John R. Melki

Identification and resolution of artifacts in bisulfite sequencing

Bisulfite sequencing has become the most widely used application to detect 5-methylcytosine (5-MeC) in DNA, and provides a reliable way of detecting any methylated cytosine at single-molecule resolution in any sequence context. The process of bisulfite treatment exploits the different sensitivity of cytosine and 5-MeC to deamination by bisulfite under acidic conditions, in which cytosine undergoes conversion to uracil while 5-MeC remains unreactive. In this article, we address the more commonly encountered experimental artifacts associated with bisulfite sequencing, and provide methods for the detection and elimination of these artifacts. In particular, we focus on conditions that inhibit complete bisulfite-mediated conversion of cytosines in a target sequence, and demonstrate the necessity of complete protein removal from DNA samples prior to bisulfite treatment. We also include a brief summary of the experimental protocol for bisulfite treatment and tips for designing polymerase chain reaction (PCR) primers to amplify from bisulfite-treated DNA.

DNA methylation and gene silencing in cancer: which is the guilty party?

The DNA methylation pattern of a cell is exquisitely controlled during early development resulting in distinct methylation patterns. The tight control of DNA methylation is released in the cancer cell characterized by a reversal of methylation states. CpG island associated genes, in particular tumour suppressor or related genes, are often hypermethylated and this is associated with silencing of these genes. Therefore methylation is commonly convicted as a critical causal event in silencing this important class of genes in cancer. In this review, we argue that methylation is not the initial guilty party in triggering gene silencing in cancer, but that methylation of CpG islands is a consequence of prior gene silencing, similar to the role of methylation in maintaining the silencing of CpG island genes on the inactive X chromosome. We propose that gene silencing is the critical precursor in cancer, as it changes the dynamic interplay between de novo methylation and demethylation of the CpG island and tilts the balance to favour hypermethylation and chromatin inactivation.

Hypermethylation trigger of the glutathione-S-transferase gene (GSTP1) in prostate cancer cells

Understanding what triggers hypermethylation of tumour suppressor genes in cancer cells is critical if we are to discern the role of methylation in the oncogenic process. CpG sites in CpG island promoters, that span most tumour suppressor genes, remain unmethylated in the normal cell, despite the fact that CpG sites are the prime target for de novo methylation by the DNA methyltransferases. The CpG island-associated with the GSTP1 gene is an intriguing example of a CpG rich region which is susceptible to hypermethylation in the majority of prostate tumours and yet is unmethylated in the normal prostate cell. In this study we evaluate a number of factors purported to be involved in hypermethylation to test their role in triggering hypermethylation of GSTP1 in prostate cancer DU145 and LNCaP cells. We find that hypermethylation is not associated with (1) elevated expression of the DNA methyltranferases, or (2) removal of Sp1 transcription factor binding sites in the CpG island or (3) removal of CpG island boundary elements or (4) prior gene silencing. Instead our results support a model that requires a combination of prior gene silencing and random ‘seeds’ of methylation to trigger hypermethylation of the GSTP1 gene in the prostate cancer cell. We propose that the GSTP1 gene is initially silenced in the prostate cancer and random sites of methylation accumulate that result in subsequent hypermethylation and chromatin remodelling.

Genetic and epigenetic instability of human bone marrow mesenchymal stem cells expanded in autologous serum or fetal bovine serum

Culture of mesenchymal stem cells (MSCs) under conditions promoting proliferation and differentiation, while supporting genomic and epigenetic stability, is essential for therapeutic use. We report here the extent of genome-wide DNA gains and losses and of DNA methylation instability on 170 cancer-related promoters in bone marrow (BM) MSCs during culture to late passage in medium containing fetal bovine serum (FBS) or autologous serum (AS). Comparative genomic hybridization indicates that expansion of BMMSCs elicits primarily telomeric deletions in a subpopulation of cells, the extent of which varies between donors. However, late passage cultures in AS consistently display normal DNA copy numbers. Combined bisulfite restriction analysis and bisulfite sequencing show that although DNA methylation states are overall stable in culture, AS exhibits stronger propensity than FBS to maintain unmethylated states. Comparison of DNA methylation in BMMSCs with freshly isolated and cultured adipose stem cells (ASCs) also reveals that most genes unmethylated in both BMMSCs and ASCs in early passage are also unmethylated in uncultured ASCs. We conclude that (i) BMMSCs expanded in AS or FBS may display localized genetic alterations, (ii) AS tends to generate more consistent genomic backgrounds and DNA methylation patterns, and (iii) the unmethylated state of uncultured MSCs is more likely to be maintained in culture than the methylated state.

