Genomic imprinting proposed as a surveillance mechanism for chromosome loss

Imprinting as Basis for Complex Evolutionary Novelties in Eutherians

The epigenetic phenomenon of genomic imprinting is puzzling. While epigenetic modifications in general are widely known in most species, genomic imprinting in the animal kingdom is restricted to autosomes of therian mammals, mainly eutherians, and to a lesser extent in marsupials. Imprinting causes monoallelic gene expression. It represents functional haploidy of certain alleles while bearing the evolutionary cost of diploidization, which is the need of a complex cellular architecture and the danger of producing aneuploid cells by mitotic and meiotic errors. The parent-of-origin gene expression has stressed many theories. Most prominent theories, such as the kinship (parental conflict) hypothesis for maternally versus paternally derived alleles, explain only partial aspects of imprinting. The implementation of single-cell transcriptome analyses and epigenetic research allowed detailed study of monoallelic expression in a spatial and temporal manner and demonstrated a broader but much more complex and differentiated picture of imprinting. In this review, we summarize all these aspects but argue that imprinting is a functional haploidy that not only allows a better gene dosage control of critical genes but also increased cellular diversity and plasticity. Furthermore, we propose that only the occurrence of allele-specific gene regulation mechanisms allows the appearance of evolutionary novelties such as the placenta and the evolutionary expansion of the eutherian brain.

Genome-wide CpG island methylation and intergenic demethylation propensities vary among different tumor sites

The epigenetic landscape of cancer includes both focal hypermethylation and broader hypomethylation in a genome-wide manner. By means of a comprehensive genomic analysis on 6637 tissues of 21 tumor types, we here show that the degrees of overall methylation in CpG island (CGI) and demethylation in intergenic regions, defined as ‘backbone’, largely vary among different tumors. Depending on tumor type, both CGI methylation and backbone demethylation are often associated with clinical, epidemiological and biological features such as age, sex, smoking history, anatomic location, histological type and grade, stage, molecular subtype and biological pathways. We found connections between CGI methylation and hypermutability, microsatellite instability, IDH1 mutation, 19p gain and polycomb features, and backbone demethylation with chromosomal instability, NSD1 and TP53 mutations, 5q and 19p loss and long repressive domains. These broad epigenetic patterns add a new dimension to our understanding of tumor biology and its clinical implications.

DNA demethylation and invasive cancer: implications for therapeutics

One of the hallmarks of cancer is aberrant DNA methylation, which is associated with abnormal gene expression. Both hypermethylation and silencing of tumour suppressor genes as well as hypomethylation and activation of prometastatic genes are characteristic of cancer cells. As DNA methylation is reversible, DNA methylation inhibitors were tested as anticancer drugs with the idea that such agents would demethylate and reactivate tumour suppressor genes. Two cytosine analogues, 5-azacytidine (Vidaza) and 5-aza-2'-deoxycytidine, were approved by the Food and Drug Administration as antitumour agents in 2004 and 2006 respectively. However, these agents might cause activation of a panel of prometastatic genes in addition to activating tumour suppressor genes, which might lead to increased metastasis. This poses the challenge of how to target tumour suppressor genes and block cancer growth with DNA-demethylating drugs while avoiding the activation of prometastatic genes and precluding the morbidity of cancer metastasis. This paper reviews current progress in using DNA methylation inhibitors in cancer therapy and the potential promise and challenges ahead.

B chromosome and NORs polymorphism in Callichthys callichthys (Linnaeus, 1758) (Siluriformes: Callichthyidae) from upper Paraná River, Brazil

B chromosomes are extra chromosomes from the normal chromosomal set, found in different organisms, highlighting their presence on the group of fishes. Callichthys callichthys from the upper Paraná River has a diploid number of 56 chromosomes (26 m-sm + 30 st-a) for both sexes, with the presence of a sporadically acrocentric B chromosome. Moreover, one individual presented a diploid number of 57 chromosomes, with the presence of a morphologically ill-defined acrocentric B chromosome in all analyzed cells. The physical mapping of 5S and 18S rDNA shows multiple 5S rDNA sites and only one pair of chromosomes with 18S sites in C. callichthys, except for two individuals. These two individuals presented a third chromosome bearing NORs (Ag-staining and 18S rDNA) where 5S and 18S rDNA genes are syntenic, differing only in position. The dispersion of the 18S rDNA genes from the main st-achromosome pair 25 to one of the chromosomes from the m-sm pair 4 would have originated two variant individuals, one of which with the ill-defined acrocentric B chromosome. Mechanisms to justify the suggested hypothesis about this B chromosome origin are discussed in the present study.

