采用蛋白质组学技术筛选鼻咽癌细胞的甲基化沉默基因

为筛选鼻咽癌的甲基化沉默基因,采用二维凝胶电泳(2-DE)技术分离甲基转移酶抑制剂5-杂氮-2'-脱氧胞苷(5-aza-2-dC)处理与未处理鼻咽癌细胞5-8F的蛋白质,PDquest图像分析软件识别差异蛋白质点,基质辅助激光解吸电离飞行时间质谱(MALDI-TOF-MS)鉴定差异蛋白质.然后采用Western blotting和RT-PCR检测差异蛋白质nm23-H1在药物处理与未处理5.8F细胞中的表达水平,采用甲基化特异性PCR(MS-PCR)检测nm23-H1基因在药物处理与未处理5-8F细胞中的甲基化水平.建立了5-aza-2-dC处理与未处理5.8F细胞蛋白质的2-DE图谱,识别了49个差异表达的蛋白质点,鉴定了33个差异表达的蛋白质,其中包括rim23.H1在内的15个蛋白质在5-aza-2-dC处理后的5-8F细胞中表达上调,而18个蛋白质表达下调.Western blotting和RT-PCR结果显示,nm23-H1在5-aza-2-dC处理5-8F细胞后表达上调,MS-PCR结果显示,在5-aza-2-dC处理5-8F细胞后nm23-H1基因甲基化水平下降,结果证实,nm23-H1基因是5-8F细胞中的甲基化沉默基因.15个5-aza.2-dC处理后表达上调的基因可能是5-8F细胞中的甲基化沉默基因,为筛选鼻咽癌甲基化失活基因提供了科学依据.     

Noninduced single-stranded breaks in DNA in murine F9 teratocarcinoma cells

Our previous study demonstrated the high incidence of non-induced DNA single strand breaks (SSB) in preimplantation mouse embryo genom (Patkin et al., 1994). F9 mouse teratocarcinoma cell line is an in vitro model for early embryonal differentiation, since F9 cells remind in many respects the inner cell mass cells of mouse blastocyst and are capable of differentiation under retinoic acid (RA) and dibutyryl cAMP (db-cAMP) treatment. Using gap filling reaction of F9 metaphase chromosomes and single-cell DNA electrophoresis, we have observed multiple SSB in undifferentiated F9 cells as well as in F9 cells at the early steps of RA-induced differentiation (days of RA treatment), but not in terminally differentiated F9 cells and in mouse embryonal fibroblasts. Rad51 nuclear protein that binds specifically single stranded DNA is highly expressed in all cells of undifferentiated F9 population and is not expressed in terminally differentiated F9 population. Multiple SSB could lead to enhanced rate of sister chromatid exchanges (SCE) in F9 cells. In undifferentiated F9 population the level of SCE was 9.6 +/- 0.44 per metaphase, that was not higher than in NIH 3T3 cell line. However, RA treatment for 48 h led to rising the SCE level up to 16.68 +/- 0.72 followed by its decrease to the initial rate by 72 h of RA treatment. Since the enhanced level of SSB in undifferentiated F9 cells and in mouse blastocyst does not normally lead to chromosomal instability, we consider SSB to be a natural consequence of fast-going DNA replication in these cells.     

Expression of ribosomal genes under the action of 5-azacytidine in the African green monkey RAMT cell line

The use of cytosine analogue--5-Azacytidine(5AzaC), derepression of ribosomal genes has been studied in one of organising chromosomes in the African green monkey RAMT cell line in which the nucleolar organizer region (NOR) in parental cells was active. The effect of 5AzaC on the functional state of NOR was assessed by the length of the secondary constriction in this chromosome and by the intensity of Ag-staining of NOR. 5AzaC was added to the cell culture at concentrations 2-16 M, either immediately after the cell passage or at the 24th h from the beginning of cell cultivation for the following 17-34 hours. As a control the cells cultivated in the absence of 5AzaC were used. Comparison of control cells with those treated with 5AzaC showed: 1) increase of the length of the second constriction in the chromosome with the initial inactive NOR in the 5AzaC--treated cells; 2) a marked increase of the intensity of NOR's Ag-staining in the same chromosome after incorporation of 5-AzaC into DNA. The conclusion about the methylation of cytosine bases in the DNA of ribosomal genes in one NOR organising chromosomes in RAMT cell line was made.     

