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Is mammalian chromosomal evolution driven by regions of genome fragility?

Abstract

Background

A fundamental question in comparative genomics concerns the identification of mechanisms that underpin chromosomal change. In an attempt to shed light on the dynamics of mammalian genome evolution, we analyzed the distribution of syntenic blocks, evolutionary breakpoint regions, and evolutionary breakpoints taken from public databases available for seven eutherian species (mouse, rat, cattle, dog, pig, cat, and horse) and the chicken, and examined these for correspondence with human fragile sites and tandem repeats.

Results

Our results confirm previous investigations that showed the presence of chromosomal regions in the human genome that have been repeatedly used as illustrated by a high breakpoint accumulation in certain chromosomes and chromosomal bands. We show, however, that there is a striking correspondence between fragile site location, the positions of evolutionary breakpoints, and the distribution of tandem repeats throughout the human genome, which similarly reflect a non-uniform pattern of occurrence.

Conclusion

These observations provide further evidence that certain chromosomal regions in the human genome have been repeatedly used in the evolutionary process. As a consequence, the genome is a composite of fragile regions prone to reorganization that have been conserved in different lineages, and genomic tracts that do not exhibit the same levels of evolutionary plasticity.

Background

Evolutionary biologists have long sought to explain the mechanisms of chromosomal evolution in order to better understand the dynamics of mammalian genome organization. Early work in this area led Nadeau and Taylor [1] to propose the 'random breakage model' of genomic evolution, based on linkage maps of human and mouse. Their thesis relied on two assumptions: first, that many chromosomal segments are expected to be conserved among species and, second, that chromosomal rearrangements are randomly distributed within genomes. More than 20 years later, in large part due to molecular cytogenetic studies, large-scale genome sequencing efforts, and new mathematical algorithms developed for whole-genome analysis, the first assumption has been confirmed. However, the second has been questioned by the 'fragile breakage model' [2], which considers that there are regions ('hotspots') throughout the mammalian genome that are prone to breakage and reorganization [3, 4].

Most recently, Murphy and colleagues [5] extended these analyses to include homologous synteny block (HSB) data from radiation hybrid maps of dog, cat, pig, and horse. Their findings corroborate the 'hotspot' theory and that some chromosome regions are reused [2] during mammalian chromosomal evolution. Indeed, that about 20% of the evolutionary breakpoint regions reported show reuse [5], particularly among the more rapidly evolving genomes (cattle, dog, and rodents), led us [6] to question whether 'hotspots' identified in silico correspond to fragile sites that can be expressed in culture under specific conditions, thus mirroring findings of a correlation between the location of fragile sites and evolutionary breakpoints in primates, including human [7, 8]. Our preliminary survey showed that at least 33 of the 88 cytogenetically defined common human fragile sites contain evolutionary breakpoints in at least three of the seven species analyzed by Murphy and colleagues [5].

But what are fragile sites? These are heritable loci located in specific regions of chromosomes that are expressed as gaps or breaks when cells are exposed to specific culture conditions or certain chemical agents such as inhibitors of DNA replication or repair [9]. According to frequency of expression in the human population, and the mechanism of their induction, fragile sites have been classically divided into two groups: common and rare. Common fragile sites are considered part of the chromosome structure since they have been described in different mammalian species (Rodentia [10], Carnivora [11, 12], Perissodactyla [13], Cetartiodactyla [14] and Primates [7, 15, 16]), whereas rare fragile sites are found expressed in a small percentage of the human population [17]. In total, 21 human fragile sites have been molecularly characterized: eight rare fragile sites (FRAXA [18], FRAXE [19], FRAXF [20], FRA10A [21], FRA10B [22], FRA11B [23], FRA16B [24], and FRA16A [25]), and 13 common human fragile sites (FRA1E [26], FRA2G [27], FRA3B [28], FRA4F [29], FRA6E [30], FRA6F [31], FRA7E [32], FRA7G [33], FRA7H [34], FRA9E [35], FRA13A [36], FRA16D [37], and FRAXB [38]). Whereas the expression of rare fragile sites is known to be related to the amplification of specific repeat motifs (CCG repeats and AT-rich regions), no simple repeat sequences have been found to be responsible for the instability observed at common fragile sites. Rather, they appear to have a high A/T content with fragility extending over large regions (from 150 kilobases [kb] to 1 megabase [Mb]) in which the DNA can adopt structures of high flexibility and low stability [39]. Clearly, resolution differences exist between cytogenetically defined fragile sites in human chromosomes and the molecular delimitation of evolutionary breakpoints (themselves fairly gross approximations given that radiation hybrid mapping data for five of the eight species resulted in an average of 1.2 Mb for breakpoint regions [5]). Nonetheless, the fact that fragile sites represent large 'unstable' regions of the genome [39] that in many instances span evolutionary breakpoints [7] is an observation that warrants further detailed analysis.

