A mutation in human VAP-B--MSP domain, present in ALS patients, affects the interaction with other cellular proteins.

Amyotrophic Lateral Sclerosis (ALS) is the most common adult-onset Motor Neuron Disease (MND), characterized by motor neurons death in the cortex, brainstem and spinal cord. Ten loci linked to Familial ALS have been mapped. ALS8 is caused by a substitution of a proline by a serine in the Vesicle-Associated Membrane Protein-Associated protein-B/C (VAP-B/C). VAP-B belongs to a highly conserved family of proteins implicated in Endoplasmic Reticulum-Golgi and intra-Golgi transport and microtubules stabilization. Previous studies demonstrated that the P56S mutation disrupts the subcellular localization of VAP-B and that this position would be essential for Unfolded Protein Response (UPR) induced by VAP-B. In the present work we expressed and purified recombinant wild-type and P56S mutant VAP-B-MSP domain for the analysis of its interactions with other cellular proteins. Our findings suggest that the P56S mutation may lead to a less stable interaction of this endoplasmic reticulum protein with at least two other proteins: tubulin and GAPDH. These two proteins have been previously related to other forms of neurodegenerative diseases and are potential key points to understand ALS8 pathogenesis and other forms of MND. Understanding the role of these protein interactions may help the treatment of this devastating disease in the future.

Analysis of the Saccharomyces cerevisiae exosome architecture and of the RNA binding activity of Rrp40p.

The exosome is a complex of eleven subunits in yeast, involved in RNA processing and degradation. Despite the extensive in vivo functional studies of the exosome, little information is yet available on the structure of the complex and on the RNase and RNA binding activities of the individual subunits. The current model for the exosome structure predicts the formation of a heterohexameric RNase PH ring, bound on one side by RNA binding subunits, and on the opposite side by hydrolytic RNase subunits. Here, we report protein-protein interactions within the exosome, confirming the predictions of constituents of the RNase PH ring, and show some possible interaction interfaces between the other subunits. We also show evidence that Rrp40p can bind RNA in vitro, as predicted by sequence analysis.

Large scale mapping of methylcytosines in CTCF-binding sites in the human H19 promoter and aberrant hypomethylation in human bladder cancer.

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.

Altered chromatin structure associated with methylation-induced gene silencing in cancer cells: correlation of accessibility, methylation, MeCP2 binding and acetylation.

Silencing of tumor-suppressor genes by hypermethylation of promoter CpG islands is well documented in human cancer and may be mediated by methyl-CpG-binding proteins, like MeCP2, that are associated in vivo with chromatin modifiers and transcriptional repressors. However, the exact dynamic between methylation and chromatin structure in the regulation of gene expression is not well understood. In this study, we have analyzed the methylation status and chromatin structure of three CpG islands in the p14(ARF)/p16(INK4A) locus in a series of normal and cancer cell lines using methylation-sensitive digestion, MspI accessibility in intact nuclei and chromatin immunoprecipitation (ChIP) assays. We demonstrate the existence of an altered chromatin structure associated with the silencing of tumor-suppressor genes in human cancer cell lines involving CpG island methylation, chromatin condensation, histone deacetylation and MeCP2 binding. The data showed that MeCP2 could bind to methylated CpG islands in both promoters and exons; MeCP2 does not interfere with transcription when bound at an exon, suggesting a more generalized role for the protein beyond transcriptional repression. In the absence of methylation, it is demonstrated that CpG islands located in promoters versus exons display marked differences in the levels of acetylation of associated histone H3, suggesting that chromatin remodeling can be achieved by methylation-independent processes and perhaps explaining why non-promoter CpG islands are more susceptible to de novo methylation than promoter islands.

The endothelin receptor B (EDNRB) promoter displays heterogeneous, site specific methylation patterns in normal and tumor cells.

