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.     

The genome: an isochore ensemble and its evolution

The genomes of eukaryotes are mosaics of isochores. These are long DNA stretches that are fairly homogeneous in base composition and that belong to a small number of families characterized by different ratios of GC to AT and different short-sequence patterns (i.e., different DNA structures that interact with different proteins). This genome organization led to two discoveries: (1) the genomic code, which refers to two correlations, that of the composition of coding and contiguous noncoding sequences, and that of coding sequences and the structural properties of the encoded proteins; and (2) the genome phenotypes, which correspond to the patterns of isochore families in the genomes. These patterns indicate that genome evolution may proceed either according to a conservative mode or to a transitional (isochore shifting) mode, apparently depending upon whether the environment is constant or shifting. According to the neoselectionist theory, natural selection is responsible for both modes.     

A Comparative Study and a Phylogenetic Exploration of the Compositional Architectures of Mammalian Nuclear Genomes

For the past four decades the compositional organization of the mammalian genome posed a formidable challenge to molecular evolutionists attempting to explain it from an evolutionary perspective. Unfortunately, most of the explanations adhered to the “isochore theory,” which has long been rebutted. Recently, an alternative compositional domain model was proposed depicting the human and cow genomes as composed mostly of short compositionally homogeneous and nonhomogeneous domains and a few long ones. We test the validity of this model through a rigorous sequence-based analysis of eleven completely sequenced mammalian and avian genomes. Seven attributes of compositional domains are used in the analyses: (1) the number of compositional domains, (2) compositional domain-length distribution, (3) density of compositional domains, (4) genome coverage by the different domain types, (5) degree of fit to a power-law distribution, (6) compositional domain GC content, and (7) the joint distribution of GC content and length of the different domain types. We discuss the evolution of these attributes in light of two competing phylogenetic hypotheses that differ from each other in the validity of clade Euarchontoglires. If valid, the murid genome compositional organization would be a derived state and exhibit a high similarity to that of other mammals. If invalid, the murid genome compositional organization would be closer to an ancestral state. We demonstrate that the compositional organization of the murid genome differs from those of primates and laurasiatherians, a phenomenon previously termed the “murid shift,” and in many ways resembles the genome of opossum. We find no support to the “isochore theory.” Instead, our findings depict the mammalian genome as a tapestry of mostly short homogeneous and nonhomogeneous domains and few long ones thus providing strong evidence in favor of the compositional domain model and seem to invalidate clade Euarchontoglires.     

Single-copy sequence homology among the GC-richest isochores of the genomes from warm-blooded vertebrates

We have hybridized a human DNA fraction corresponding to the GC-richest and gene-richest isochore family, H3, on compositional fractions of DNAs from 12 mammalian species and three avian species, representing eight and three orders, respectively. Under conditions in which repetitive sequences are competed out, the H3 isochore probe only or predominantly hybridized on the GC-richest fractions of main-band DNA from all the species investigated. These results indicate that single-copy sequences from the human H3 isochores share homology with sequences located in the compositionally corresponding compartments of the vertebrate genomes tested. These sequences are likely to be essentially formed by conserved coding sequences. The present results add to other lines of evidence indicating that isochore patterns are highly conserved in warm-blooded vertebrate genomes. Moreover, they refine recent reports (Sabeur et al., 1993; Kadi et al., 1993), and correct them in some details and also in demonstrating that the shrew genome does not exhibit the general mammalian pattern, but a special pattern.Correspondence to: G. Bernardi     

Compositional properties of coding sequences and mammalian phylogeny

The compositional distributions of large DNA fragments reflect those of the isochores that make up vertebrate genomes and can provide novel phylogenetic insights in the case of mammalian genomes (see Sabeur et al. 1993). This approach has been complemented here by an analysis of the compositional patterns of coding sequences and their codon positions (which also reflect the isochore pattern) and by a comparison of the base compositions of codon positions from homologous genes in a number of pairs of species. The results obtained using these two approaches support the existence of a general compositional pattern for mammalian genomes and of a distinct pattern for Myomorpha. The other two “special” patterns identified in a megachiropteran and in pangolin could not be tested here. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

The length of chromatin loops in meiotic prophase I of warm-blooded vertebrates depends on the DNA compositional organization