Epigenetics and colorectal cancer pathogenesis

Colorectal cancer (CRC) develops through a multistage process that results from the progressive accumulation of genetic mutations, and frequently as a result of mutations in the Wnt signaling pathway. However, it has become evident over the past two decades that epigenetic alterations of the chromatin, particularly the chromatin components in the promoter regions of tumor suppressors and oncogenes, play key roles in CRC pathogenesis. Epigenetic regulation is organized at multiple levels, involving primarily DNA methylation and selective histone modifications in cancer cells. Assessment of the CRC epigenome has revealed that virtually all CRCs have aberrantly methylated genes and that the average CRC methylome has thousands of abnormally methylated genes. Although relatively less is known about the patterns of specific histone modifications in CRC, selective histone modifications and resultant chromatin conformation have been shown to act, in concert with DNA methylation, to regulate gene expression to mediate CRC pathogenesis. Moreover, it is now clear that not only DNA methylation but also histone modifications are reversible processes. The increased understanding of epigenetic regulation of gene expression in the context of CRC pathogenesis has led to development of epigenetic biomarkers for CRC diagnosis and epigenetic drugs for CRC therapy.

The negative correlation between somatic aneuploidy and growth in the oysterCrassostrea gigasand implications for the effects of induced polyploidization

This study extends previous observations that chromosome loss in somaticcells of juveniles of the pacific oysterCrassostrea gigasis associated with reduced growth rate. All four studies designed to examine this association (two usingrandom population samples and two using full sibs) produced the same result. This consistent effect appears to be unrelated with the commonly, but not consistently, observed correlation between degree of allozyme heterozygosity and growth. We propose thatthe inverse relationship between aneuploidy and growth is due to the unmasking of deleterious recessive genes caused by ‘progressive haploidization’ of somatic cells. Because unmasking of deleterious recessive genes by random chromosome lossisunlikely in polyploid cells, this hypothesis may also provide an explanation for theobservation that artificially produced polyploid shellfish usually grow at faster rates than normal diploid ones.

Genomic imprinting and dermatological disease

Imprinting is the process whereby genetic alleles responsible for a phenotype are derived from one parent only. It is an epigenetic phenomenon resulting from DNA methylation or modification of protruding histones. When imprinted genes are disrupted, syndromes with characteristic patterns of inheritance and multisystem phenotype occur. Those detailed in this article have some quite characteristic cutaneous features and patterns of inheritance. These diseases include Beckwith-Wiedmann, Silver-Russell, Prader-Willi, McCune-Albright and Angelman syndromes, Albright's hereditary osteodystrophy, and progressive osseous heteroplasia. In the case of Von Hippel-Lindau syndrome, hypomelanosis of Ito and dermatopathia pigmentosa reticularis, imprinting may play a part in the inheritance. With neurofibromatosis type 1, a nonimprinted condition, the expression of the phenotype could be affected by interaction with imprinted gene loci. Imprinted genes could also play a part in the polygenetic inheritance of more common diseases also, as atopic eczema and psoriasis may have predominantly maternal and paternal modes of transmission, respectively.

Chromatin elimination--an oddity or a common mechanism in differentiation and development?

Over many decades, a great number of exceptions from the rule of equal segregation of the chromosomes during cell division have been found in different animal species. The most diversified is the process of chromosome re-arrangement that takes place during the specification of soma versus germ-line cell fate in the embryos from the whole spectrum of animal phyla. In nematodes, copepodes, insects, hagfish, and marsupials, the chromatin/chromosome elimination is a common path of normal cell differentiation and development. This also raises the question of the mechanisms and factors that promote elimination in pre-somatic cell lines and/or inhibit the elimination in the prospective germ cells. We will discuss the possible role of the germ plasm in this process.

