An isochore transition zone in the NF1 gene region is a conserved landmark of chromosome structure and function

The mammalian genome is organized as a mosaic of isochores, stretches of DNA with a distinct sequence composition. Isochores form the basis of the chromosomal banding pattern, which is tightly correlated with a number of structural and functional features. We have recently demonstrated that the transition from a GC-poor isochore to a GC-rich one in the NF1 gene region occurs within 5 kb and demarcates genomic regions with high and low recombination frequency. We now report that the same transition zone separates early replicating from late replicating chromatin on the molecular level. At the isochore transition the replication fork is stalled in mid-S phase and can be visualized by fiber-FISH techniques as a Y-shaped structure. The switch in GC content and in replication timing is conserved between human and mouse, emphasizing the importance of the transition zones as landmarks of chromosome organization and function.     

Similar integration but different stability of Alus and LINEs in the human genome

Alus and LINEs (LINE1) are widespread classes of repeats that are very unevenly distributed in the human genome. The majority of GC-poor LINEs reside in the GC-poor isochores whereas GC-rich Alus are mostly present in GC-rich isochores. The discovery that LINES and Alus share similar target site duplication and a common AT-rich insertion site specificity raised the question as to why these two families of repeats show such a different distribution in the genome. This problem was investigated here by studying the isochore distributions of subfamilies of LINES and Alus characterized by different degrees of divergence from the consensus sequences, and of Alus, LINEs and pseudogenes located on chromosomes 21 and 22. Young Alus are more frequent in the GC-poor part of the genome than old Alus. This suggests that the gradual accumulation of Alus in GC-rich isochores has occurred because of their higher stability in compositionally matching chromosomal regions. Densities of Alus and LINEs increase and decrease, respectively, with increasing GC levels, except for the telomeric regions of the analyzed chromosomes. In addition to LINEs, processed pseudogenes are also more frequent in GC-poor isochores. Finally, the present results on Alu and LINE stability/exclusion predict significant losses of Alu DNA from the GC-poor isochores during evolution, a phenomenon apparently due to negative selection against sequences that differ from the isochore composition.     

Statistical analysis of vertebrate sequences reveals that long genes are scarce in GC-rich isochores

We compared the exon/intron organization of vertebrate genes belonging to different isochore classes, as predicted by their GC content at third codon position. Two main features have emerged from the analysis of sequences published in GenBank: (1) genes coding for long proteins (i.e., 500 aa) are almost two times more frequent in GC-poor than in GC-rich isochores; (2) intervening sequences (=sum of introns) are on average three times longer in GC-poor than in GC-rich isochores. These patterns are observed among human, mouse, rat, cow, and even chicken genes and are therefore likely to be common to all warm-blooded vertebrates. Analysis of Xenopus sequences suggests that the same patterns exist in cold-blooded vertebrates. It could be argued that such results do not reflect the reality because sequence databases are not representative of entire genomes. However, analysis of biases in GenBank revealed that the observed discrepancies between GC-rich and GC-poor isochores are not artifactual, and are probably largely underestimated. We investigated the distribution of microsatellites and interspersed repeats in introns of human and mouse genes from different isochores. This analysis confirmed previous studies showing that Ll repeats are almost absent from GC-rich isochores. Microsatellites and SINES (Alu, B1, B2) are found at roughly equal frequencies in introns from all isochore classes. Globally, the presence of repeated sequences does not account for the increased intron length in GC-poor isochores. The relationships between gene structure and global genome organization and evolution are discussed.     

Isochore patterns and gene distributions in fish genomes

The compositional approach developed in our laboratory many years ago revealed a large-scale compositional heterogeneity in vertebrate genomes, in which GC-rich and GC-poor regions, the isochores, were found to be characterized by high and low gene densities, respectively. Here we mapped isochores on fish chromosomes and assessed gene densities in isochore families. Because of the availability of sequence data, we have concentrated our investigations on four species, zebrafish (Brachydanio rerio), medaka (Oryzias latipes), stickleback (Gasterosteus aculeatus), and pufferfish (Tetraodon nigroviridis), which belong to four distant orders and cover almost the entire GC range of fish genomes. These investigations produced isochore maps that were drastically different not only from those of mammals (in that only two major isochore families were essentially present in each genome vs five in the human genome) but also from each other (in that different isochore families were represented in different genomes). Gene density distributions for these fish genomes were also obtained and shown to follow the expected increase with increasing isochore GC. Finally, we discovered a remarkable conservation of the average size of the isochores (which match replicon clusters in the case of human chromosomes) and of the average GC levels of isochore families in both fish and human genomes. Moreover, in each genome the GC-poorest isochore families comprised a group of "long isochores" (2-20 Mb in size), which were the lowest in GC and varied in size distribution and relative amount from one genome to the other.     

