Comparison of age-associated changes of c-myc gene methylation in liver between man and mouse

Age-associated changes in DNA methylation of the c-myc gene in lever were compared between humans and mice which have large differences in aging rate. Although the overall methylation profiles of the gene and their age-related changes were found to be similar, the rate of change was much slower in humans than in mice. It suggests that the age-associated alteration of c-myc gene methylation is closely related to biological aging rather than to chronological aging.     

Effects of energy restriction on age-associated changes of DNA methylation in mouse liver

DNA methylation is known to change with age in several mammalian species. Here we have examined the effect of dietary energy restriction on this age-associated change in liver DNA of C3H/SHN mice. The total 5-methyldeoxycytidine level in the genome decreased slightly soon after energy restriction started. The effect, however, diminished with time and no appreciable difference was detected at middle and old ages. The degree of methylation at the c-myc gene, on the other hand, was not affected by energy restriction at early periods, but the age-dependent alterations at later ages were repressed. This is a new finding to show that DNA methylation is one of the molecular indices of aging affected by energy restriction. It suggests an importance of DNA methylation in the aging process.     

Human and mouse cellularmyc protooncogenes reside on chromosomes involved in numerical and structural aberrations in cancer 1

A molecular clone of viralmyc (v-myc, the oncogene of avian myelocytomatosis virus, MC29, detected homologous human, mouse, and Chinese hamster cellularmyc (c-myc sequences by Southern filter hybridization. A v-myc probe, containing sequences from the 3′ domain of the gene, hybridized to single human HindIII and mouse EcoRI genomic DNA fragments of the cellular myc genes whose segregation could be followed in interspecies somatic cell hybrids. Human c-myc segregated concordantly with the enzyme marker glutathione reductase and with a karyotypically normal chromosome 8. A rearrangement of human c-myc was observed in Burkitt's lymphoma cells possessing the t(8;14) translocation. These results suggest that human c-myc is located close to the breakpoint on chromosome 8 (q24) involved in the t(8;14) translocation. The mouse c-myc gene segregated concordantly with chromosome 15 in mouse-Chinese hamster cell hybrids. These gene assignments are noteworthy, as structural and numerical abnormalities of human chromosome 8 and mouse chromosome 15 are associated frequently with B-cell neoplasms.     

Age-related increase in methylation of ribosomal genes and inactivation of chromosome-specific rRNA gene clusters in mouse

An age-related increase in DNA methylation of the multicopy 18S and 28S ribosomal RNA genes was found in CBA/Ca mice beginning between 6 and 18 months of age at the 5′ end of these genes in liver, brain and spleen. The highest level of age-associated hypermethylation was mapped to the proximal 5′ spacer domain. Silver staining of actively transcribing ribosomal genes in metaphase chromosomes from stimulated spleen cells provided cytological evidence that these mice have 3 rRNA cistrons located on chromosomes 15, 16, and 18. The ribosomal gene cluster located on chromosome 16 was preferentially inactivated in older animals. Exposure of spleen cells from older individuals to 5-azacytidine appeared to both reactivate ribosomal gene clusters and reduce rRNA gene methylation.     

Catecholamine-induced cardiac hypertrophy: significance of proto-oncogene expression

The effect of β- and α-adrenergic stimulation on cardiovascular function and development of cardiac hypertrophy was studied in rats by measuring the heart weight/body weight and cardiac RNA/DNA ratios. β-Receptor stimulation with isoproterenol over 3 days induced an increase in the biosynthesis of cardiac adenine nucleotides, myocardial protein synthesis, and the heart weight/body weight ratio. The isoproterenol-induced metabolic effects were prevented by simultaneous β-adrenergic blockade with propranolol. α-Adrenergic stimulation with norfenephrine for 3 days induced an increase in heart rate, total peripheral resistance, the myocardial RNA/DNA, and left ventricular weight/body weight ratio. The calcium antagonist verapamil prevented the hemodynamic changes but did not influence the development of cardiac hypertrophy. The α-adrenergic blocker prazosin reversed the norfenephrine-induced functional changes and prevented cardiac hypertrophy. Norepinephrine was infused into isolated perfused working rat hearts to elucidate some molecular biological changes that precede the development of cardiac hypertrophy. It increased transiently and sequentially the mRNA of c-fos and c-myc. This enhancement occurred at about the same time as that induced by elevation of pre- and afterload but was more pronounced. These findings were compared with those obtained in other studies assessing the effects of catecholamines on proto-oncogene expression. Combination of norepinephrine with pre- and afterload elevation induced the c-fos mRNA signal to appear earlier, to be more pronounced, and to persist for a longer period of time. Similar results were obtained in regard to the c-myc mRNA. These findings indicate that the combination of two hypertrophy-inducing stimuli which may cause a higher degree of cardiac hypertrophy in vivo induce an earlier, more pronounced, and longer lasting expression of the proto-oncogenes c-fos and c-myc.     

