Tissue specificity of methylation and expression of human genes coding for neuropeptides and their receptors, and of a human endogenous retrovirus K family

Retrotransposon hypomethylation in melanoma and expression of a placenta-specific gene

In the human placenta, DNA hypomethylation permits the expression of retrotransposon-derived genes that are normally silenced by methylation in somatic tissues. We previously identified hypomethylation of a retrotransposon-derived transcript of the voltage-gated potassium channel gene KCNH5 that is expressed only in human placenta. However, an RNA sequence from this placental-specific transcript has been reported in melanoma. This study examined the promoter methylation and expression of the retrotransposon-derived KCNH5 transcript in 25 melanoma cell lines to determine whether the acquisition of 'placental' epigenetic marks is a feature of melanoma. Methylation and gene expression analysis revealed hypomethylation of this retrotransposon in melanoma cell lines, particularly in those samples that express the placental KCNH5 transcript. Therefore we propose that hypomethylation of the placental-specific KCNH5 promoter is frequently associated with KCNH5 expression in melanoma cells. Our findings show that melanoma can develop hypomethylation of a retrotransposon-derived gene; a characteristic notably shared with the normal placenta.

DRD2 and PPP1R1B (DARPP-32) polymorphisms independently confer increased risk for autism spectrum disorders and additively predict affected status in male-only affected sib-pair families

Background

The neurotransmitter dopamine (DA) modulates executive functions, learning, and emotional processing, all of which are impaired in individuals with autism spectrum disorders (ASDs). Our previous findings suggest a role for dopamine-related genes in families with only affected males.

Methods

We examined two additional genes which affect DA function, the DRD2 and PPP1R1B (DARPP-32) genes, in a cohort of 112 male-only affected sib-pair families. Selected polymorphisms spanning these genes were genotyped and both family-based and population-based tests were carried out for association analysis. General discriminant analysis was used to examine the gene-gene interactions in predicting autism susceptibility.

Results

There was a significantly increased frequency of the DRD2 rs1800498TT genotype (P = 0.007) in affected males compared to the comparison group, apparently due to over-transmission of the T allele (P = 0.0003). The frequency of the PPP1R1B rs1495099CC genotype in affected males was also higher than that in the comparison group (P = 0.002) due to preferential transmission of the C allele from parents to affected children (P = 0.0009). Alleles rs1800498T and rs1495099C were associated with more severe problems in social interaction (P = 0.0002 and P = 0.0016, respectively) and communication (P = 0.0004 and P = 0.0046), and increased stereotypic behaviours (P = 0.0021 and P = 0.00072). General discriminant analysis found that the DRD2 and PPP1R1B genes additively predicted ASDs (P = 0.00011; Canonical R = 0.26) and explain ~7% of the variance in our families. All findings remained significant following corrections for multiple testing.

Conclusion

Our findings support a role for the DRD2 and PPP1R1B genes in conferring risk for autism in families with only affected males and show an additive effect of these genes towards prediction of affected status in our families.

DNA methylation profiling highlights the unique nature of the human placental epigenome

As the 'gateway' to the fetus, the placenta is subject to a myriad of environmental factors, each with the potential to alter placental epigenetic and gene expression profile. This can have direct consequences for the developing fetus and potentially even long-term health implications. As a result, interest in placental epigenetics generally, and changes occurring in placenta-associated disease, has intensified over recent years. This article will discuss the general features of placental DNA methylation and will describe current technologies for profiling genome-wide DNA methylation patterns in this tissue, the approaches to data analysis and some of the major findings from recent studies.

Differential methylation of imprinted genes in growth-restricted placentas

A complex network of epigenetic factors participates in regulating the monoallelic expression of a small subset of genes (~1%) in the human genome. This phenomenon goes under the definition of genomic imprinting, a parent-of-origin effect that, when altered during early embryogenesis, may influence fetal development into adulthood. Pertubations in genomic imprinting have been associated with placental and fetal growth restrictions. We analyzed the differential DNA methylation of all known imprinted genes on 10 appropriate-for-gestational-age, clinically normal, placentas and 7 severe intrauterine growth-restricted placentas. Samples were pooled according to the diagnosis and analyzed by methylated DNA immunoprecipitation (MeDIP) on a tiling microarray platform. The distribution of the differentially methylated regions (DMRs) identified in growth-restricted placentas showed a slight tendency toward hypermethylation. Imprinted genes not expressed in placenta showed a unique DMR profile with the fewest hyper- and hypomethylated DMRs. Promoter and CpG island DMRs were sporadic and randomly distributed. The vast majority of DMR identified (~99%) were mapped in introns, showing no common sequence features. Also, by using the more advanced array data mining softwares, no significant patterns emerged. In contrast, differential methylation showed a highly significant correlation with gene length. Overall these data suggest that differential methylation changes in growth-restricted placentas occur throughout the genomic regions, encompassing genes actively expressed in the placenta. These findings warrant caution in interpreting the significance of genes carrying clustered DMRs because the distribution of DMRs in a gene may be attributed as a function of its length rather than as a specific biological role.

