslational modification of histone and other chromatin proteins has a well recognized but poorly defined role in the physiology of gene expression. With implications for interfering with these epigenetic mechanisms, we now report the existence of a relatively abundant secondary modification of chromatin proteins, the N(6)-formylation of lysine that appears to be uniquely associated with histone and other nuclear proteins. Using both radiolabeling and sensitive bioanalytical methods, we demonstrate that the formyl moiety of 3'-formylphosphate residues arising from 5'-oxidation of deoxyribose in DNA, caused by the enediyne neocarzinostatin, for example, acylate the N(6)-amino groups of lysine side chains. A liquid chromatography (LC)-tandem mass spectrometry (MS) method was developed to quantify the resulting N(6)-formyl-lysine residues, which were observed to be present in unperturbed cells and all sources of histone proteins to the extent of 0.04-0.1% of all lysines in acid-soluble chromatin proteins including histones. Cells treated with neocarzinostatin showed a clear dose-response relationship for the formation of N(6)-formyl-lysine, with this nucleosome linker-selective DNA-cleaving agent causing selective N(6)-formylation of the linker histone H1. The N(6)-formyl-lysine residue appears to represent an endogenous histone secondary modification, one that bears chemical similarity to lysine N(6)-acetylation recognized as an important determinant of gene expression in mammalian cells. The N(6)-formyl modification of lysine may interfere with the signaling functions of lysine acetylation and methylation and thus contribute to the pathophysiology of oxidative and nitrosative stress.

Megaloblastosis: from morphos to molecules

OBJECTIVE

Megaloblastosis (i.e., megaloblastic transformation of erythroid precursor cells in the bone marrow) is the cytomorphological hallmark of megaloblastic anemia resulting from vitamin B12 and folate deficiency. It is characterized by a finely stippled lacy pattern of nuclear chromatin, which is believed to be an expression of deranged cellular DNA synthesis. However, the molecular basis of these cytomorphological aberrations still remains obscure. The current presentation describes the results of our studies on some molecular events associated with the development of megaloblastosis.

METHODS

Transmission electron microscopy was used to study megaloblasts as well as DNA fibers extracted from megaloblastic and normoblastic bone marrows with and without treatment with proteinase K during the extraction procedure; cellular DNA synthesis in bone marrow cultures was studied by incorporation of 3H-thymidine and deoxyuridine suppression test, while histone biosynthesis in bone marrow cells was studied by in vitro incorporation of 3H-tryptophan, 3H-lysine and 3H-arginine into histones.

RESULTS

Derangement of DNA synthesis occurred due to an impaired de novo pathway of thymidylate synthesis in both vitamin-B12- and folate-deficient human megaloblastic bone marrows as well as in the bone marrows of rhesus monkeys and rats with experimentally induced folate deficiency. Interestingly, folate-deficient monkeys developed frank megaloblastic bone marrows, but folate-deficient rats did not. On the other hand, megaloblastic changes in the bone marrow of human patients with myelodysplastic syndrome and erythroleukemia were not associated with this DNA synthetic abnormality. Biosynthesis of predominantly arginine-rich histones in megaloblastic bone marrows was markedly reduced as compared to normoblastic bone marrows, which was consistently associated with elongation and despiralization of chromosomes and finely stippled nuclear chromatin in megaloblasts.

CONCLUSION

The impaired biosynthesis of predominantly arginine-rich nuclear histones appeared to be a common molecular event (a denominator) underlying the development of megaloblastosis with or without abnormal DNA synthesis.

Differential acetylation of core histones in rat cerebral cortex neurons during development and aging

Core histones can be modified by aceylation and this modification has been correlated with the modulation of chromatin condensation and histone deposition. We have now studied the levels of acetylation of the core histones in rat brain cortical neurons from the middle of the period of neuronal proliferation through postnatal development and aging. The results show that the level of acetylation of H4 decreases with age. The kinetics of H4 deacetylation show a perinatal fast phase followed by a much slower phase that spans the rest of the period examined. H4 deacetylation is accounted for by the decrease of the monoacetylated species, the proportions of the more highly acetylated species remaining essentially constant. By contrast to histone H4, the overall levels of acetylation and the proportions of the different acetylated species of H2A, H2B and H3 remain unchanged throughout the period examined. Furthermore, the variants belonging to a given histone class always show the same level of acetylation. The fact that in neurons the level of monoacetylated H4 decreases during development and aging, in sharp contrast with the constancy of the levels of all other acetylated histone species, raises the possibility that in interphase chromatin monoacetylated H4 may have a central role in the modulation of chromatin structure. The results also suggest that the slow decrease of the proportion of monoacetylated H4 may imply a gradual loss of chromatin structural plasticity and thus lead to aging.