The 5' region for the endothelin receptor B (EDNRB) gene is a complex CpG island giving rise to four individual transcripts initiating within the island. Here, for the first time, we analyze the relationship between methylation and gene expression in a CpG island located in the 5' region of a gene with multiple transcription start sites. The CpG island was unmethylated in normal prostate and bladder tissue, whereas it became methylated in apparently normal colonic epithelium. Tumors derived from these tissues were frequently hypermethylated relative to the respective normal tissues. Analysis of 11 individual CpG sites located throughout the CpG island showed that specific sites with high methylation levels in several tumors were also methylated in normal tissues, suggesting that they might serve as foci for further de novo methylation. This region also had high levels of methylation in several cancer cell lines, and we found that a low methylation level in a small region within the 5' region correlated with expression of the 5'-most transcript. Interestingly, almost complete methylation 200-1000 bp downstream of the transcriptional start site did not block expression of this transcript. Finally, we show that treatment with 5-aza-2'-deoxycytidine can induce transcriptional activation of the four EDNRB transcripts. Our results show the existence of differential, tissue-dependent methylation at the EDNRB 5' region, suggest the existence of a spreading mechanism for de novo methylation, starting from methylation hotspots, and show that hypermethylation immediately 3' to a transcriptional start site does not prevent initiation.

PAX6 methylation and ectopic expression in human tumor cells.

The mechanisms underlying the de novo methylation of CpG islands in human cancer remain almost completely unknown. We used a methylation-sensitive arbitrarily primed polymerase chain reaction (Ms AP-PCR) technique to scan genomic DNA for differential methylation patterns and identified a 550 bp band that was hypermethylated in a majority of colon and bladder cancer cells. This band corresponded to a CpG-rich region in exon 5 of PAX6, which is a highly conserved transcription regulatory factor involved in embryogenesis. Interestingly, exon 5 was very frequently methylated in solid tumors compared with adjacent normal tissues, 17 out of 27 (63%) in bladder, and colon, but the promoter remained unmethylated in all these cases. This methylation was not effective in blocking transcription since ectopic expression of PAX6 was seen in several tumors and cell lines with extensive exon 5 methylation. De novo methylation of the promoter was only seen in tumor cell lines and was associated with gene silencing since treatment with 5-aza-2'-deoxycytidine restored expression to the cells and resulted in a less methylated promoter. Thus, ectopic expression and hypermethylation of exon 5 of PAX6 demonstrate that methylation within a transcribed region, as opposed to promoter methylation, does not block gene expression.

Analysis of cyclin-dependent kinase inhibitor expression and methylation patterns in human prostate cancers.

BACKGROUND: Downregulation of genes which negatively control cell cycle progression represents a possible mechanism for prostate tumorigenesis. We examined the expression levels of the p16, p15, p14, and retinoblastoma-susceptibility (RB) genes in primary prostate cancers and human prostate cancer cell lines, and correlated this with the DNA methylation levels of two loci in p16. METHODS: The mRNA levels of p16, p15, and p14 were examined by reverse transcriptase-PCR (RT-PCR). DNA methylation of the p16 5' CpG island was determined by bisulfite genomic sequencing, while methylation of exon 2 shared by the p16 and p14 genes was measured by a quantitative bisulfite-based technique, methylation-sensitive single-nucleotide primer extension (Ms-SNuPE). RB protein levels were assessed by immunohistochemical staining of histologic sections of normal and tumor prostate tissues, using a monoclonal antibody (mAB). RESULTS: Overexpression of p16 mRNA was found in 6/9 (67) of prostate tumors compared to the adjacent normal prostate, whereas elevated p14 and p15 levels were only observed in 2/9 (22) and 1/6 (17) of prostate cases, respectively. There was no statistically significant association of grade (P = 0.18) and stage (P = 1.00) of prostate cancer to the elevated p16 levels in the tumors. The p16 5' CpG island was completely unmethylated in these tissues. In contrast, exon 2 of p16/p14 was methylated in both the tumor and normal adjacent prostates, and was increased in 8/11 (73) of tumors relative to normal tissues. There was no association between p16 overexpression and increased p16/p14 exon 2 methylation in these tumors (P = 1.00). Diminished RB levels in prostate tumors that had upregulated p16 mRNA were found, although absent RB was also detected in tumors without elevated p16 levels. The expression levels of the two genes, RB and p16, were not correlated statistically (P = 0.16). CONCLUSIONS: Our studies show that although the levels of the cell cycle regulators p16, p15, p14, and Rb are altered in prostate cancers, there is no apparent correlation to grade, stage, or any pattern of regulation between the related genes. Exon 2 of p16/p14 is methylated in a majority of prostate tumors compared to the unmethylated upstream 5' region, and may be a potential tumor marker for human prostate cancer.