Regulation of human endogenous retrovirus-K expression in melanomas by CpG methylation

The overall prognosis of patients with advanced melanoma is poor due to the lack of effective treatment. A key factor for successful therapy is an early detection of disease. Therefore, reliably detection methods and meaningful tumor markers are required. Expression of the human endogenous retrovirus (HERV)-K(HML-2) was found elevated in melanomas and it was shown that HERV-K supports the in vitro transition of melanoma cells from adherent to a more malignant, nonadherent phenotype. Furthermore, the detection of HERV-K-specific antibodies in melanoma patients was found to correlate with reduced survival. However, the reason for HERV-K expression in melanomas still remains unclear and its use as a tumor marker needs further investigation. Therefore, the tumor-specific transcriptional regulation of HERV-K expression in melanoma was studied in detail. Human melanoma cell lines were investigated for HERV-K expression using real-time PCR. Five cell lines showed very high levels of HERV-K mRNA as a result of increased promoter activity. This promoter activity was directly silenced by DNA methylation in reporter gene experiments. Higher levels of long terminal repeat (LTR) methylation in cells not expressing HERV-K compared with cells expressing HERV-K were found using methylation-sensitive PCR and bisulfite sequencing. Treatment of cell lines with the demethylating agent 5-aza-2'-deoxycytidine resulted in increased levels of HERV-K expression in cells previously not expressing HERV-K and it was shown that this increase is not the result of transcription factor activation. These results demonstrate that increased HERV-K expression in melanomas may be due to increased promoter activity and demethylation of the 5'LTR.

Inactive X chromosome-specific reduction in placental DNA methylation

Genome-wide levels of DNA methylation vary between tissues, and compared with other tissues, the placenta has been reported to demonstrate a global decrease in methylation as well as decreased methylation of X-linked promoters. Methylation is one of many features that differentiate the active and inactive X, and it is well established that CpG island promoters on the inactive X are hypermethylated. We now report a detailed analysis of methylation at different regions across the X in male and female placenta and blood. A significant (P < 0.001) placental hypomethylation of LINE1 elements was observed in both males and females. Relative to blood placental promoter hypomethylation was only observed for X-linked, not autosomal promoters, and was significant for females (P < 0.0001) not males (P = 0.9266). In blood, X-linked CpG island promoters were shown to have moderate female methylation (66% across 70 assays) and low (23%) methylation in males. A similar methylation pattern in blood was observed for approximately 20% of non-island promoters as well as 50% of the intergenic or intragenic CpG islands, the latter is likely due to the presence of unannotated promoters. Both intragenic and intergenic regions showed similarly high methylation levels in male and female blood (68 and 66%) while placental methylation of these regions was lower, particularly in females. Thus placental hypomethylation relative to blood is observed globally at repetitive elements as well as across the X. The decrease in X-linked placental methylation is consistently greater in females than males and implicates an inactive X specific loss of methylation in the placenta.

Developmentally regulated extended domains of DNA hypomethylation encompass highly transcribed genes of the human beta-globin locus

OBJECTIVE

DNA methylation has long been implicated in developmental beta-globin gene regulation. However, the mechanism underlying this regulation is unclear, especially because these genes do not contain CpG islands. This has led us to propose and test the hypothesis that, just as for histone modifications, developmentally specific changes in human beta-like globin gene expression are associated with long-range changes in DNA methylation.

MATERIALS AND METHODS

Bisulfite sequencing was used to determine the methylation state of individual CpG dinucleotides across the beta-globin locus in uncultured primary human erythroblasts from fetal liver and bone marrow, and in primitive-like erythroid cells derived from human embryonic stem cells.

RESULTS

beta-globin locus CpGs are generally highly methylated, but domains of DNA hypomethylation spanning thousands of base pairs are established around the most highly expressed genes during each developmental stage. These large domains of DNA hypomethylation are found within domains of histone modifications associated with gene expression. We also find hypomethylation of a small proportion of gamma-globin promoters in adult erythroid cells, suggesting a mechanism by which adult erythroid cells produce fetal hemoglobin.