Use of protein blotting to study the DNA-binding properties of histone H1 and H1 variants

Sub-types of histone H1 have been observed in a variety of tissues from several organisms. One of the best characterized H1 variants is H5 from avian erythrocytes. Several lines of evidence suggest that H5 has a greater affinity for DNA than H1 and is thus thought to account, in part, for the highly condensed and transcriptionally repressed state of avian erythrocyte chromatin. In trout there is an analogous erythrocyte-specific H1 variant, previously termed 'H5' [B.L.A. Miki and J.M. Neelin (1975) Can. J. Biochem. 53, 1158-1169). Using a sensitive and rapid protein-blotting procedure which is specific amongst the histones for histone H1 and its variants, we compared DNA-binding properties of the trout erythrocyte histone 'H5' and chicken H5. By increasing the NaCl concentration of the binding buffer, a gradual decrease in the amount of DNA that bound to chicken H1, trout H1 and trout erythrocyte 'H5' variant was observed, such that at concentrations above 0.37 M, negligible amounts of DNA were bound. By contrast, chicken H5 bound a significantly greater amount of DNA even at a concentration of 0.4 M NaCl. Based on the DNA-binding, properties, we conclude that the trout erythrocyte variant 'H5' is more closely related to H1 than to H5. By assaying the DNA-binding affinity of calf thymus H1 DNA-binding affinity of calf thymus H1 peptide fragments, generated by protease and chemical cleavage, and the sperm-specific H1 variants of the annelid, Platynereis dumerilii, which possess greatly shortened C-terminal tails, we conclude that a domain that includes a very small portion of the C-terminal tail and part of the globular domain is sufficient for the binding of H1 to DNA.

Specific targets of alkylating agents in nuclear proteins of cultured hepatocytes

We have established a specific correlation between the carcinogenic potency of a series of alkylating agents, with a mechanism of reaction ranging between Ingold's SN1-SN2 (ENU greater than MNU = MNNG greater than EMS greater than DMS = MMS) (Vogel et al., 1979; Bartsch et al., 1983) and specific target sites in the amino acids of nuclear proteins of cultured hepatocytes. More potent carcinogens, that react predominantly with an Ingold's SN1 mechanism, mainly alkylate the amino group of lysine and the guanido group of arginine. Weaker carcinogens, reacting with a mechanism closely resembling an Ingold's SN2, mainly alkylate the sulfhydryl group of the cysteine and the 3 position of the imidazolic ring of histidine. A compound with an intermediate type of reactivity alkylates, to a comparable extent, all 4 of the above-described positions. Although stable DNA damage brought about by alkylating carcinogens is considered to be the most likely cause of neoplastic transformation, epigenetic modifications may also play an important role in the process, especially because of their extreme stability. We have verified the existence of a linear correlation between the Swain-Scott substrate constant (S) of each compound and the amount of alkylation produced at the specific target sites. This type of correlation could be the basis of a 'short-term' genotoxicity assay in a battery of complementary tests.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Core histone variants and ubiquitinated histones 2A and 2B of rat cerebral cortex neurons

The pattern of non-allelic variants of core histones was investigated in terminally differentiated rat cerebral cortex neurons. At 30 days two major H2A variants are present, H2A.1 and .2, together with two minor components, .x and .z. H2B has two variants, H2B.1 and .2, and H3 presents three variants, H3.1, .2 and .3. The ubiquitinated adducts of all H2A and H2B variants can be recognised on two-dimensional electrophoresis as forming a pattern similar to that of the unmodified species. uH2A amounts to 12-14% of total H2A. All H2A variants appear to be equally modified. uH2B amounts to 1-2% of total H2B.

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.

The effect of elective surgery on 3-methylhistidine excretion

Elective surgical operation in normally nourished patients is associated with an increase of up to 40 per cent in the urinary excretion of 3-methylhistidine during the first three postoperative days. This increase was statistically significant (P less than 0.01) on the second and third postoperative days. This probably represents a minor degree of increased muscle proteolysis, principally due to the operative trauma. The possible effect of postoperative starvation requires further elucidation.