Differential mRNA expression of the human DNA methyltransferases (DNMTs) 1, 3a and 3b during the G(0)/G(1) to S phase transition in normal and tumor cells.

DNA methylation is essential for mammalian development, X-chromosome inactivation, and imprinting yet aberrant methylation patterns are one of the most common features of transformed cells. One of the proposed causes for these defects in the methylation machinery is overexpression of one or more of the three known catalytically active DNA methyltransferases (DNMTs) 1, 3a and 3b, yet there are clearly examples in which overexpression is minimal or non-existent but global methylation anomalies persist. An alternative mechanism which could give rise to global methylation errors is the improper expression of one or more of the DNMTs during the cell cycle. To begin to study the latter possibility we examined the expression of the mRNAs for DNMT1, 3a and 3b during the cell cycle of normal and transformed cells. We found that DNMT1 and 3b levels were significantly downregulated in G(0)/G(1)while DNMT3a mRNA levels were less sensitive to cell cycle alterations and were maintained at a slightly higher level in tumor lines compared to normal cell strains. Enzymatic activity assays revealed a similar decrease in the overall methylation capacity of the cells during G(0)/G(1)arrest and again revealed that a tumor cell line maintained a higher methylation capacity during arrest than a normal cell strain. These results reveal a new level of control exerted over the cellular DNA methylation machinery, the loss of which provides an alternative mechanism for the genesis of the aberrant methylation patterns observed in tumor cells.

Roles of cell division and gene transcription in the methylation of CpG islands.

De novo methylation of CpG islands within the promoters of eukaryotic genes is often associated with their transcriptional repression, yet the methylation of CpG islands located downstream of promoters does not block transcription. We investigated the kinetics of mRNA induction, demethylation, and remethylation of the p16 promoter and second-exon CpG islands in T24 cells after 5-aza-2'-deoxycytidine (5-Aza-CdR) treatment to explore the relationship between CpG island methylation and gene transcription. The rates of remethylation of both CpG islands were associated with time but not with the rate of cell division, and remethylation of the p16 exon 2 CpG island occurred at a higher rate than that of the p16 promoter. We also examined the relationship between the remethylation of coding sequence CpG islands and gene transcription. The kinetics of remethylation of the p16 exon 2, PAX-6 exon 5, c-ABL exon 11, and MYF-3 exon 3 loci were examined following 5-Aza-CdR treatment because these genes contain exonic CpG islands which are hypermethylated in T24 cells. Remethylation occurred most rapidly in the p16, PAX-6, and c-ABL genes, shown to be transcribed prior to drug treatment. These regions also exhibited higher levels of remethylation in single-cell clones and subclones derived from 5-Aza-CdR-treated T24 cells. Our data suggest that de novo methylation is not restricted to the S phase of the cell cycle and that transcription through CpG islands does not inhibit their remethylation.

The human DNA methyltransferases (DNMTs) 1, 3a and 3b: coordinate mRNA expression in normal tissues and overexpression in tumors.