An intriguing aspect to emerge from comparative genomic studies performed largely on primates and rodents is the finding that breakpoint regions are rich in repetitive elements. In other words, there may be a causal link between the process of chromosome rearrangement, segmental duplications [40–44], and some simple tandem repeats (for instance, the dinucleotide [TA]n [45] and [TCTG]n, [CT]n and [GTCTCT]n [46]). In addition, microsatellites have been implicated in the mechanism underlying the chromosomal instability that characterizes some human fragile sites and constitutional human chromosomal disorders. For example, some human rare and common fragile sites have been found to be particularly rich in A/T minisatellites [39], and certain human chromosomal aberrations have been related to palindromic AT-rich repeats [47, 48], underscoring the presence of repetitive elements in regions of chromosomal instability.

With this as the background, we analyze the distribution of 1,638 syntenic blocks, 1,152 evolutionary breakpoint regions, and 2,304 evolutionary breakpoints taken from public databases available for seven eutherian species (mouse, rat, cattle, dog, pig, cat and horse) and chicken, and examine these for correspondence with fragile sites and tandem repeat locations in the human genome. We show that evolutionary breakpoints are not uniformly distributed and that there are certain human chromosomes and chromosomal bands with high breakpoint accumulation. Additionally, there is a striking correspondence between human fragile site location, the positions of evolutionary breakpoints, and the distribution of tandem repeats throughout the human genome.

Results

Multispecies alignments

We analyzed homologous regions between the human genome and those of the rat, mouse, cattle, pig, cat, horse, dog, and chicken. By using the HSBs described by Murphy and coworkers [5] and adding data from the human/chicken and human/dog whole-genome sequence assemblies, we were able to identify 1,638 syntenic blocks in the human genome (Additional data file 4). (The dog radiation hybrid genome map data used by Murphy and coworkers [5] was replaced by the dog whole-genome assembly, which is now available.) The analysis of the human/chicken and human/dog whole-genome sequence assemblies revealed a total of 550 syntenic blocks among the three compared species (Additional data file 4). The homologous chromosomal segments of the seven mammals and the chicken were plotted against the 550 band human ideogram (Additional data file 1). We excluded the human chromosome Y from our study of evolutionary breakpoint regions (see Materials and methods, below).

In addition we identified the chromosomal position of 1,152 evolutionary breakpoint regions of 4 Mb or less in size (Additional data file 5) in the human karyotype and their corresponding evolutionary breakpoints (n = 2,304; Additional data files 1 and 5). The 2,304 evolutionary breakpoints grouped within 352 evolutionary chromosomal bands, which represents 67.77% of the human genome (2,217.46 Mb of the 3,272.19 Mb of the total human genome, NCBI35; Additional data file 5). See Figure 1 for a schematic representation of evolutionary breakpoint regions, evolutionary breakpoints and evolutionary chromosomal bands, as well as the Materials and methods section (below) for definitions of these terms. Approximately 45% (159 out of 352) of the evolutionary chromosomal bands contain evolutionary breakpoints in three or more of the eight species compared herein (Additional data file 6). These data clearly show that the distribution of the evolutionary breakpoints and breakpoint regions is concentrated in specific bands and/or chromosomes.

Figure 1
figure 1

Schematic representation of evolutionary breakpoint regions, evolutionary breakpoints, and evolutionary chromosomal bands. An evolutionary breakpoint region is defined as the interval between two syntenic blocks 4 megabases (Mb) or less in size. This is done in order to avoid problems of low comparative coverage. Evolutionary breakpoints are defined by sequences coordinates in any of the seven mammalian species compared with human plus the chicken, and serve to delimit the start and end of each breakpoint region. Evolutionary chromosomal bands correspond to any band in the human ideogram that contains at least one evolutionary breakpoint in any of the eight species compared with the human genome.