Methylation and colorectal cancer

Statistics rate colorectal adenocarcinoma as the most common cause of cancer death on exclusion of smoking-related neoplasia. However, the reported accumulation of genetic lesions over the adenoma to adenocarcinoma sequence cannot wholly account for the neoplastic phenotype. Recently, heritable, epigenetic changes in DNA methylation, in association with a repressive chromatin structure, have been identified as critical determinants of tumour progression. Indeed, the transcriptional silencing of both established and novel tumour suppressor genes has been attributed to the aberrant cytosine methylation of promoter-region CpG islands. This review aims to set these epigenetic changes within the context of the colorectal adenoma to adenocarcinoma sequence. The role of cytosine methylation in physiological and pathological gene silencing is discussed and the events behind aberrant cytosine methylation in ageing and cancer are appraised. Emphasis is placed on the interrelationships between epigenetic and genetic lesions and the manner in which they cooperate to define a CpG island methylator phenotype at an early stage in tumourigenesis. Finally, the applications of epigenetics to molecular pathology and patient diagnosis and treatment are reviewed.

Maternal origin of a unique extra chromosome, der(9)(pter-->q13::q13-->q12:) in a girl with typical trisomy 9p syndrome

We report on a girl with the typical trisomy 9p syndrome who had an additional E-sized metacentric chromosome. On the basis of GTG- and CBG-banding, her karyotype was considered to be 47,XX,+der(9)(pter-->q13::q13-->q12:) de novo. Results of a fluorescence in situ hybridization study using a chromosome 9-specific painting probe were compatible with this cytogenetic interpretation. Molecular analyses of six highly polymorphic dinucleotide repeat loci on the short arm and the proximal long arm of chromosome 9 demonstrated that the girl inherited one allele from her father and two identical or different alleles from the mother. We speculated that the extra chromosome may have resulted from either nondisjunction of chromosome 9 followed by a U-type exchange and a crossing-over between different sister chromatids during maternal meiosis I and subsequent breakage and malsegregation during meiosis II, or nondisjunction during meiosis II followed by isochromosome formation in one of the two maternal chromosomes 9 and subsequent breakage.

Imprinted genes as potential genetic and epigenetic toxicologic targets

Genomic imprinting is an epigenetic phenomenon in eutherian mammals that results in the differential expression of the paternally and maternally inherited alleles of a gene. Imprinted genes are necessary for normal mammalian development. This requirement has been proposed to have evolved because of an interparental genetic battle for the utilization of maternal resources during gestation and postnatally. The nonrandom requisite for monoallelic expression of a subset of genes has also resulted in the formation of susceptibility loci for neurobehavioral disorders, developmental disorders, and cancer. Since imprinting involves both cytosine methylation within CpG islands and changes in chromatin structure, imprinted genes are potential targets for dysregulation by epigenetic toxicants that modify DNA methylation and histone acetylation.

B-chromosome evolution

B chromosomes are extra chromosomes to the standard complement that occur in many organisms. They can originate in a number of ways including derivation from autosomes and sex chromosomes in intra- and interspecies crosses. Their subsequent molecular evolution resembles that of univalent sex chromosomes, which involves gene silencing, heterochromatinization and the accumulation of repetitive DNA and transposons. B-chromosome frequencies in populations result from a balance between their transmission rates and their effects on host fitness. Their long-term evolution is considered to be the outcome of selection on the host genome to eliminate B chromosomes or suppress their effects and on the B chromosome's ability to escape through the generation of new variants. Because B chromosomes interact with the standard chromosomes, they can play an important role in genome evolution and may be useful for studying molecular evolutionary processes.

CpG methylation reduces genomic instability

Hypomethylation of DNA in tumor cells is associated with genomic instability and has been suggested to be due to activation of mitotic recombination. We have studied the methylation patterns in two 650 kb double minute chromosomes present in two mouse tumor cell lines, resistant to methotrexate. Multiple copies of the double minute chromosomes amplifying the dihydrofolate reductase gene are present in both the cell lines. In one of the cell lines (Mut F), two unmethylated CpG islands in the double minute chromosomes are readily cleaved by methylation-sensitive rare-cutting restriction endonucleases. In the other cell line (Mut C), the cleavage sites in the double minute chromosomes are partially methylated and resistant to cleavage. The double minute chromosomes with the two unmethylated CpG islands undergo rapid dimerization, whereas the double minute chromosomes with the partially methylated CpG islands are unchanged in size for over a year in continuous culture. The partially methylated CpG islands can be demethylated by azacytidine treatment or naturally by extended time in culture, and become sensitive to cleavage with the rare-cutting restriction endonucleases. The Mut C double minute chromosomes, with the newly demethylated CpG islands, but not the double minute chromosomes with the partially methylated CpG islands, undergo deletions and dimerizations. These results suggest a role for CpG island methylation controlling mitotic recombination between and within large DNA molecules.