Increased DNA methyltransferase expression in leukaemia

Aberrant DNA methylation has been observed consistently in many human tumours, in particular in the CpG islands of tumour suppressor genes, but the underlying mechanism of these changes remains unclear. To determine whether DNA methyltransferase expression is increased in leukaemia, we developed a standarised competitive RT-PCR assay to measure the level of DNA methyltransferase transcripts. Using this assay on bone marrow RNA samples from 12 patients with acute leukaemia, we observed a 4.4-fold mean increase in the level of DNA methyltransferase mRNA compared with normal bone marrow. These results support but do not prove the hypothesis that an increase in DNA methyltransferase activity is associated with malignant haematological diseases and may constitute a key step in carcinogenesis.

Methylation sequencing from limiting DNA: embryonic, fixed, and microdissected cells.

It is frequently useful to determine the methylation state of samples containing limited amounts of DNA such as from embryos, or from fixed tissue samples in which DNA is degraded or difficult to isolate. By modification of the standard protocols for DNA preparation and bisulfite treatment, it is possible to obtain DNA methylation sequence data for such samples. We present methods for bisulfite treatment of embryos, fixed sections, and samples obtained by laser capture microdissection, and discuss the additional experimental considerations required when working with small numbers of cells or degraded DNA samples.

DNA methylation changes in leukaemia

Leukaemogenesis is a multi-step process whereby a clonal population arises that has undergone successive alterations to the genotype and the phenotype of the cells that make up the clone. Leukaemia has traditionally been viewed as a genetic disease, however epigenetic defects also play an important role. Expression of the DNA methyltransferase enzymes is elevated in leukaemia, and aberrant methylation is common with both a decrease in the total genomic 5-methylcytosine, and a concomitant hypermethylation of CpG island-associated tumour suppressor genes. This review will discuss the multitude of DNA methylation changes in haematopoietic malignancies and the implications they have for diagnosis and treatment.

Cancer-specific region of hypermethylation identified within the HIC1 putative tumour suppressor gene in acute myeloid leukaemia

Abnormal DNA methylation has been found to be a common feature in cancer cells, although the mechanism of this alteration remains poorly understood. HIC1 is a putative tumour suppressor gene on chromosome 17p13.3 and is hypermethylated in a number of cancers including leukaemia. In this study, using bisulphite genomic sequencing, we have identified a ‘boundary’ sequence within the HIC1 CpG island that shows a marked junction between methylated and unmethylated DNA in normal haematopoietic cells. Surprisingly, this boundary of differential methylation lies exactly between the intron 2 and exon 3 junction. In contrast to normal haematopoietic cells, hypermethylation extends past this boundary at a high frequency (83%) in newly diagnosed acute myeloid leukaemias (AML). Identification of the hypermethylated boundary sequence not only provides the first step in understanding the mechanisms that normally protect CpG islands from de novo methylation but also may prove to be a useful cancer- specific marker.

Alterations in the p16INK4a and p53 tumor suppressor genes of hTERT-immortalized human fibroblasts

Exogenous expression of the catalytic subunit of telomerase, hTERT, in a normal human foreskin fibroblast cell strain resulted in telomerase activity and an extended proliferative lifespan prior to a period of crisis. Three immortalized cell lines with stably maintained telomere lengths were established from cells that escaped crisis. Each of these cultures underwent a significant downregulation of p16INK4a expression due to gene deletion events. One cell line also acquired mutations in both alleles of the p53 tumor suppressor gene. Downregulation of p16INK4a and loss of wild-type p53 expression occurred after escape from crisis, so these mutations are most likely not required for immortalization of these cells but rather were selected for during continuous growth in vitro. These findings emphasize the need for caution in the use of hTERT-immortalized cells in studies of normal cell biology or in tissue engineering and the need to monitor for genetic instability and the accumulation of mutations in both the p16INK4a/pRb and p53 pathways.

Comparison of a novel HPV test with the Hybrid Capture II (hcII) and a reference PCR method shows high specificity and positive predictive value for 13 high-risk human papillomavirus infections.

BACKGROUND It is well established that human papillomavirus (HPV) infection is highly related to the development of precursor lesions of cervical cancer and uterine cancers. However, for a pre-cancerous lesion to develop, a persistent infection with a high-risk type HPV is necessary. The Digene Hybrid Capture II (hcII) assay is the only FDA approved method used in conjunction with cytology for HPV screening of women older than 30. The hcII has moderate sensitivity (64.7%) and is dependent on the cellular content of samples, rendering occasionally false positive and false negative results. OBJECTIVE This study aims to evaluate the performance of a new HPV diagnostic kit (High-Risk HPV detection kit, manufactured by Human Genetic Signatures (HGS), Sydney, Australia). METHODS The method under evaluation was assessed by comparing the results obtained from testing 834 cervical specimens with the HGS method and the Digene hcII method, using genotyping as the reference standard. RESULTS Results of the study showed that the specificity and positive predictive value of the HGS High-Risk HPV detection test are significantly greater than those of the Digene hcII test. Overall the HGS HPV assay provides a more accurate system for the detection of high-risk HPV strains, with simpler technical use compared with PCR-sequencing methods.