Evidence that both G + C rich and G + C poor isochores are replicated early and late in the cell cycle.

Since the G + C content of a gene is correlated to that of the isochore in which it resides, and early replicating isochores are thought to be relatively G + C rich, early replicating genes should also be rich in G + C. This hypothesis is tested on a sample of 44 mammalian genes for which replication time data and sequence information are available. Early replicating genes do not appear to be more G + C rich than late replicating genes, instead there is considerable variation in the G + C content of genes replicated during both halves of S phase. These results show that both G + C rich and poor fractions of the genome are replicated early and late in the cell cycle, and suggest that isochores are not maintained by the replication of DNA sequences in compositionally biased free nucleotide pools.     

Isochore structures in the mouse genome

The distribution of the G+C content in the mouse genome has been studied using a windowless technique. We have found that: (i). Abrupt variations of the G+C content from a GC-rich region to a GC-poor region, and vice versa, occur frequently at some sites along the sequence of the mouse genome. (ii). Long domains with relatively homogeneous G+C content (isochores) exist, which usually have sharp boundaries. Consequently, 28 isochores longer than 1 Mb have been identified in the mouse genome. A homogeneity index was used to quantify the variations of the G+C content within isochores. The precise boundaries, sizes, and G+C contents of these isochores have been determined. The windowless technique for the G+C content computation was also used to analyze the DNA sequence containing the mouse MHC region, which has a GC-poor isochore. This isochore is located at the central part of the sequence with boundaries at 468459 and 812716 bp, where the sequence is extended from the centromeric end to the telomeric end. In addition, the analysis of a segment of the rat genome shows that the rat genome also has clear isochore structures.     

Evidence of distinct gene functional patterns in GC-poor and GC-rich isochores in Bos taurus

Vertebrate genomes are mosaics of megabase-size DNA segments with a fairly homogeneous base composition, called isochores. They are divided into five families characterized by different guanine-cytosine (GC) levels and linked to several functional and structural properties. The increased availability of fully sequenced genomes allows the investigation of isochores in several species, assessing their level of conservation across vertebrate genomes. In this work, we characterized the isochores in Bos taurus using the ARS-UCD1.2 genome version. The comparison of our results with the well-studied human isochores and those of other mammals revealed a large conservation in isochore families, in number, average GC levels and gene density. Exceptions to the established increase in gene density with the increase in isochores (GC%) were observed for the following gene biotypes: tRNA, small nuclear RNA, small nucleolar RNA and pseudogenes that have their maximum number in H2 and H1 isochores. Subsequently, we assessed the ontology of all gene biotypes looking for functional classes that are statistically over- or under-represented in each isochore. Receptor activity and sensory perception pathways were significantly over-represented in L1 and L2 (GC-poor) isochores. This was also validated for the horse genome. Our analysis of housekeeping genes confirmed a preferential localization in GC-rich isochores, as reported in other species. Finally, we assessed the SNP distribution of a bovine high-density SNP chip across the isochores, finding a higher density in the GC-rich families, reflecting a potential bias in the chip, widely used for genetic selection and biodiversity studies.     

Turtle isochore structure is intermediate between amphibians and other amniotes

Vertebrate genomes are comprised of isochores that are relatively long (>100 kb) regions with a relatively homogenous (either GC-rich or AT-rich) base composition and with rather sharp boundaries with neighboring isochores. Mammals and living archosaurs (birds and crocodilians) have heterogeneous genomes that include very GC-rich isochores. In sharp contrast, the genomes of amphibians and fishes are more homogeneous and they have a lower overall GC content. Because DNA with higher GC content is more thermostable, the elevated GC content of mammalian and archosaurian DNA has been hypothesized to be an adaptation to higher body temperatures. This hypothesis can be tested by examining structure of isochores across the reptilian clade, which includes the archosaurs, testudines (turtles), and lepidosaurs (lizards and snakes), because reptiles exhibit diverse body sizes, metabolic rates, and patterns of thermoregulation. This study focuses on a comparative analysis of a new set of expressed genes of the red-eared slider turtle and orthologs of the turtle genes in mammalian (human, mouse, dog, and opossum), archosaurian (chicken and alligator), and amphibian (western clawed frog) genomes. EST (expressed sequence tag) data from a turtle cDNA library enriched for genes that have specialized functions (developmental genes) revealed using the GC content of the third-codon-position to examine isochore structure requires careful consideration of the types of genes examined. The more highly expressed genes (e.g., housekeeping genes) are more likely to be GC-rich than are genes with specialized functions. However, the set of highly expressed turtle genes demonstrated that the turtle genome has a GC content that is intermediate between the GC-poor amphibians and the GC-rich mammals and archosaurs. There was a strong correlation between the GC content of all turtle genes and the GC content of other vertebrate genes, with the slope of the line describing this relationship also indicating that the isochore structure of turtles is intermediate between that of amphibians and other amniotes. These data are consistent with some thermal hypotheses of isochore evolution, but we believe that the credible set of models for isochore evolution still includes a variety of models. These data expand the amount of genomic data available from reptiles upon which future studies of reptilian genomics can build.     