Identification of differentially expressed genes in isogenic highly metastatic and poorly metastatic cell lines of R3230AC rat mammary adenocarcinoma

Tumour metastasis occurs as a result of a cascade of events including alterations in the expression of various genes. The identification of such genes is essential to understanding formation of metastasis. In a previous study, highly metastatic (LN4.D6) and poorly metastatic (CAb.D5) cell lines were obtained from the rat mammary adenocarcinoma cell line R3230AC. Subtractive hybridization was used to identify differentially expressed genes between these two cell lines. We identified eight cDNA clones in CAb.D5 and six cDNA clones in LN4.D6 that were differentially expressed. One of the cDNA clones in each cell line had no homology with known sequences. Expression patterns of these differentially expressed genes were examined in a pair of rat mammary and prostate adenocarcinoma cell lines. Compared with cell lines examined, cDNA FF-10 was only expressed in CAb.D5; however, cDNA RB-8, RE-1, RF-5 were only expressed in the highly metastatic LN4.D6. No correlation was observed between expression patterns of the differentially expressed genes and metastatic potential of these cells. However, differential expression of genes, especially cytokeratins (CK8 and CK5) and collagens (III and IV) between highly metastatic and low metastatic rat mammary adenocarcinoma cell lines might initiate further investigation of these genes in metastatic process.     

Astrocyte-specific genes are generally demethylated in neural precursor cells prior to astrocytic differentiation

Epigenetic changes are thought to lead to alterations in the property of cells, such as differentiation potential. Neural precursor cells (NPCs) differentiate only into neurons in the midgestational brain, yet they become able to generate astrocytes in the late stage of development. This differentiation-potential switch could be explained by epigenetic changes, since the promoters of astrocyte-specific marker genes, glial fibrillary acidic protein (Gfap) and S100beta, have been shown to become demethylated in late-stage NPCs prior to the onset of astrocyte differentiation; however, whether demethylation occurs generally in other astrocyctic genes remains unknown. Here we analyzed DNA methylation changes in mouse NPCs between the mid-(E11.5) and late (E14.5) stage of development by a genome-wide DNA methylation profiling method using microarrays and found that many astrocytic genes are demethylated in late-stage NPCs, enabling the cell to become competent to express these genes. Although these genes are already demethylated in late-stage NPCs, they are not expressed until cells differentiate into astrocytes. Thus, late-stage NPCs have epigenetic potential which can be realized in their expression after astrocyte differentiation.     

Rearrangements and deletions of immunoglobulin heavy chain genes in the double-producing B cell lymphoma I.29.

The B cell lymphoma I.29 consists of a mixture of cells expressing membrane-bound immunoglobulin M (IgM) (lambda) and IgA (lambda) of identical idiotypes. Whereas most of the cells express either IgM or IgA alone, 1 to 5% of the cells in this tumor express IgM and IgA simultaneously within the cytoplasm and on the cell membrane (R. Sitia et al., J. Immunol. 127:1388-1394, 1981; R. Sitia, unpublished data). When IgM+ cells are purified from the lymphoma and passaged in mice or cultured, a portion of the cells convert to IgA+. These properties suggest that some cells of the I.29 lymphoma may undergo immunoglobulin heavy chain switching, although it is also possible that the mixed population was derived by a prior switching event in a clone of cells. We performed Southern blotting experiments on genomic DNAs isolated from populations of I.29 cells containing variable proportions of IgM+ and IgA+ cells and on a number of cell lines derived from the lymphoma. The results were consistent with the deletion model for heavy chain switching, as the IgM+ cells contained rearranged mu genes and alpha genes in the germ line configuration on both the expressed and nonexpressed heavy chain chromosomes, whereas the IgA+ cells had deleted both mu genes and contained one rearranged and one germ line alpha gene. In addition, segments of DNA located within the intervening sequence 5' to the mu gene, near the site of switch recombination, were deleted from both the expressed and the nonexpressed chromosomes. Although mu genes were deleted from both chromosomes in the IgA+ cells, the sites of DNA recombination differed on the two chromosomes. On the expressed chromosome, Smu sequences were recombined with S alpha sequences, whereas on the nonexpressed chromosome, Smu sequences were recombined with S gamma 3 sequences.     