DNA methylation in mammals is required for embryonic development, X chromosome inactivation and imprinting. Previous studies have shown that methylation patterns become abnormal in malignant cells and may contribute to tumorigenesis by improper de novo methylation and silencing of the promoters for growth-regulatory genes. RNA and protein levels of the DNA methyltransferase DNMT1 have been shown to be elevated in tumors, however murine stem cells lacking Dnmt1 are still able to de novo methylate viral DNA. The recent cloning of a new family of DNA methyltransferases (Dnmt3a and Dnmt3b) in mouse which methylate hemimethylated and unmethylated templates with equal efficiencies make them candidates for the long sought de novo methyltransferases. We have investigated the expression of human DNMT1, 3a and 3b and found widespread, coordinate expression of all three transcripts in most normal tissues. Chromosomal mapping placed DNMT3a on chromosome 2p23 and DNMT3b on chromosome 20q11.2. Significant overexpression of DNMT3b was seen in tumors while DNMT1 and DNMT3a were only modestly over-expressed and with lower frequency. Lastly, several novel alternatively spliced forms of DNMT3b, which may have altered enzymatic activity, were found to be expressed in a tissue-specific manner.

DNA methylation differences associated with tumor tissues identified by genome scanning analysis.

Most investigations on the role of DNA methylation in cancer have focused on epigenetic changes associated with known tumor suppressor genes. This may have led to an underestimation of the number of CpG islands altered by DNA methylation, since it is possible that a subset of unknown genes relevant to cancer development may preferentially be affected by epigenetic rather than genetic means and would not be identified as familial deletions, mutations, or loss of heterozygosity. We used a recently developed screening procedure (methylation-sensitive arbitrarily primed-polymerase chain reaction to scan genomic DNA for CpG islands methylated in white blood cells (WBCs) and in tumor tissues. DNA methylation pattern analysis showed little interindividual differences in the WBCs and normal epithelium (adjacent to colon, bladder, and prostate cancer cells), but with some tissue-specific differences. Cancer cells showed marked methylation changes that varied considerably between different tumors, suggesting variable penetrance of the methylation phenotype in patients. Direct sequencing of 8 of 45 bands altered in these cancers showed that several of them were CpG islands, and 2 of these sequences were identified in GenBank. Surprisingly, three of the bands studied corresponded to transcribed regions of genes. Thus, hypermethylation of CpG islands in cancer cells is not confined to the promoters of growth regulatory genes but is also found in actively transcribed regions.

The role of DNA methylation in expression of the p19/p16 locus in human bladder cancer cell lines.

Methylation of CpG sites in the control regions of tumor suppressor genes may be an important mechanism for their heritable, yet reversible, transcriptional inactivation. These changes in methylation may impair the proper expression and/or function of cell cycle regulatory genes and confer a selective growth advantage to affected cells. Detailed methylation analysis using genomic bisulfite sequencing was performed on a series of subclones of a bladder cancer cell line in which a hypermethylated p16 gene had been reactivated by transient treatment with 5-aza-2'-deoxycytidine. Methylation of the CpG island in the promoter of the p16 gene in human bladder cancer cells did not stop the formation of a transcript initiated 20 kb upstream by the p19 promoter but did prevent the expression of a p16 transcript. Furthermore, we show that reactivant clones that expressed p16 at varying levels contained heterogeneous methylation patterns, suggesting that p16 expression can occur even in the presence of a relatively heavily methylated coding region. We also present the first functional evidence that methylation of only a small number of CpG sites can significantly down-regulate p16 promoter activity, thus providing support for the model of progressive inactivation of this tumor suppressor gene by DNA methylation.

Progressive increases in the methylation status and heterochromatinization of the myoD CpG island during oncogenic transformation.

