Genes constitute only a small proportion of the total mammalian genome, and the precise control of their expression in the presence of an overwhelming background of noncoding DNA presents a substantial problem for their regulation. Noncoding DNA, containing introns, repetitive elements, and potentially active transposable elements, requires effective mechanisms for its long-term silencing. Mammals appear to have taken advantage of the possibilities afforded by cytosine methylation to provide a heritable mechanism for altering DNA-protein interactions to assist in such silencing. Genes can be transcribed from methylation-free promoters even though adjacent transcribed and nontranscribed regions are extensively methylated. Gene promoters can be used and regulated while keeping noncoding DNA, including transposable elements, suppressed. Methylation is also used for long-term epigenetic silencing of X-linked and imprinted genes and can either increase or decrease the level of transcription, depending on whether the methylation inactivates a positive or negative regulatory element.
. Any definition of a CpG island is somewhat arbitrary, and this one, which was derived before the sequencing of mammalian genomes, will include many sequences that are not necessarily associated with controlling regions of genes but rather are associated with intragenomic parasites. We have therefore used the complete genomic sequences of human chromosomes 21 and 22 to examine the properties of CpG islands in different sequence classes by using a search algorithm that we have developed. Regions of DNA of greater than 500 bp with a G؉C equal to or greater than 55% and observed CpG͞expected CpG of 0.65 were more likely to be associated with the 5 regions of genes and this definition excluded most Alu-repetitive elements. We also used genome sequences to show strong CpG suppression in the human genome and slight suppression in Drosophila melanogaster and Saccharomyces cerevisiae. This finding is compatible with the recent detection of 5-methylcytosine in Drosophila, and might suggest that S. cerevisiae has, or once had, CpG methylation.
Almost 1-2% of the human genome is located within 500 bp of either side of a transcription initiation site, whereas a far larger proportion (Ϸ25%) is potentially transcribable by elongating RNA polymerases. This observation raises the question of how the genome is packaged into chromatin to allow start sites to be recognized by the regulatory machinery at the same time as transcription initiation, but not elongation, is blocked in the 25% of intragenic DNA. We developed a chromatin scanning technique called ChAP, coupling the chromatin immunoprecipitation assay with arbitrarily primed PCR, which allows for the rapid and unbiased comparison of histone modification patterns within the eukaryotic nucleus. Methylated lysine 4 (K4) and acetylated K9͞14 of histone H3 were both highly localized to the 5 regions of transcriptionally active human genes but were greatly decreased downstream of the start sites. Our results suggest that the large transcribed regions of human genes are maintained in a deacetylated conformation in regions read by elongating polymerase. Common models depicting widespread histone acetylation and K4 methylation throughout the transcribed unit do not therefore apply to the majority of human genes.
Epigenetic silencing of tumor suppressor genes is generally thought to involve DNA cytosine methylation, covalent modifications of histones, and chromatin compaction. Here, we show that silencing of the three transcription start sites in the bidirectional MLH1 promoter CpG island in cancer cells involves distinct changes in nucleosomal occupancy. Three nucleosomes, almost completely absent from the start sites in normal cells, are present on the methylated and silenced promoter, suggesting that epigenetic silencing may be accomplished by the stable placement of nucleosomes into previously vacant positions. Activation of the promoter by demethylation with 5-aza-2'-deoxycytidine involves nucleosome eviction. Epigenetic silencing of tumor suppressor genes may involve heritable changes in nucleosome occupancy enabled by cytosine methylation.
The methylation status of binding sites of the insulator protein, CTCF, in the H19 promoter has been suggested as being critical to the regulation of imprinting of the H19/IGF2 locus located in chromosome 11p15. In this study, we have analyzed the methylation of all of seven potential CTCF-binding sites in the human H19 promoter since the methylation status of these sites has not been reported. We found that all the binding sites except the sixth were hypermethylated whereas only the sixth binding site showed allele-specific methylation in normal human embryonic ureteral tissue. We also analyzed the methylation status of these sites in human-mouse somatic-cell-hybrid clones containing a single copy of human chromosome 11 and which were treated with 5-aza-2'-deoxycytidine (5-aza-CdR) to yield clones which expressed human IGF2 and H19 mutually exclusively of each other. In most of the clones, a correlation between methylation of the sixth CTCF-binding site and expression of IGF2 was observed. Therefore, we analyzed the methylation status of this site in human bladder cancer and found hypomethylation of the paternal allele in two of six informative cases. These results demonstrate that only the sixth CTCF-binding site acts as a key regulatory domain for switching between H19 or IGF2 expression, whereas the other sites are not subject to allele-specific methylation. Loss of methylation imprinting of H19 is linked to hypomethylation of the paternal allele in human bladder cancer, unlike the situation in Wilms' tumor and colon cancer where the maternal allele becomes hypermethylated.