Localization of DNA sequences tightly associated with synaptonemal complex in compositional fractions of golden hamster

The synaptonemal complex isolated from the spermatocyte nuclei by exhaustive hydrolysis of the latter by DNase II contains tightly associated DNA sequences (SCAR DNA). Here we studied the compositional properties of a cloned family of SCAR DNA of golden hamster, namely we performed the localization of 27 SCAR DNA clones on compositionally fractionated genomic DNA from golden hamster. We observed that sequences of the SCAR DNA family are mainly localized in the GC-poor isochore families L1 and L2, that showed 63% hybridization signals. This means that 37% of signals is referred to the GC-rich isochores, indicating the presence of SCAR DNA overall the genome, even if each isochore family presents differences in density and sequence type. Moreover, the SCAR DNA sequences containing regions of homology with LINE/SINE repeats were observed in all the isochore families. The compositional localization of SCAR DNA is in agreement with the hypothesis that SC and SCAR DNA participate in the chromatin organization during the meiosis prophase I, which should result in the attachment of chromatin loops to lateral elements of SC along the whole length of the latter.     

A compositional map of the cen-q21 region of human chromosome 21

A compositional map of the centromere and of the subcentromeric region of the long arm of human chromosome 21 was established by determining the GC levels (GC is the molar fraction of guanine+cytosine in DNA) of 11 YACs (yeast artificial chromosomes) covering this 13–14 Mb region which extends from the α-satellite sequences of the C(entromeric) band qll.1, through R(everse) band q11.2, to the proximal part of G(iemsa) band q21. The entire region is made up of GC-poor, or L, isochores with only one GC-rich H1 isochore, at least 2 Mb in size, located in band q21. The almost identical GC levels of the centromeric α-satellite repeats (38.5%), of R band q11.2 (39%), and of G bands (38–40%) provide a direct demonstration that base composition cannot be the only cause of the cytogenetic differences between C, G, and the majority of R bands, namely the H3^- R bands (which do not contain the GC-richest H3 isochores). The results obtained also show that isochores may be as long as 6 Mb, at least in the GC-poor regions of the genome, and support previous observations suggesting that YACs from isochore borders are unstable and/or difficult to clone. Genes and CpG islands are very rare in the GC-poor region investigated, as expected from the fact that their concentration is proportional to the GC levels of the isochores in which they are contained.     

How not to search for isochores: a reply to Cohen et Al

In a recent paper in these pages, Cohen et al. search for isochores in the human genome, based on a system of attributes that they assign to isochores. The putative isochores that they find and choose for presentation are almost all below 45% GC and cover only about 41% of the genome. Closer inspection reveals that the authors' methodology systematically loses GC-rich isochores because it does not anticipate the considerable fluctuations and corresponding long-range correlations that characterize mammalian DNA and that are highest in GC-rich DNA. Thus, they over-fragment GC-rich isochores (and also many GC-poor isochores) beyond recognition.     

Deciphering heterogeneity in pig genome assembly Sscrofa9 by isochore and isochore-like region analyses

Background

The isochore, a large DNA sequence with relatively small GC variance, is one of the most important structures in eukaryotic genomes. Although the isochore has been widely studied in humans and other species, little is known about its distribution in pigs.

Principal Findings

In this paper, we construct a map of long homogeneous genome regions (LHGRs), i.e., isochores and isochore-like regions, in pigs to provide an intuitive version of GC heterogeneity in each chromosome. The LHGR pattern study not only quantifies heterogeneities, but also reveals some primary characteristics of the chromatin organization, including the followings: (1) the majority of LHGRs belong to GC-poor families and are in long length; (2) a high gene density tends to occur with the appearance of GC-rich LHGRs; and (3) the density of LINE repeats decreases with an increase in the GC content of LHGRs. Furthermore, a portion of LHGRs with particular GC ranges (50%–51% and 54%–55%) tend to have abnormally high gene densities, suggesting that biased gene conversion (BGC), as well as time- and energy-saving principles, could be of importance to the formation of genome organization.