In meiotic prophase I, chromatin fibrils attached to the lateral elements of the synaptonemal complexes (SC) form loops. SCAR DNA (synaptonemal complex associated regions of DNA) is a family of genomic DNA tightly associated with the SC and located at the chromatin loop basements. Using the hybridization technique, it was demonstrated that localization of SCAR DNA was evolutionarily conserved in the isochore compositional fractions of the three examined genomes of warm-blooded vertebrates—human, chicken, and golden hamster. The introduction of the concept of the comparative loops (CL) of DNA that form of chromatin attach to SC in the isochore compositional fractions provided the calculation of their length. An inverse proportional relationship between the length of CL DNA and the GC level in the isochore compartments of the studied warm-blooded vertebrate genomes was revealed. An exception was the GCpoorest L1 isochore family. For different compositional isochores of the human and chicken genomes, the number of genes in the CL DNA was evaluated. A model of the formation of GC-rich isochores in vertebrate genomes, according to which there was not only an increase in the GC level but also the elimination of functionally insignificant noncoding DNA regions, as well as joining of isochores decreasing in size, was suggested.     

Isochore pattern and gene distribution in the chicken genome

We report here investigations on the isochore pattern and the distribution of genes in the chromosomes of chicken. In spite of large differences in genome size and karyotype, the compositional properties and the gene distribution of the chicken genome are very similar to those recently published for the human genome, which is a good representative of most mammalian genomes. In fact, this similarity, which extends to the relative amounts and, also, to a large extent at least, to the average base composition of isochore families, is most interesting in view of the very large distance of mammals and birds for a common ancestor, which goes back to 310–340 million years ago. This raises important questions about genome evolution in vertebrates.     

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.     

Isochore chromosome maps of the human genome

The human genome is a mosaic of isochores, which are long DNA segments (300 kbp) relatively homogeneous in G+C. Human isochores were first identified by density-gradient ultracentrifugation of bulk DNA, and differ in important features, e.g. genes are found predominantly in the GC-richest isochores. Here, we use a reliable segmentation method to partition the longest contigs in the human genome draft sequence into long homogeneous genome regions (LHGRs), thereby revealing the isochore structure of the human genome. The advantages of the isochore maps presented here are: (1) sequence heterogeneities at different scales are shown in the same plot; (2) pair-wise compositional differences between adjacent regions are all statistically significant; (3) isochore boundaries are accurately defined to single base pair resolution; and (4) both gradual and abrupt isochore boundaries are simultaneously revealed. Taking advantage of the wide sample of genome sequence analyzed, we investigate the correspondence between LHGRs and true human isochores revealed through DNA centrifugation. LHGRs show many of the typical isochore features, mainly size distribution, G+C range, and proportions of the isochore classes. The relative density of genes, Alu and long interspersed nuclear element repeats and the different types of single nucleotide polymorphisms on LHGRs also coincide with expectations in true isochores. Potential applications of isochore maps range from the improvement of gene-finding algorithms to the prediction of linkage disequilibrium levels in association studies between marker genes and complex traits. The coordinates for the LHGRs identified in all the contigs longer than 2 Mb in the human genome sequence are available at the online resource on isochore mapping: http://bioinfo2.ugr.es/isochores.     

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.     

Isochores and the evolutionary genomics of vertebrates

The nuclear genomes of vertebrates are mosaics of isochores, very long stretches (>300kb) of DNA that are homogeneous in base composition and are compositionally correlated with the coding sequences that they embed. Isochores can be partitioned in a small number of families that cover a range of GC levels (GC is the molar ratio of guanine+cytosine in DNA), which is narrow in cold-blooded vertebrates, but broad in warm-blooded vertebrates. This difference is essentially due to the fact that the GC-richest 10-15% of the genomes of the ancestors of mammals and birds underwent two independent compositional transitions characterized by strong increases in GC levels. The similarity of isochore patterns across mammalian orders, on the one hand, and across avian orders, on the other, indicates that these higher GC levels were then maintained, at least since the appearance of ancestors of warm-blooded vertebrates. After a brief review of our current knowledge on the organization of the vertebrate genome, evidence will be presented here in favor of the idea that the generation and maintenance of the GC-richest isochores in the genomes of warm-blooded vertebrates were due to natural selection.     