An analysis of the distribution of evolutionary breakpoints among the evolutionary chromosomal bands using JMP software (see Materials and methods, below) revealed a mean of six evolutionary breakpoints per evolutionary chromosomal band. Out of the 352 evolutionary chromosomal bands that were identified, 296 contain between one and ten evolutionary breakpoints, whereas 16 human chromosomal bands contain 20 or more evolutionary breakpoints each (10p11.2, 10q11.2, 15q13, 15q24, 15q25, 17p13, 17q24, 1q42.1, 22q11.2, 2p13, 2q14.3, 3p25, 3q21, 4p16, 7q22 and 8p23.1; Additional data file 6). Otherwise stated, 4.21% of the human genome (137.9 Mb of 3,272.19 Mb) accumulates 17.79% of all evolutionary breakpoints (410 of the 2,304 identified). Similarly, not all human chromosomes have been equally affected by the evolutionary process. Human chromosomes 1, 2, 3, 4, 7, 8, 10, 15, 17, and 22 carry most of the evolutionary breakpoints, whereas human chromosomes 14 and 21 are the least frequently involved.

Distribution of evolutionary breakpoints regions, breakpoints, and fragile sites

Given the distribution of evolutionary breakpoints outlined above, we proceeded to determine whether there is a significant correlation between the position of evolutionary breakpoints and the known location of fragile sites. We mapped all fragile sites (both rare and common) and evolutionary breakpoint regions (regions ≤ 4 Mb; Table 1 and Additional data file 1) to their location on the human ideogram at the 550 band resolution. Our examination reveals that 147 chromosomal bands express fragile sites (both common and rare). A contingency analysis shows that those bands that express fragility (they contain either rare or common fragile sites) have a tendency, although not significantly so (P = 0.09), to concentrate evolutionary breakpoints as compared with bands that do not express fragile sites. In fact, we observed 104 bands that contain fragile sites (rare and common) and evolutionary breakpoints, in contrast to the 95.4 bands expected if the distribution were random. A more refined analysis was subsequently conducted in which four categories of chromosomal bands (those that contain common fragile sites, those with rare fragile sites, bands with both common and rare fragile sites, and finally bands with no fragile sites) were examined using contingency analysis. There is a significant tendency (P = 0.01) for bands with rare fragile sites to accumulate evolutionary breakpoints (22 of the 24 bands known to express rare fragile sites contain evolutionary breakpoints versus the 15.6 bands expected if the distribution were random). The same tendency does not hold in the case of common fragile sites, where 73 of 111 bands that express common fragile sites contain evolutionary breakpoints (72.2 expected), or bands that contain evolutionary breakpoints but no fragile sites (248 observed versus 256.3 expected).

Table 1 The human ideogram at the 550 band resolution showing the location of fragile sites and evolutionary breakpoints

As stated above, resolution differences exist between cytogenetically defined fragile sites in human chromosomes and the molecular delimitation of evolutionary breakpoints. That differences in resolution may confound the association between them is clearly of concern. However, of the 12 autosomal common fragile sites that have been characterized at the molecular level (Additional data file 8), six (FRA4F, FRA6E, FRA7E, FRA7G, FRA7H, and FRA9E) were shown to span evolutionary breakpoints in at least one of the species analyzed with an additional two fragile sites (FRA3B and FRA16D) located within 1 Mb of evolutionary breakpoints (Additional data file 8). Importantly, of the four autosomal common fragile sites with the highest expression frequencies (FRA3B [28], FRA6E [30], FRA7H [34], and FRA16D [37]), two (FRA6E and FRA7H) are localized within evolutionary breakpoints, and two (FRA3B and FRA16D) lie within 1 Mb of breakpoint boundaries. With respect to the eight cloned rare fragile sites [18–25], three (FRA10A, FRA16A, and FRA16B) are located in bands that contain evolutionary breakpoints in at least one of the species analyzed by us.

Distribution of tandem repeats

The distribution of tandem repeats in human chromosomes was analyzed using 250,000 bp search windows in order to determine whether there is any correspondence between tandem repeats, fragile sites (both rare and common), and the location of evolutionary breakpoints (Additional data files 2 and 8). The tandem repeats range from microsatellites (unit size 1 bp to 6 bp) to different types of minisatellites (from 7 bp to 300 bp). We identified a high concentration of tandem repeats in the telomeres and the pericentromeric regions of each chromosome (Additional data file 2), mirroring earlier findings (for instance, see Näslund and coworkers [49]). The distribution of tandem repeats (1 to 300 bp) along human chromosomes showed that on average 3,738.56 bp of the 250,000 bp of genomic sequence contained in each window comprised tandem repeats (about 1.5%). Chromosome 19 is exceptional for the high number of repeats found along its length [50], which is almost double (8,377.27 bp) the average for the whole genome (Table 2 and Additional data file 3). Additionally, chromosome 19 has been shown to be exceptional in many other genomic features, most of which (including the high number of repeats) may be due to the extremely high GC content of this chromosome [51, 52].

