Probes for CpG islands on the distal long arm of the human X chromosome are clustered in Xq24 and Xq28

We have isolated and characterized 55 EagI-containing genomic DNA clones from the distal long arm of the human X chromosome. The presence of additional sites for rare-cutter restriction enzymes and the demethylation of the corresponding genomic DNA demonstrate that at least 30 clones correspond to CpG islands of the Xq24-Xqter region. All clones were regionally mapped with a hybrid panel. The majority are in Xq28 and Xq24 (18 and 14 clones, respectively), 15 are in the Xq26-Xq27 interval, and none is in Xq25. This analysis demonstrates a nonuniform distribution of CpG islands that may reflect the distribution of coding regions in this part of the genome.     

Expression of the G6PD locus on the human X chromosome is associated with demethylation of three CpG islands within 100 kb of DNA.

We have previously reported that expression of the G6PD locus is correlated with the methylation status of two islands of CpG dinucleotides which are 3' to the locus and in the 5' region of two adjacent genes of unknown function, P3 and GdX. We have now examined the methylation of a third CpG island in the promoter region of the G6PD gene itself in DNA from males, females and reactivants that express G6PD on the inactive X chromosome. Our results show that expression of the G6PD gene is associated with concordant demethylation of all three CpG islands in this 100-kb region of DNA.     

Evolution of CpG islands within the myc gene family

CpG islands are discrete regions of DNA with significantly greater frequencies of CpG doublets than bulk genomic DNA. They are most frequently associated with the 5'-ends of housekeeping genes and are involved in the regulation of their expression. In this study, the structure and evolution of CpG islands within genes of the myc family were evaluated with the protein-coding sequences of animals and their transducing viruses. These evaluations relied on a gene tree for the entire myc family to test the origins of CpG islands within their two protein-coding exons. Overall, CG-very rich and CG-rich islands are associated with exon 2 of the different myc genes of warm-blooded vertebrates and with exon 3 of the N-myc and s-myc sequences of mammals, but not birds. These overall distributions of well-developed islands can be related to the major transitions of the CG-rich genomes of warm-blooded vertebrates from the CG-poor ones of other animals. In turn, the greater variability of well-developed islands within exon 3 of the N-myc gene and among the different retrogenes of the myc family can be attributed to their reduced functional constraints, as evidenced by their limited and very restricted patterns of expression, respectively.     

CpG islands from the alpha-globin gene cluster increase gene expression in an integration-dependent manner.

In contrast to other globin genes, the human and rabbit alpha-globin genes are expressed in transfected erythroid and nonerythroid cells in the absence of an enhancer. This enhancer-independent expression of the alpha-globin gene requires extensive sequences not only from the 5' flanking sequence but also from the intragenic region. However, the features of these internal sequences that are responsible for their positive effect are unclear. We tested several possible determinants of this activity. One possibility is that a previously identified array of discrete binding sites for known and potential regulatory proteins within the alpha-globin gene comprise an intragenic enhancer specific for the alpha-globin promoter, but directed rearrangements of the sequences show that this is not the case. Alternatively, the promoter may extend into the gene, with the function of the discrete binding sites being dependent on maintenance of their proper positions and orientations relative to the 5' flanking sequence. However, the positive effects observed in gene fusions do not localize to a discrete region of the alpha-globin gene and the results of internal deletions and point mutations argue against a required role of the targeted discrete binding sites. A third possibility is that the CpG island, which includes both the 5' flanking and intragenic regions associated with the positive activity, may itself have a more general effect on expression in transfected cells. Indeed, we show that the size of the CpG island in constructs correlates with the level of gene expression. Furthermore, the alpha-globin promoter is more active in the context of a previously inactive CpG island than in an A+T-rich context, showing that the CpG island provides an environment more permissive for expression. These effects are seen only after integration, suggesting a possible mechanism at the level of chromatin structure.     

Identification of novel RFLPs in the vicinity of CpG islands in Xq28: application to the analysis of the pattern of X chromosome inactivation.

Probes for CpG islands were cloned from the distal long arm of the human X chromosome; three of them were found to be polymorphic. A HindIII RFLP was identified by the probe 2-25 (DXS606), and it was mapped to the Xq27-Xq28 boundary. Probes 2-19 (DXS605) and 2-55 (DXS707), which identify EcoRI and MspI polymorphisms, respectively, have been mapped to the distal part of Xq28, in the G6PD-RCP/GCP gene region. Probe 2-19 has been further localized about 16 kb from the 3' end of the G6PD gene. The new RFLPs may be useful for the precise mapping of the many disease genes localized in this part of the human X chromosome. Probe 2-19 is highly informative, and it has been studied in greater detail. Using the methylation-sensitive rare-cutter enzyme EagI in conjunction with the polymorphic EcoRI site, we were able to demonstrate that the RFLP may be used both to study randomness of X chromosome inactivation and for carrier detection in X-linked syndromes where nonrandom X inactivation occurs. It is conceivable that the combined use of 2-19 and of the probes described so far (pSPT-PGK and M27 beta) will make analysis of X inactivation feasible in virtually every female.     