Hypomethylation of CpG sites and c-myc gene overexpression in hepatocellular carcinomas, but not hyperplastic nodules, induced by a choline-deficient L-amino acid-defined diet in rats

We have investigated aberrant methylation of CpG nucleotides (CpG sites) and gene expression of c-myc during hepatocarcinogenesis induced by a choline-deficient, L-amino acid-defined (CDAA) diet in rats. Male Fischer 344 rats, 6 weeks old, were continuously given a CDAA diet for 50 and 75 weeks and then killed. Macroscopically detectable nodules, which were histologically confirmed to be hyperplastic nodules (HNs) or well-differentiated hepatocellular carcinomas (HCCs), were dissected free from the surrounding tissue. Normal control liver was obtained from 6-week-old rats. Methylation of CpG sites of the c-myc gene was investigated in bisulfite-treated DNA isolated from normal liver, HNs and HCCs. All 33 cytosines in the 5'-upstream region of the c-myc gene were fully methylated in control liver and the 4 HNs. In contrast, these cytosines were completely unmethylated in 5 HCCs. Examination of the c-myc expression by reverse transcription-polymerase chain reaction (RT-PCR) analysis also showed a marked increase as compared to the low levels in normal livers and HNs. These results suggest that hypomethylation of the c-myc gene might play a critical role in malignant transformation from HN to HCC during CDAA diet-induced hepatocarcinogenesis in rats.

Overall deregulation in gene expression as a novel indicator of tumor aggressiveness in colorectal cancer

Malignant transformation of the cell is accompanied and characterized by disruption of genetic material and aberrant expression of multiple genes. Systematic analysis of differential gene expression in human tumor samples may provide an estimate of the degree of genetic and epigenetic deregulation in neoplastic cells. We have assessed, by means of a RNA differential display technique, the overall gene expression deregulation in a prospectively collected series of 68 human colorectal carcinomas. An index of differential expression has been calculated for each case. A similar proportion of the displayed sequences (23%) was under- and over-represented in the tumor in respect of the normal tissue. An increased variation in the expression profile was observed in advanced Dukes' stages (P < 0.02) and correlated with lymph node invasion (P < 0.05). Furthermore, a diminished overall survival was associated to increased rates of deregulation (Log-rank, P < 0.02) and especially down-regulation (P < 0.001). When Cox multivariate analysis was performed in front of Dukes' stage, both indexes of differential expression were independent indicators of a worse outcome (P = 0.05 and P < 0.01 respectively). We conclude that estimation of the fraction of differentially displayed tags by RNA fingerprinting may have relevant applications in the prognostic assessment of colorectal cancer.

Acquired homozygosity (isodisomy) of chromosome 3 in uveal melanoma

Cytogenetic investigation of uveal melanoma (UM) has revealed that monosomy 3 is the most frequent karyotypic abnormality, present in approximately 60% of cases. We investigated a cohort of 41 cases of UM, 19 of which retained two apparently normal copies of chromosome 3. Investigation of loss of heterozygosity (LOH) status was undertaken in an attempt to detect subcytogenetic loss of genetic material in those cases with two copies of chromosome 3. DNA from peripheral blood lymphocytes and fresh frozen or paraffin-embedded tumor tissue from 19 patients was amplified by the polymerase chain reaction for polymorphic loci on chromosome 3, including dinucleotide repeats, a tetranucleotide repeat, and polymorphic restriction enzyme sites. Three tumors showed LOH at multiple informative loci on both short and long arms of chromosome 3. Two additional tumors showed localized LOH on 3q, which corresponded to large deletions seen by cytogenetic analysis. The remaining 16 tumors showed retention of heterozygosity at all informative loci. This study did not detect the presence of cryptic deletions but revealed instead complete chromosomal homozygosity or functional monosomy, which probably occurred by loss and then duplication of the remaining chromosome 3. The demonstration of acquired isodisomy (functional monosomy) in a subset of UM increases the percentage of cases with monosomy 3 and provides further evidence for a central role of chromosome 3 loss in the molecular pathogenesis of uveal melanoma.