CONCLUSION

This is one of the first reports to show that changes in DNA methylation patterns across large domains around non-CpG island genes correspond with changes in developmentally regulated histone modifications and gene expression. These data support a new model in which extended domains of DNA hypomethylation and active histone marks are coordinately established to achieve developmentally specific gene expression of non-CpG island genes.

A DRD1 haplotype is associated with risk for autism spectrum disorders in male-only affected sib-pair families

Individuals with autism spectrum disorders (ASDs) have impairments in executive function and social cognition, with males generally being more severely affected in these areas than females. Because the dopamine D1 receptor (encoded by DRD1) is integral to the neural circuitry mediating these processes, we examined the DRD1 gene for its role in susceptibility to ASDs by performing single marker and haplotype case-control comparisons, family-based association tests, and genotype-phenotype assessments (quantitative transmission disequilibrium tests: QTDT) using three DRD1 polymorphisms, rs265981C/T, rs4532A/G, and rs686T/C. Our previous findings suggested that the dopaminergic system may be more integrally involved in families with affected males only than in other families. We therefore restricted our study to families with two or more affected males (N = 112). There was over-transmission of rs265981-C and rs4532-A in these families (P = 0.040, P = 0.038), with haplotype TDT analysis showing over-transmission of the C-A-T haplotype (P = 0.022) from mothers to affected sons (P = 0.013). In addition, haplotype case-control comparisons revealed an increase of this putative risk haplotype in affected individuals relative to a comparison group (P = 0.004). QTDT analyses showed associations of the rs265981-C, rs4532-A, rs686-T alleles, and the C-A-T haplotype with more severe problems in social interaction, greater difficulties with nonverbal communication and increased stereotypies compared to individuals with other haplotypes. Preferential haplotype transmission of markers at the DRD1 locus and an increased frequency of a specific haplotype support the DRD1 gene as a risk gene for core symptoms of ASD in families having only affected males.

Placenta-restricted expression of LTR-derived NOS3

Domestication events of long terminal repeat (LTR) sequences of the human endogenous retrovirus (HERV) family have been considered to be a new mechanism for the generation of alternative splicing in the human genome. We investigated an LTR10A belonging to the HERV-I family at the human endothelial nitric oxide synthase (NOS3) gene locus. The LTR10A element was located upstream of the original promoter sequences of NOS3. Expression analysis using RT-PCR and reporter gene assays in HCT116 and COS7 cells indicated placenta-specific expression of NOS3 driven by the LTR10A-derived promoter. The placenta-restricted expression was also determined to be associated with hypomethylation of the LTR10A element by methylation analysis using sodium bisulfite DNA sequencing. Furthermore, treatment of brain-derived cell lines with demethylation reagents did not restore expression of the LTR-derived NOS3 gene transcript. Taken together, the integration event of an LTR10A element in the upstream region of NOS3 led to the generation of a placenta-specific alternative transcript governed by cooperative mechanisms of epigenetic control (DNA methylation) and transcriptional regulation (interaction between cis- and trans-acting elements).

Global hypomethylation of peripheral leukocyte DNA in male patients with schizophrenia: a potential link between epigenetics and schizophrenia

Genetic and epigenetic factors can potentially alter susceptibility to psychiatric disorders such as schizophrenia. In order to explore the effect of epigenetics on the pathogenesis of schizophrenia, we examined the global methylation level of leukocyte DNA from 210 patients with schizophrenia (124 males and 86 females) and 237 healthy subjects (108 males and 129 females). Methylated deoxycytidine (mC) content in peripheral leukocyte DNA was measured by high performance liquid chromatography (HPLC). We confirmed in the healthy subjects our previous finding that there are sex-dependent differences in mC content (males>females; beta=0.319, p<0.001), in addition to the effect of age (beta=-0.141, p=0.022). We therefore used multiple regression to analyze the data from all subjects by sex, with age as a co-variant. In males, a tendency was observed toward lower mC content in patients than in controls (beta=-0.115, p=0.075), with a significant effect of age (beta=-0.212, p<0.001). This difference was more prominent in younger individuals. In females, no effect of age or disease status on mC content was observed. These results established that there is significant sex-dependent difference in the mC content of human peripheral leukocyte DNA, and raise the possibility that alterations in DNA methylation state are present in patients with schizophrenia.