Alterations in DNA methylation patterns are one of the earliest and most common events in tumorigenesis. Overall levels of genomic methylation often decrease during transformation, but localized regions of increased methylation have been observed in the same tumors. We have examined changes in the methylation status of the muscle determination gene myoD, which contains a CpG island, as a function of oncogenic transformation. This CpG island underwent de novo methylation during immortalization of 10T1/2 cells, and progressively more sites became methylated during the subsequent transformation of the cells to oncogenicity. The greatest increase in methylation occurred in the middle of the CpG island in exon 1 during transformation. Interestingly, no methylation was apparent in the putative promoter of myoD in either the 10T1/2 cell line or its transformed derivative. The large number of sites in the CpG island that became methylated during transformation was correlated with heterochromatinization of myoD as evidenced by a decreased sensitivity to cleavage of DNA in nuclei by MspI. A site in the putative promoter also became insensitive to MspI digestion in nuclei, suggesting that the chromatin structural changes extended beyond the areas of de novo methylation. Unlike Lyonized genes on the inactive X chromosome, whose timing of replication is shifted to late S phase, myoD replicated early in S phase in the transformed cell line. Methylation analysis of myoD in DNAs from several human tumors, which presumably do not express the gene, showed that hypermethylation also frequently occurs during carcinogenesis in vivo. Thus, the progressive increase in methylation of myoD during immortalization and transformation coinciding with a change in chromatin structure, as illustrated by the in vitro tumorigenic model, may represent a common mechanism in carcinogenesis for permanently silencing the expression of genes which can influence cell growth and differentiation.

Activation of an imprinted Igf 2 gene in mouse somatic cell cultures.

The mouse insulin-like growth factor II gene (Igf 2), located on distal chromosome 7, is parentally imprinted such that the paternal allele is expressed while the maternal allele is transcriptionally silent. We derived a cell line from a mouse embryo maternally disomic and paternally deficient for distal chromosome 7 (MatDi7) to determine the stability of gene repression in culture. MatDi7 cells maintained Igf2 in a repressed state even after immortalization, except for one randomly picked clone which spontaneously expressed the gene. Igf 2 was expressed in a cell culture derived from a normal littermate; this expression was growth regulated, with Igf 2 mRNA levels increasing in the stationary phase of growth. Analysis of the methylation status of 28 sites distributed over 10 kb of the gene did not show consistent differences associated with expression level in the normal and MatDi7 cell lines, and the CpG island in the Igf 2 promoter remained unmethylated in all of the cell lines. Only with an oncogenically transformed cell line did the promoter become extensively methylated. We attempted to derepress the imprinted gene in MatDi7 cells by treatments known to alter gene expression. Expression of the Igf 2 allele in MatDi7 cells was increased in a dose-dependent manner by treatment with 5-aza-2'-deoxycytidine or bromodeoxyuridine, agents known to change DNA methylation patterns or chromatin conformation. Treatment of the cells with 1-beta-D-arabinofuranosylcytosine, 2'-deoxycytidine, calcium ionophore, heat shock, cold shock, or sodium butyrate did not result in increases in the levels of Igf 2 expression. It seems likely that the mechanism of the Igf 2 imprint involves subtle changes in the methylation or chromatin conformation of the gene which are affected by 5-aza-2'-deoxycytidine and bromodeoxyuridine.

Methylation of CpG-island-containing genes in human sperm, fetal and adult tissues.

The methylation of three human genes containing CpG islands and a CpG-depleted gene were measured in sperm, fetal and adult tissues. The c-Ha-ras was methylated extensively in the 3' region in sperm with a methylation-free region extending from the promoter to the third exon. The extent of methylation in the 3' region decreased in fetal cells, however, de novo methylation of sites closer to the island and within exon 1 were apparent. These sites were more completely methylated in adult lymphocytes and kidney. Essentially similar results were obtained with the CpG-island-containing genes, c-myc and HPRT (encoding hypoxanthine phosphoribosyl transferase), which showed that unmethylated sites near the CpG islands in sperm became methylated in fetal and adult cells. The variations in methylation seen in the non-island regions of the c-Ha-ras gene were mirrored in the insulin-encoding gene which does not contain a CpG island. The results show similar variations in methylation of non-island regions of DNA which occur independent of expression, and show that regions of extensive methylation in sperm may move closer to CpG islands in fetal and adult somatic cells.

De novo methylation of the MyoD1 CpG island during the establishment of immortal cell lines.