Analysis of c-myc DNA amplification in non-small cell lung carcinoma in comparison with small cell lung carcinoma using polymerase chain reaction

Previous studies of c-myc DNA amplification in lung cancer have focused primarily on analysis of small cell carcinoma or its tumor cell lines. There are few data about c-myc DNA amplification in histological types of lung cancer other than small cell carcinoma. Therefore the present study was conducted to investigate c-myc oncogene amplification in non-small cell lung carcinoma. We studied 46 lung tumor specimens for c-myc DNA amplification (15 adenocarcinomas, 15 squamous cell carcinomas, 6 large cell carcinomas, and 10 small cell carcinomas). Polymerase chain reaction, digoxigenin DNA labeling, and elecrophoresis were utilized to investigate the c-myc copy number in the lung tumor specimens. The c-myc copy number of non-small cell carcinoma ranged from 1.5 to more than 20.0 in adenocarcinoma and squamous cell carcinoma, and from 6.0 to 12.0 in large cell carcinoma. That of small cell carcinoma ranged from 1.8 to 12.0. The c-myc copy number of non-small cell carcinoma was significantly higher that than of small cell carcinoma (Wilcoxon rank sum test, Z=2.06, P=0.040). However, the differences in c-myc copy number among these four histological types were not statistically significant. Amplification of c-myc (more than 4 copies) was observed not only in small cell carcinoma but also in non-small cell carcinoma at similarly high frequency (12/15 in adenocarcinoma and squamous cell carcinoma, 6/6 in large cell carcinoma, and 9/10 in small cell carcinoma). Received: 17 October 2000 / Accepted: 7 May 2001     

c-myc null cells misregulate cad and gadd45 but not other proposed c-Myc targets

We report here that the expression of virtually all proposed c-Myc target genes is unchanged in cells containing a homozygous null deletion of c-myc. Two noteworthy exceptions are the gene cad, which has reduced log phase expression and serum induction in c-myc null cells, and the growth arrest gene gadd45, which is derepressed by c-myc knockout. Thus, cad and gadd45 are the only proposed targets of c-Myc that may contribute to the dramatic slow growth phenotype of c-myc null cells. Our results demonstrate that a loss-of-function approach is critical for the evaluation of potential c-Myc target genes.     

急性白血病p53基因P1启动子区域DNA甲基化研究

目的：通过检测急性白血病（AL）中p53基因P1启动子异常甲基化，探讨p53基因异常甲基化在急性白血病中的意义。方法:分别使用限制性内切酶MspⅠ、HpaⅡ、EcoRⅡ、BstNⅠ酶切提取基因组DNA，然后分别使用酶切后产物及基因组DNA为模板进行PCR扩增。产物电泳后在凝胶成像分析系统内观测电泳条带及摄像；部分标本的电泳条带经凝胶回收纯化后进行测序。结果:急性白血病患者p53基因第一启动子甲基化阳性率为38.7％，而急性淋巴细胞白血病（ALL）与急性非淋巴细胞白血病(ANLL)患者分别为45.5％、35.0％。正常对照标本中未检测到p53基因的异常甲基化。p53基因甲基化情况在急性白血病病人与正常人之间经过统计学检验，P<0.05；但急性淋巴细胞白血病与急性非淋巴细胞白血病患者之间无显著差异，P>0.05。分析急性白血病患者p53基因甲基化与患者临床资料之间的关系，其中，p53基因异常甲基化与肝脾淋巴结是否肿大之间的关系经统计学分析P<0.05。结论:①部分急性白血病患者存在p53基因第一启动子异常甲基化，正常对照中未检测到p53基因的甲基化；②p53基因第一启动子在急性淋巴细胞白血病与急性非淋巴细胞白血病均可发生异常甲基化，两者之间发生甲基化的概率无统计学差异；③p53基因异常甲基化与肝脾淋巴结肿大有显著差异，但p53基因异常甲基化与急性白血病治疗效果及预后的关系尚不能确定，须进一步研究确定。     

No correlation of c-myc overexpression and p53 mutations in liposarcomas

 Although it is well known that oncogenesis is a multistep process involving the activation of normal cellular genes to become oncogenes and/or the inactivation of tumor suppressor genes, this process has seldom been investigated in soft tissue tumours. We screened a group of 36 liposarcomas for genetic abnormalitis in the p53 tumour suppressor gene and c-myc oncogene. Altered c-myc gene expression was examined by differential RT-PCR assay. p53 Gene mutations in exons 4–8 were analysed by using PCR-SSCP analysis and direct sequencing. Elevated c-myc expression was found in 6 of 31 liposarcomas (19.4%). p53 Gene mutations were observed in 5 of 36 liposarcomas (13.9%). Both genetic alterations were associated with the histological subtype of liposarcomas. Whereas c-myc gene expression was a characteristic of myxoid/round cell liposarcomas, p53 gene mutations were found more frequently in pleomorphic variants. Liposarcomas of the well-differentiated subtype showed neither p53 gene mutations nor altered c-myc gene expression. Our results indicate that the c-myc oncogene and the p53 tumor suppressor gene do not seem to cooperate in the oncogenesis of liposarcomas. Received: 22 April 1998 / Accepted: 11 May 1998     