Individual Xenopus histone genes are replication-independent in oocytes and replication-dependent in Xenopus or mouse somatic cells.

We have assessed the response of many histone H3 mRNAs and an H1C mRNA in Xenopus tissue culture cells after treatment with the DNA synthesis inhibitor hydroxyurea. The amount of the histone mRNAs falls rapidly in response to the inhibitor. This response is prevented by cycloheximide. Cloned Xenopus histone genes were transfected into mouse cells and a cell line was obtained in which the Xenopus genes were actively expressed giving rise to mRNA with correct 5'-termini. The Xenopus genes were correctly regulated at the level of mRNA amounts in the mouse cell line. Nuclear microinjection experiments with Xenopus oocytes and S1 nuclease analysis of normal ovary RNA showed that the H1C gene, and probably also two H3 genes, which are replication-dependent in somatic cells are expressed in oocytes and are therefore replication-independent in this cell type. The same promoters are used in both replication-dependent and independent expression.     

Cloning of cancer-related genes of Rat6 fibroblasts by using an improved differential display method]

The p53 gene is the most frequently mutated gene identified so far in human cancers. When a mutant p53(135)-val gene was allowed to be over-expressed in Rat6(R6) cells, a high incidence of spontaneous transformation was observed in long-term culture of this cell line(R6 # 13-8). To identify genes involved in cell transformation, parental p53 over-expressing cell, R6 # 13-8, and its spontaneous transformant T2, were analyzed by an improved mRNA differential display technique, which was reproducible, simpler, and was able to clone cDNA longer than 500 bp, and was with less false positives. When 33 10-mer or 12-mer single primers with arbitrary but defined sequence were used for PCR, over 90 discrete cDNAs were obtained from R6 # 13-8 and T2 cells. Three differentially expressed cDNAs were identified, one of them is highly expressed in T2 cells, while the other two, 0.8 kb and 0.9 kb long, are highly expressed in R6 # 13-8 cells. The latter were cloned and confirmed by Northern hybridization. Both cloned fragment were not homologous with any published sequence. Our results suggest that the activation and inactivation of genes are involved in the process of the spontaneous transformation from R6 # 13-8 to T2.     

Amplification and overexpression of oncogene Mdm2 and orphan receptor gene Nr1h4 in immortal PRKDC knockout cells

DNA-dependent protein kinase (DNA-PK) is required for the repair of double strand DNA breaks by nonhomologous DNA end joining. The catalytic subunit of DNA-PK, PRKDC, may also be involved in repair-related or separate cell signaling pathways. To learn more about the cellular function of DNA-PK under normal physiological conditions, we identified genes that are differentially expressed between an immortalized wild-type mouse fibroblast cell line and its DNA-PK-deficient counterpart (Prkdc -/-). The proto-oncogene Mdm2 and the farnesoid X receptor gene Nrlh4 were overexpressed in the DNA-PK-deficient cell line. We show that in the DNA-PK-deficient cell line the genes for both Mdm2 and Nrlh4 are amplified to a degree that could account for most, if not all, of their increased expression. Other genes were strongly downregulated in the DNA-PK-deficient cell line, but this opposite expression pattern was not due to gene amplification in the wild-type cells. None of these genes was differentially expressed in DNA-PK-containing and DNA-PK-deficient primary mouse embryo fibroblasts. Our results suggest a model in which DNA-PK indirectly affects the cellular gene expression profile through its caretaker role and by preventing gene amplification.