The compositional evolution of vertebrate genomes

The compositional evolution of vertebrate genomes is characterized: (i) by one predominant conservative mode, in which nucleotide changes occur, but the base composition of DNA sequences in general, and of coding sequences in particular, does not change; and (ii) by three different shifting or transitional modes, in which nucleotide changes are accompanied by changes in the base composition of sequences. Investigations on these evolutionary modes have shed new light on a central problem in molecular evolution, namely the role played by natural selection in modulating the mutational input.This review will present first the intragenomic shifts, the 'major shifts' and the 'minor shift', and then the 'whole-genome', or 'horizontal', shift. In each case, the shifts were preceded and followed by a conservative mode of evolution. This review expands on a previous one [Bernardi, Gene 241 (2000) 3-17], and summarizes the evidence that the changes of the compositional patterns of the genome and their maintenance are controlled by Darwinian natural selection.     

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.     

Two Low Coverage Bird Genomes and a Comparison of Reference-Guided versus De Novo Genome Assemblies

As a greater number and diversity of high-quality vertebrate reference genomes become available, it is increasingly feasible to use these references to guide new draft assemblies for related species. Reference-guided assembly approaches may substantially increase the contiguity and completeness of a new genome using only low levels of genome coverage that might otherwise be insufficient for de novo genome assembly. We used low-coverage (∼3.5–5.5x) Illumina paired-end sequencing to assemble draft genomes of two bird species (the Gunnison Sage-Grouse, Centrocercus minimus, and the Clark''s Nutcracker, Nucifraga columbiana). We used these data to estimate de novo genome assemblies and reference-guided assemblies, and compared the information content and completeness of these assemblies by comparing CEGMA gene set representation, repeat element content, simple sequence repeat content, and GC isochore structure among assemblies. Our results demonstrate that even lower-coverage genome sequencing projects are capable of producing informative and useful genomic resources, particularly through the use of reference-guided assemblies.     

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.     

Correlations between coding and contiguous non-coding sequences in isochore families from vertebrate genomes

Many years ago compositional correlations were found to hold between coding and contiguous non-coding sequences. These correlations were essentially studied in whole genomes of mammals, which are characterized by strong compositional heterogeneities. Here we investigated whether these correlations also hold within the much more homogeneous isochore families. This point was checked not only in the case of mammals, but also in that of phylogenetically distant vertebrates, which are characterized by very different compositional patterns. Indeed, these are remarkably different in cold- and warm-blooded vertebrates. Fish genomes, for instance, are much more homogeneous than those of mammals and birds. The compositional correlations between coding sequences and the corresponding introns, or their 5′ and 3′ flanking regions, were studied in the isochore families of the fully sequenced genomes from four fishes (Brachydanio rerio, Oryzias latipes, Gasterosteus aculeatus and Tetraodon nigroviridis), human and chicken.     

Telomeres in Warm-Blooded Vertebrates Are Composed of GC-Rich Isochores

We have hybridized the vertebrate telomeric sequence (TTAGGG)n on DNA compositional fractions from 13 mammalian species and 3 avian species, representing 9 and 3 orders, respectively. Our results indicate that the 50- to 100-kb fragments derived from telomeric regions are composed of GC-rich and GC-richest isochores. Previous works from our laboratory demonstrated that single-copy sequences from the human H3 isochore family (the GC-richest and gene-richest isochore in the human genome) share homology with compositionally correlated compartments of warm-blooded vertebrates. This correlation suggested that the GC-richest isochores are, as in the human genome, the gene-richest regions of warm-blooded vertebrates' genome. Moreover, this evidence suggests that telomeric regions are the most gene-dense region of all warm-blooded vertebrates. The implications of these findings are discussed.     

Evolution conservatively of SCAR DNA localization in genome isochores of warm-blooded vertebrates

In meiotic prophase I, chromatin fibrils attached to the lateral elements of the synaptonemal complexes form loops. Synaptonemal complex associated regions of DNA (SCARs DNA) are a family of genomic DNA sequences tightly associated with the synaptonemal complex; they are located at the chromatin loop basements. Isochore compositional fractions of the human and chicken genomes were used as 32P labeled probes for hybridization with SCAR DNA isolated previously from the spermatocyte nuclei of the golden hamster Mesocricetus auratus. Nucleotide sequences similar to the golden hamster’s SCAR DNA were found in human and chicken genome isochores. The localization of SCAR DNA in isochore compartments of the examined genomes was established to be evolutionary conservative.