[Study On The Chromosomal Proteins Of Fasciola Hepatica]

In attempt to investigate histone fractions and non-histones of parasites, nuclei were isolated from Fasciola hepatica by the procedure of Pogo et al. (1966). Histone fractions H1, H2a, H2b, H3 and H4 were prepared from isolated nuclei by the procedure of Johns (1964 and l967). The five histone fractions found in most tissues were also present in the Fasciola hepatica histones. These histone fractions were characterized by amino acid analysis and by polyacrylamide disc gel electrophoresis. Non-histone proteins were extracted from isolated Fasciola hepatica nuclei and separated by SDS-polyacrylamide gel electrophoresis. The results of the experiment were summarized as follows: 1. The yield of whole histone recovered was 2.47 mg per 1 g of Fasciola hepatica. 2. The yield of DNA was 1.02 mg per gm of tissues. Consequently the DNA to histone ratio was 1:2.44. 3. The relative amounts of five fractions, i.e., Hl, H2a, H2b, H3 and H4 were 19.96%, 26.48%, 29.60%, 12.56% and 14.37%, respectively. 4. Amino acid analysis of the individual histone fractions showed that the over-all compositions were similar but not identical to those of corresponding fraction from calf thymus. 5. It was found that histone H2b fraction of Fasciola hepatica contained detectable amounts of epsilon-N-monomethyllysine. No evidence for the presence of methylated lysine or other side-chain derivatives was reported on this histone fraction. 6. In SDS-polyacrylamide disc gel, it showed that 17 protein bands of nuclear acidic protein can be identified visually.

Posttranslational covalent modification of proteins

A search for derivatized amino acids in proteins has shown that the extent of posttranslational modification of proteins is quite substantial. While only 20 primary amino acids are specified in the genetic code and are involved as monomer building blocks in the assembly of the polypeptide chain, about 140 amino acids and amino acid derivatives have been identified as constituents of different proteins in different organisms. A brief consideration of the questions about where and when the derivatization reactions occur, how the specificity of the reactions is established, and how the posttranslational modifications can facilitate biological processes, reveal a need for more information on all these points. Answers to these questions should represent significant contributions to our understanding of biochemistry and cell biology.

Overview: molecular changes associated with large bowel cancer and their potential as markers and chemotherapeutic agents

The search for molecular changes that may be diagnostic of malignancy in the colonic epithelium is complicated by the diversity of cell types and complex cell kinetics of a tissue in which most of the cells are destined to leave within hours or days. Methods for cell separation and nuclear fractionation now permit biochemical studies of those cells that retain or regain the capacity for DNA synthesis and that are likely to include the transformed cell population. Among the changes associated with malignant transformation to be described are alterations in nuclear protein composition and metabolism, qualitative and quantitative differences in adenosine deaminase activities, activation of the guanylate/cyclic GMP system, and modification of both DNA and chromosomal proteins by alkylating carcinogens. DNA modification to produce O6-methylguanine correlates well with the incidence of tumor induction by methylazoxymethanol. Modifications of chromosomal proteins to produce methylated derivatives of lysine and arginine have been observed after the administration of 1,2-dimethylhydrazine. Such changes are likely to lead to aberrant interactions between DNA and regulatory elements in chromatin, and may not be subject to repair.

Ntau-methylhistidine content of mixed proteins in various rat tissues

In order to use Ntau-methylhistidine (3-methylhistidine) excretion in the urine as a measure of muscle protein breakdown, it is necessary to demonstrate that other tissues are not important sources of this protein constituent. Accordingly, the concentration of Ntau-methylhistidine in blood serum and in the mixed proteins of heart, brain, lung, kidney, diaphragm, spleen, testis, stomach, liver and hind leg skeletal muscle was measured in male rats of approx. 400 g body weight. The free Ntau-methylhistidine concentration of rat serum was less than 2 nmol per ml. In contrast, measurable amounts of Ntau-methylhistidine were found in the mixed proteins of all tissues and organs examined. The highest concentration was found in skeletal muscle (658 nmol/g tissue). Assuming muscle mass to be 45% of body weight, it has been estimated that the muscle contains more than ten times the total amount of this amino acid present in all of the other organs analyzed, which together account for about 20% of total body weight. These findings indicate that skeletal muscle is likely to be the major source of urinary Ntau-methylhistidine and the latter is, in consequence, a reflection of myofibrillar protein breakdown in skeletal muscle.