Small interference RNA (siRNA) is an emerging methodology in reverse genetics. Here we report the development of a new tetracycline-inducible vector-based siRNA system, which uses a tetracycline-responsive derivative of the U6 promoter and the tetracycline repressor for conditional in vivo transcription of short hairpin RNA. This method prevents potential lethality immediately after transfection of a vector when the targeted gene is indispensable, or the phenotype of the knockdown is lethal or results in a growth abnormality. We show that the controlled knockdown of DNA methyltransferase 1 (DNMT1) in human cancer resulted in growth arrest. Removal of the inducer, doxycycline, from treated cells led to re-expression of the targeted gene. Thus the method allows for a highly controlled approach to gene knockdown.
To determine whether mtDNA and mitochondrial respiratory function in pancreatic beta cells are necessary for the phenotypic expression of glucose-stimulated insulin secretion, we used a cultured mouse pancreatic beta cell line, MIN6, and two derivative lines, mtDNA knockout MIN6 ( 0 MIN6) and mtDNA repopulated cybrid MIN6. The MIN6 cells retain the property of glucose-stimulated insulin secretion, but their mtDNA knockout induced the loss of mitochondrial transcription, translation, and respiration activity, without inhibition of transcription of the insulin gene or loss of succinate dehydrogenase activity, indicating that the observed mitochondrial dysfunction in 0 MIN6 cells was not due to a cytotoxic side effect derived from the mtDNA knockout. Moreover, the mtDNA depletion also inhibited both the glucose-stimulated increase in the intracellular free Ca 2؉ content and the elevation of insulin secretion. The possibility of the involvement of nuclear genome-encoded factors in this process was excluded by the observation that the missing sensitivity to extracellular glucose stimulation in 0 MIN6 cells was restored reversibly by repopulation with foreign mtDNA and isolating cybrid MIN6 clones. Therefore, these findings provide unambiguous evidence for the involvement of the mitochondrial dysfunction induced by mtDNA impairment in developing pathogeneses of some forms of diabetes mellitus.
MicroRNA (miRNA) expression is frequently altered in human cancers. To search for epigenetically silenced miRNAs in nonsmall-cell lung cancer (NSCLC), we mapped human miRNAs on autosomal chromosomes and selected 55 miRNAs in silico. We treated six NSCLC cell lines with the DNA methylation inhibitor 5-aza-2 0 -deoxycytidine (5-aza-CdR) and determined the expressions of the 55 miRNAs. Fourteen miRNAs were decreased in the cancer cell lines and were induced after 5-aza-CdR treatment. After a detailed DNA methylation analysis, we found that mir-34b and mir-126 were silenced by DNA methylation. Mir-34b was silenced by the DNA methylation of its own promoter, whereas mir-126 was silenced by the DNA methylation of its host gene, EGFL7. A chromatin immunoprecipitation assay revealed H3K9me2 and H3K9me3 in mir-34b and EGFL7, and H3K27me3 in EGFL7. The overexpression of mir-34b and mir-126 decreased the expression of c-Met and Crk, respectively. The 5-aza-CdR treatment of lung cancer cell line resulted in increased mir-34b expression and decreased c-Met protein. We next analyzed the DNA methylation status of these miRNAs using 99 primary NSCLCs. Mir-34b and mir-126 were methylated in 41 and 7% of all the cases, respectively. The DNA methylation of mir-34b was not associated with c-Met expression determined by immunohistochemistry, but both mir-34b methylation (p 5 0.007) and c-Met expression (p 5 0.005) were significantly associated with lymphatic invasion in a multivariate analysis. The DNA methylation of mir-34b can be used as a biomarker for an invasive phenotype of lung cancer.MicroRNAs (miRNAs) are broadly conserved small noncoding RNA that regulate gene expression by binding to the 3 0 UTR of target mRNAs in a complementary manner. 1Through the posttranscriptional regulation of many target genes, miRNAs are involved in many biological processes, such as development and human carcinogenesis. MicroRNA expression is altered in human cancers, and some miRNAs have oncogenic or tumor suppressive functions in human malignancies, including lung cancer. 2-5Chromosomal deletions or amplifications are important mechanisms of miRNA expression change in cancers. For example, mir-15 and mir-16 are frequently deleted and downregulated in chronic lymphocytic leukemia.2 The mir-17-92 miRNA cluster is amplified and overexpressed in B-cell lymphoma 6 and lung cancer. 4 However, the precise mechanisms responsible for changes in miRNA expression in cancer remain largely unknown.DNA methylation plays an important role in inactivating tumor suppressor genes in many types of human cancers. 7,8 Recently, DNA methylation in cancerous tissue has been shown to cause the silencing of miRNAs located in the vicinity of CpG islands. 9,10 As the epigenetic silencing of tumor suppressor genes is a common event in lung carcinogenesis 11-14 and miRNA expression is altered in lung cancer, 5 we decided to search for epigenetically silenced miRNAs in lung cancer.In our study, we selected 55 candidate miRNAs in silico based on the genome structure and tre...
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