Nucleotide sequence of the CMII v-myc allele

The entire nucleotide sequence of the transduced v-myc allele in the genome of avian oncogenic retrovirus CMII was determined. The CMII v-myc and the chicken c-myc alleles differ in their shared coding sequences by a single nucleotide substitution causing a glutamic acid/alanine exchange in the predicted sequences of the corresponding protein products. This mutation has not been found in the transduced v-myc alleles of avian oncogenic retroviruses MC29, MH2, and OK10. We conclude that no specific, if any, missense mutation of the c-myc coding sequence is necessary for oncogenic activation upon transduction of the cellular gene.     

c-myc GENE ABNORMALITIES IN MUCOSA-ASSOCIATED LYMPHOID TISSUE (MALT) LYMPHOMAS

c-myc gene abnormalities associated with lymphomagenesis, including rearrangements and mutations in the regulatory region between exon I and intron I, have been studied in 54 MALT lymphomas (43 low and 11 high grade) and 36 nodal lymphomas (27 low and 9 high grade). By Southern blot analysis, none of the 54 MALT lymphomas but 2 of 36 nodal lymphomas had c-myc gene rearrangements. Defined tumour cell populations from all MALT lymphoma cases were isolated by microdissection from frozen tissue sections and analysed by polymerase chain reaction–single-strand conformational polymorphism (PCR–SSCP) and direct sequencing for somatic mutations in the exon I/intron I region of the gene. Point mutations in this region were identified in nine cases of MALT lymphoma (7/43=16·2 per cent of low grade; 2/11=18·1 per cent of high grade). These mutations were located at either the exon I/intron I border of myc intron factor (MIF) binding sites, which are critical in the negative regulation of c-myc expression. Of the nodal lymphomas, only the two cases (5·6 per cent) with c-myc gene rearrangement showed scattered or clustered mutations. These results suggest that c-myc mutations in MALT lymphomas are unlikely to be associated with chromosome translocation, which is the main cause of somatic mutations observed in other types of lymphoma. The mutations involving the c-myc regulatory regions may play a pathogenetic role in at least a proportion of MALT lymphomas. © 1997 by John Wiley & Sons, Ltd.     

Age- and sex-dependent DNA hypomethylation controlled by growth hormone in mouse liver

In mammals, differences in liver function and aging have been observed between sexes; however, the epigenetic mechanisms underlying such differences remain largely unexplored. In this study, we investigated sex- and age-dependent DNA methylation status in the mouse liver. We analyzed 90 known sex-differentially expressed genes, and identified sex-dependent methylation in Zfp809, Hsd3b5, Treh, Cxcl11, Cyp17a1, and Nnmt genes. After 4 weeks of age, we noted the gradual establishment of sex-dependent hypomethylation in each of these genes in either males or females. The exposure of male mice to female-like growth hormone (GH) profile repressed male-predominant hypomethylation and promoted female-predominant hypomethylation. The occurrence of age-dependent hypomethylation, including at loci for which we also observed sex-dependent changes in DNA methylation, was accompanied by the downregulation of DNMT3A/B. In addition, we found that age-dependent hypomethylation was promoted through liver regeneration induced by partial hepatectomy, suggesting that DNMT activities were not enough to retain methylation levels. In conclusion, our results demonstrate that sex-dependent GH profiles influence the age-progressive hypomethylation under decreased DNMT3A/B levels in certain regions of the genome.     

Messenger RNA 3′-end formation of a DNA fragment from the human c-myc 3′-end region in Saccharomyces cerevisiae

We have tested the functioning of the human c-myc polyadenylation signal in Saccharomyces cerevisiae. A DNA fragment containing the two AATAAA polyadenylation signals of the c-myc gene was inserted into a plasmid designed for the in-vivo testing of polyadenylation signals in yeast. The c-myc fragment had a partial capacity for directing mRNA 3-end formation in yeast. The 3-endpoints were 50–100 bp distant from the mRNA 3-ends mapped in humans. This human DNA fragment is therefore unspecifically functional in yeast, indicating that other sequence elements than the human polyadenylation signal, AATAAA, are necessary for 3-end formation.     

Messenger RNA levels and methylation patterns of GAPDH and beta-actin genes in rat liver, spleen and brain in relation to aging

Messenger RNA levels and methylation patterns of the glyceraldehyde-3-phosphate-dehydrogenase (GAPDH) and beta-actin genes were studied in spleen, liver and brain of 6-, 24- and 36-month old female inbred rats. In the spleen, the mRNA levels of both housekeeping genes significantly increased between 24 and 36 months. No age-related alterations in the expression of GAPDH or beta-actin mRNA were observed in brain or liver. A considerable intertissue and interindividual variation was observed in the mRNA levels of these genes in all age-groups as compared to the level of 28 S rRNA, which was used as an internal control. In this respect the interindividual variation in the level of GAPDH mRNA paralleled the variation observed in the beta-actin mRNA level in the three tissues studied. The methylation pattern of beta-actin was found to be tissue-specific in contrast to that of GAPDH, which was identical in all three tissues. No significant age-related alterations were observed in the GAPDH methylation pattern, whereas beta-actin appeared to become slightly demethylated with age in the spleen at the CpG site for which tissue-specificity was observed.