Conclusion

This study significantly improves our knowledge of chromatin organization in the pig genome. Correlations between the different biological features (e.g., gene density and repeat density) and GC content of LHGRs provide a unique glimpse of in silico gene and repeats prediction.     

A compositional map of human chromosome 21.

GC-poor and GC-rich isochores, the long (greater than 300 kb) compositionally homogeneous DNA segments that form the genome of warm-blooded vertebrates, are located in G- and R-bands respectively of metaphase chromosomes. The precise correspondence between GC-rich isochores and R-band structure is still, however, an open problem, because GC-rich isochores are compositionally heterogeneous and only represent one-third of the genome, with the GC-richest family (which is by far the highest in gene concentration) corresponding to less than 5% of the genome. In order to clarify this issue and, more generally, to correlate DNA composition and chromosomal structure in an unequivocal way, we have developed a new approach, compositional mapping. This consists of assessing the base composition over 0.2-0.3 Mb (megabase) regions surrounding landmarks that were previously localized on the physical map. Compositional mapping was applied here to the long arm of human chromosome 21, using 53 probes that had already been used in physical mapping. The results obtained provide a direct demonstration that the DNA stretches of G-bands essentially correspond to GC-poor isochores, and that R-band DNA is characterized by a compositional heterogeneity that is much more striking than expected, in that it comprises isochores covering the full spectrum of GC levels. GC-poor isochores of R-bands may, however, correspond to 'thin' G-bands, as visualized at high resolution, leaving GC-rich and very GC-rich isochores as the real components of (high-resolution) R-band DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biological implications of isochore boundaries in the human genome

The human genome is composed of large sequence segments with fairly homogeneous GC content, namely isochores, which have been linked to many important functions; biological implications of most isochore boundaries, however, remain elusive, partly due to the difficulty in determining these boundaries at high resolution. Using the segmentation algorithm based on the quadratic divergence, we re-determined all 79 boundaries of previously identified human isochores at single-nucleotide resolution, and then compared the boundary coordinates with other genome features. We found that 55.7% of isochore boundaries coincide with termini of repeat elements; 45.6% of isochore boundaries coincide with termini of highly conserved sequences based on alignment of 17 vertebrate genomes, i.e., the highly conserved genome sequence switches to a less or non-conserved one at the isochore boundary; some isochore boundaries coincide with abrupt change of CpG island distribution (note that one boundary can associate with more than one genome feature). In addition, sequences around isochore boundaries are highly conserved. It seems reasonable to deduce that the boundaries of all the isochores studied here would be replication timing sites in the human genome. These results suggest possible key roles of the isochore boundaries and may further our understanding of the human genome organization.     

Vanishing GC-rich isochores in mammalian genomes

To understand the origin and evolution of isochores-the peculiar spatial distribution of GC content within mammalian genomes-we analyzed the synonymous substitution pattern in coding sequences from closely related species in different mammalian orders. In primate and cetartiodactyls, GC-rich genes are undergoing a large excess of GC --> AT substitutions over AT --> GC substitutions: GC-rich isochores are slowly disappearing from the genome of these two mammalian orders. In rodents, our analyses suggest both a decrease in GC content of GC-rich isochores and an increase in GC-poor isochores, but more data will be necessary to assess the significance of this pattern. These observations question the conclusions of previous works that assumed that base composition was at equilibrium. Analysis of allele frequency in human polymorphism data, however, confirmed that in the GC-rich parts of the genome, GC alleles have a higher probability of fixation than AT alleles. This fixation bias appears not strong enough to overcome the large excess of GC --> AT mutations. Thus, whatever the evolutionary force (neutral or selective) at the origin of GC-rich isochores, this force is no longer effective in mammals. We propose a model based on the biased gene conversion hypothesis that accounts for the origin of GC-rich isochores in the ancestral amniote genome and for their decline in present-day mammals.     