Genomic imprinting in mammals

A handful of autosomal genes in the mammalian genome are inherited in a silent state from one of the two parents, and in a fully active form from the other, thereby rendering the organism functionally hemizygous for imprinted genes. To date 19 imprinted genes have been identified; 5 are expressed from the maternal chromosome while the rest are expressed from the paternal chromosome. Allele-specific methylation of CpG residues, established in one of the germlines and maintained throughout embryogenesis, has been clearly implicated in the maintenance of imprinting in somatic cells. Although the function of imprinting remains a subject of some debate, the process is thought to have an important role in regulating the rate of fetal growth.

DNA methylation and genetic instability in colorectal cancer cells

Apparent alterations in DNA methylation have been observed in many cancers, but whether such alterations represent a persistent alteration in the normal methylation process is not known. In this study, we report a striking difference in the expression of exogenously introduced retroviral genes in various colorectal cancer cell lines. Extinguished expression was associated with DNA methylation and could be reversed by treatment with the demethylating agent 5-azacytidine. A striking correlation between genetic instability and methylation capacity suggested that methylation abnormalities may play a role in chromosome segregation processes in cancer cells.

Genomic imprinting in disorders of growth

This review has briefly considered some of the vast amount of information that has been gathered on genomic imprinting and its role in PWS, AS, BWS and Russell-Silver syndrome. The pace of investigation into the phenomenon of imprinting will undoubtedly continue, because our understanding remains far from complete. Newer approaches to identifying imprinted genes based on their expression rather than their location are likely to uncover currently unknown genes. We can also look forward to more insight into the fascinating complexities of the imprinting process.

Stage-specific and cell type-specific aspects of genomic imprinting effects in mammals

Recent studies have revealed that maternal and paternal alleles of some imprinted genes are differentially expressed from the earliest time of expression, with virtually no expression from one of the two alleles, while for other imprinted genes the normally silent allele can be transcribed during early development. In addition, a number of imprinted genes manifest their imprints only in select tissues. These observations indicate that the marks that denote parental chromosome origin need not directly determine allele expression, but rather bias later epigenetic modifications toward a particular allele. Thus, factors expressed at specific stages or in specific cell types are required to silence one parental allele or another. Stage-dependent and tissue-specific epigenetic modifications include the progressive establishment of the mature adult parental allele-specific DNA methylation patterns. These changes resemble and may share a common mechanistic basis with other epigenetic modifications that occur during development. Understanding the mechanisms by which these post-fertilization epigenetic modifications are mediated and regulated will be essential for understanding how genomic imprinting leads to differences in parental allele expression.

An enhancer deletion affects both H19 and Igf2 expression

The distal end of mouse Chromosome 7 contains four tightly linked genes whose expression is dependent on their parental inheritance. Mash-2 and H19 are expressed exclusively from the maternal chromosome, whereas Insulin-2 (Ins-2) and Insulin-like growth factor 2 (Igf2) are paternally expressed. The identical expression during development of the 3'-most genes in the cluster, Igf2 and H19, led to the proposal that their imprinting was mechanistically linked through a common set of transcriptional regulatory elements. To test this hypothesis, a targeted deletion of two endoderm-specific enhancers that lie 3' of H19 was generated by homologous recombination in embryonic stem cells. Inheritance of the enhancer deletion through the maternal lineage led to a loss of H19 gene expression in cells of endodermal origin, including cells in the liver, gut, kidney, and lung. Paternal inheritance led to a very similar loss in the expression of Igf2 RNA in the same tissues. These results establish that H19 and Igf2 utilize the same endoderm enhancers, but on different parental chromosomes. Mice inheriting the enhancer deletion from fathers were 80% of normal size, reflecting a partial loss-of-function of Igf2. The reduction was uniformly observed in a number of internal organs, indicating that insulin-like growth factor II (IGFII), the product of Igf2, acts systemically in mice to affect prenatal growth. A modest decline in Ins-2 RNA was observed in the yolk sac. In contrast Mash-2, which is expressed in spongiotrophoblast cells of the placenta, was unaffected by the enhancer deletion.