Identification of multiple CpG islands and associated conserved sequences in a candidate region for the Huntington disease gene

The HD locus has been assigned to 4p16.3 distal to the DNA segment D4S10. However, the precise location of this gene is still unknown. At least three regions, together encompassing more than 3.5 Mb of DNA, can still be considered as candidate regions for the HD gene. Our efforts are directed toward the cloning and the complete characterization of one of these regions. Thus far we have cloned 460 kb of DNA in contiguously overlapping cosmids distal to D4S111 and have developed a detailed long-range restriction map orienting the contig within the terminal region of 4p16.3. We characterized 15 CpG-rich islands defined by tightly clustered rare cutter restriction sites for the enzymes NotI, BssHII, EagI, NruI, and SacII. In addition, we show that the sequences associated with the CpG-rich islands detect cross-species conservation. The detailed genetic analysis of the 460-kb contig provides a framework for the identification of genes, which can be assessed for the characteristics expected for the HD gene.     

Unmethylated CpG islands associated with genes in higher plant DNA

The genomes of many higher plant species are the most highly methylated among eukaryotes. We report here that in spite of their heavy methylation, genomic DNAs from four plant species contain a fraction that is very rich in non-methylated sites. The fraction was characterized in maize where it represents about 2.5% of the total nuclear genome. In order to establish the genomic origin of the fraction, three maize genes containing clustered CpG were tested for methylation and were found to be non-methylated in the CpG-rich regions. By contrast, tested CpGs were methylated in a gene whose sequence showed no clustering of CpG. These observations suggest that the CpG-rich fraction of plants is at least partially derived from non-methylated regions that are associated with genes. A similar phenomenon has been described in vertebrate genomes. We discuss the evolution of CpG islands in both groups of organisms, and their possible uses in mapping and gene isolation in plants.     

Inversions are bigger on the X chromosome

In many insects, X‐linked inversions fix at a higher rate and are much less polymorphic than autosomal inversions. Here, we report that in Drosophila, X‐linked inversions also capture 67% more genes. We estimated the number of genes captured through an approximate Bayesian computational analysis of gene orders in nine species of Drosophila. X‐linked inversions fixed with a significantly larger gene content. Further, X‐linked inversions of intermediate size enjoy highest fixation rate, while the fixation rate of autosomal inversions decreases with size. A less detailed analysis in Anopheles suggests a similar pattern holds in mosquitoes. We develop a population genetic model that assumes the fitness effects of inversions scale with the number of genes captured. We show that the same conditions that lead to a higher fixation rate also produce a larger size for inversions on the X.     

CpG islands are the second main factor shaping codon usage in human genes

A correspondence analysis of codon usage in human genes revealed, as expected, that the first axis is strongly correlated with the base composition at synonymous third codon positions. At one extreme of the second axis were localized genes with a high frequency of NCG and CGN codons. The great majority of these sequences were embedded in CpG islands, while the opposite is true for the genes placed at the other extreme. The two main conclusions of this paper are: (1) the influence of CpG islands on codon usage, and (2) since the second axis is orthogonal (and therefore independent) of the first, GC3-rich genes are not necessarily associated with CpG islands.     

Primate CpG islands are maintained by heterogeneous evolutionary regimes involving minimal selection

Mammalian CpG islands are key epigenomic elements that were first characterized experimentally as genomic fractions with low levels of DNA methylation. Currently, CpG islands are defined based on their genomic sequences alone. Here, we develop evolutionary models to show that several distinct evolutionary processes generate and maintain CpG islands. One central evolutionary regime resulting in enriched CpG content is driven by low levels of DNA methylation and consequentially low rates of CpG deamination. Another major force forming CpG islands is biased gene conversion that stabilizes constitutively methylated CpG islands by balancing rapid deamination with CpG fixation. Importantly, evolutionary analysis and population genetics data suggest that selection for high CpG content is not?a significant factor contributing to conservation of CpGs in differentially methylated regions. The heterogeneous, but not selective, origins of CpG islands have direct implications for the understanding of DNA methylation patterns in healthy and diseased cells.     

A comprehensive analysis of allelic methylation status of CpG islands on human chromosome 11q: comparison with chromosome 21q.

It was generally believed that autosomal CpG islands (CGIs) escape methylation. However, our comprehensive analysis of allelic methylation status of 149 CGIs on human chromosome 21q revealed that a sizable fraction of them are methylated on both alleles even in normal blood cells. Here, we performed a similar analysis of 656 CGIs on chromosome 11q, which is gene-rich in contrast with 21q. The results indicate that 11q contains less methylated CGIs, especially those with tandem repeats and those in the coding or 3'-untranslated regions (UTRs), than 21q. Thus, methylation status of CGIs may substantially differ from one chromosome to another.     

Cosmid walking and chromosome jumping in the region of PKD1 reveal a locus duplication and three CpG islands.

The locus responsible for the most common form of autosomal dominant polycystic kidney disease (PKD1) is located on chromosome 16p13.3. Genetic mapping studies indicate that PKD1 is flanked on the proximal side by the DNA marker 26.6 (D16S125). Here we show that 26.6 has undergone a locus duplication and that the two loci are less than 150kb apart. One of the two loci contains a polymorphic TaqI site that has been used in genetic studies and represents the proximal boundary for the PKD1 locus. We demonstrate that the polymorphic locus is the more proximal of the two 26.6-hybridizing loci. Therefore, four cosmids isolated from the distal 26.6-hybridizing locus contain candidate sequences for the PKD1 gene. These cosmids were found to contain two CpG islands that are likely markers for transcribed regions. A third CpG island was detected and cloned by directional chromosome jumping.