Biological Implications of Isochore Boundaries in the Human Genome

Abstract

The human genome is composed of large sequence segments with fairly homogeneous GC content, namely isochores, which have been linked to many important functions; biological implications of most isochore boundaries, however, remain elusive, partly due to the difficulty in determining these boundaries at high resolution. Using the segmentation algorithm based on the quadratic divergence, we re-determined all 79 boundaries of previously identified human isochores at single-nucleotide resolution, and then compared the boundary coordinates with other genome features. We found that 55.7% of isochore boundaries coincide with termini of repeat elements; 45.6% of isochore boundaries coincide with termini of highly conserved sequences based on alignment of 17 vertebrate genomes, i.e., the highly conserved genome sequence switches to a less or non-conserved one at the isochore boundary; some isochore boundaries coincide with abrupt change of CpG island distribution (note that one boundary can associate with more than one genome feature). In addition, sequences around isochore boundaries are highly conserved. It seems reasonable to deduce that the boundaries of all the isochores studied here would be replication timing sites in the human genome. These results suggest possible key roles of the isochore boundaries and may further our understanding of the human genome organization.     

Mapping Insertions,Deletions and SNPs on Venter's Chromosomes

Background

The very recent availability of fully sequenced individual human genomes is a major revolution in biology which is certainly going to provide new insights into genetic diseases and genomic rearrangements.

Results

We mapped the insertions, deletions and SNPs (single nucleotide polymorphisms) that are present in Craig Venter''s genome, more precisely on chromosomes 17 to 22, and compared them with the human reference genome hg17. Our results show that insertions and deletions are almost absent in L1 and generally scarce in L2 isochore families (GC-poor L1+L2 isochores represent slightly over half of the human genome), whereas they increase in GC-rich isochores, largely paralleling the densities of genes, retroviral integrations and Alu sequences. The distributions of insertions/deletions are in striking contrast with those of SNPs which exhibit almost the same density across all isochore families with, however, a trend for lower concentrations in gene-rich regions.

Conclusions

Our study strongly suggests that the distribution of insertions/deletions is due to the structure of chromatin which is mostly open in gene-rich, GC-rich isochores, and largely closed in gene-poor, GC-poor isochores. The different distributions of insertions/deletions and SNPs are clearly related to the two different responsible mechanisms, namely recombination and point mutations.     

Evolution of isochores in rodents

The most deviant isochore pattern within mammals was found in rat and mouse; most other mammals possess a different kind of isochore organization called the "general pattern." However, isochore patterns remain largely unknown in rodents other than mouse and rat. To investigate the taxonomic distribution of isochore patterns in rodents, we sequenced the nuclear gene LCAT (lecithin:cholesterol acyltransferase) from 17 rodents species (bringing the total of LCAT sequences in rodent to 19) and compared their GC contents at third codon positions and in introns. We also analyzed an extensive sequence database from rodents other than rat and mouse. All murid LCAT sequences are much poorer in GC than all nonrodent LCAT sequences, and the hamster sequence database shows exactly the same isochore pattern as rat and mouse. Thus, all murids share the same special isochore pattern--GC homogenization. LCAT sequences are GC-poor in hystricomorphs too, but the guinea pig sequence database indicates that large changes in GC content occur without an overall modification of the isochore pattern. This novel mode of isochore evolution is called GC reordering. LCAT sequences also show that the evolution of isochores in sciurids and glirids is nonconservative in comparison with that in nonrodents. Thus, at least two novel patterns of isochore evolution were found. No rodent investigated to date shared the general mammalian pattern.      

Comparative Compositional Mapping of Chicken and Quail Chromosomes

The distribution of various isochore families on mitotic chromosomes of domestic chicken and Japanese quail was studied by the method of fluorescence in situ DNA–DNA hybridization (FISH). DNA of various isochore families was shown to be distributed irregularly and similarly on chromosomes of domestic chicken and Japanese quail. The GC-rich isochore families (H2, H3, and H4) hybridized mainly to microchromosomes and a majority of macrochromosome telomeric regions. In chicken, an intense fluorescence was also in a structural heterochromatin region of the Z chromosome long arm. In some regions of the quail macrochromosome arms, hybridization was also with isochore families H3 and H4. On macrochromosomes of both species, the pattern of hybridization with isochores of the H2 and H3 families resembled R-banding. The light isochores (L1 and L2 families) are mostly detected within macrochromosome internal regions corresponding to G bands, whereas microchromosomes lack light isochores. Although mammalian and avian karyotypes differ significantly in organization, the isochore distribution in genomes of these two lineages of the warm-blooded animals is similar in principle. On macrochromosomes of the two avian species studied, a pattern of isochore distribution resembled that of mammalian chromosomes. The main specific feature of the avian genome, a great number of microchromosomes (about 30% of the genome), determines a compositional specialization of the latter. This suggests the existence of not only structural but also functional compartmentalization of the avian genome.