CpG dinucleotides are unevenly distributed in the vertebrate genome. Bulk DNA is depleted of CpGs and most of the cytosines in the dinucleotide in this fraction are methylated. On the other hand, CpG islands, which are often associated with genes, are unmethylated at testable sites in all normal tissues with the exception of genes on the inactive X chromosome. We used Hpa II/Msp I analysis and ligation-mediated polymerase chain reaction to examine the methylation of the MyoD1 CpG island in adult mouse tissues, early cultures of mouse embryo cells, and immortal fibroblastic cell lines. The island was almost devoid of methylation at CCGG sites in adult mouse tissues and in low-passage mouse embryo fibroblasts. In marked contrast, the island was methylated in 10T 1/2 cells and in six other immortal cell lines showing that methylation of this CpG island had occurred during escape from senescence. The island became even more methylated in chemically transformed derivatives of 10T 1/2 cells. Thus, CpG islands not methylated in normal tissues may become modified to an abnormally high degree during immortalization and transformation.

Preclinical evaluation of hematopoietic toxicity of antileukemic agent, 5-aza-2'-deoxycytidine.

The hematopoietic toxicity of 5-aza-2'-deoxycytidine (5-AZA-CdR), an experimental antileukemic agent, was investigated in mice and dogs. Mice were administered a 12 h intravenous infusion of 5-AZA-CdR at a total dose of 20 mg/kg and at different times after treatment samples of bone marrow were analyzed for cell count, DNA synthesis and colony-forming activity (CFUc). The 5-AZA-CdR treatment produced a marked decrease in femur cell count and CFUc activity with recovery occurring on days 8-14. DNA synthesis activity increased significantly during the recovery period. Dogs were also administered a 12 h intravenous infusion at doses 3-7 mg/kg and the blood hemogram evaluated. This treatment produced a pronounced leukopenia, granulocytopenia and thrombocytopenia with a nadir between days 7-16 with recovery occurring on days 19-21. These results indicate that 5-AZA-CdR produces marked hematopoietic toxicity in mice and dogs and this toxicity appears to be reversible under these experimental conditions.

DNA methylation in 5-aza-2'-deoxycytidine-resistant variants of C3H 10T1/2 C18 cells.

A cell line (T17) was derived from C3H 10T1/2 C18 cells after 17 treatments with increasing concentrations of 5-aza-2'-deoxycytidine. The T17 cell line was very resistant to the cytotoxic effects of 5-aza-2'-deoxycytidine, and the 50% lethal dose for 5-aza-2'-deoxycytidine was ca. 3 microM, which was 30-fold greater than that of the parental C3H 10T1/2 C18 cells. Increased drug resistance was not due to a failure of the T17 cell line to incorporate 5-aza-2'-deoxycytidine into DNA. The cells were also slightly cross-resistant to 5-azacytidine. The percentage of cytosines modified to 5-methylcytosine in T17 cells was 0.7%, a 78% decrease from the level of 3.22% in C3H 10T1/2 C18 cells. The DNA cytosine methylation levels in several clones isolated from the treated lines were on the order of 0.7%, and clones with methylation levels lower than 0.45% were not obtained even after further drug treatments. These highly decreased methylation levels appeared to be unstable, and DNA modification increased as the cells divided in the absence of further drug treatment. The results suggest that it may not be possible to derive mouse cells with vanishingly low levels of 5-methylcytosine and that considerable de novo methylation can occur in cultured lines.

The role of lipids and glycerol in determining the shelf-life of glycerol desorbed intermediate moisture meat products.

During storage of glycerol desorbed intermediate moisture beef at 38°C the marked loss of eating quality, demonstrated by increasing loss of nitrogen solubility in sodium dodecyl sulphate (SDS) plus ß-mercaptoethanol, loss of haemoprotein character, decrease in pH and the formation of water-soluble hydroxyproline containing fragments, is not markedly affected by the presence of oleic acid and/or butylated hydroxytoluene. In addition, gas-liquid chromatographic analysis of the lipid fractions suggests that, in these meats, the relative composition of the neutral phospholipid fractions does not change to any marked extent during storage. However, the TBA and peroxide values, which are very high in the freshly prepared meats, do decrease quite markedly during storage. Consideration of these results suggests that, in glycerol desorbed meats, glycerol oxidation products are the major reactants leading to loss of eating quality.