Table 2 Mean repeat size in base pairs per window of 0.250 megabases in each human chromosome analyzed.

Tandem repeats and evolutionary chromosomal bands

When analyzing the human genome in its entirety, but excluding the centromeric and telomeric regions from the analysis, evolutionary chromosomal bands (E bands) tend to contain significantly more (P < 0.05) tandem repeats than chromosomal bands not implicated in evolutionary change (B bands; Table 2). It is noteworthy that in the case of human chromosomes 3, 15, 17, 18, and 21, E bands contain significantly more tandem repeats than do the B bands (P < 0.05), whereas the converse holds for human chromosomes 8 and 16. In all other instances no statistically supported differences were noted. Elimination of chromosome 19 from the analysis, with its singularly high repeat content, reduces the difference between E bands and B bands but not significantly so. In addition, we detected 256 human chromosomal bands that contain regions with more than 6,000 bp of tandem repeats in the 250,000 bp of genomic sequence contained in each window. Of these high-density repeat loci, 76.95% (197 of 256) contain evolutionary breakpoints.

Tandem repeats and fragile sites

Overall, chromosomal bands that express fragile sites (rare and common combined) contain significantly more tandem repeats (P < 0.05) than do bands that do not (Table 2 and Additional data file 9). There are, however, differences evident among chromosomes. In the case of human chromosomes 1, 5, 7, 8, 11, 12, and 22, chromosomal bands that express fragile sites contain more tandem repeats than do bands that do not show fragility (P < 0.05). The converse holds for chromosomes 10, 14, 17, and 20, where regions of fragility are not characterized by elevated tandem repeat levels. In the remaining human chromosomes (2, 3, 4, 6, 9, 13, 15, 16, 18, and 19), there is no statistical relationship between those bands that express fragile sites and have high numbers of tandem repeats, and bands that do not (Table 2). Moreover, the statistically significant differences detailed above hold irrespective of whether chromosome 19 is omitted from the analysis or not. Interestingly, 62.6% (92 out of 147; Table 1) of the human bands that contain human fragile sites are localized in regions that contain high densities of repeats (for instance, regions containing >6,000 bp of tandem repeats in the 250,000 bp of genomic sequence contained in each window; see above). No fragile sites have been described in the literature for human chromosome 21.

We examined the repeat content of the four categories of chromosomal bands (those that express common fragile sites, bands with rare fragile sites, bands with both common and rare fragile sites, and finally bands that do not contain fragile sites; Additional data file 9). Those containing rare fragile sites were shown to have significantly (P < 0.05) greater numbers of tandem repeats (average of 4,852.53 bp per 250,000 bp of genomic sequence contained in each window) than any other category (3,714.86 bp per 250,000 bp of genomic sequence contained in each window in the case of common fragile sites, the next most frequent category).

Discussion

Evolutionary breakpoints

Evolutionary breakpoints can be defined by levels of resolution [53]. The holistic perspective of evolutionary breakpoints has traditionally been underpinned by molecular cytogenetic studies that assign regions of chromosomal homology to species of the same or different orders of mammals at the chromosomal band level. Investigations using comparative chromosome painting (ZOO-fluorescence in situ hybridization [ZOO-FISH]) involving more than 80 different species from almost all of the recognized eutherian orders have defined regions of the human genome that are implicated in chromosomal evolution (for review, see Froenicke [54]). The integration of cross-species chromosome painting data published from 30 nonprimate species [54], and even greater numbers of primate species [8], clearly demonstrate that evolutionary breakpoints are not uniformly distributed along the length human chromosomes, and in some cases they are conserved during chromosome evolution.

The use of whole-genome comparisons (the reductionist view) allows for the delimitation of evolutionary breakpoints at a finer level of resolution than can be obtained by chromosome painting. By analyzing published data [5], and adding complementary information from the human/chicken and human/dog whole-genome sequence assemblies, we were able to identify 1,152 evolutionary breakpoint regions throughout the human genome at a resolution of 4 Mb or less, which contain 2,304 evolutionary breakpoints. Plotting the evolutionary breakpoints included in our data onto the 550 chromosomal band human ideogram provided a means of combining the cytogenetic and the sequence comparisons. This identified 352 human chromosomal bands that contain evolutionary breakpoints and showed that the distribution of evolutionary breakpoints is not uniform in the human genome. Quite clearly, there are evolutionary 'hot spots', defined by chromosomal bands, which are coincidental with genomic reorganization characterizing different lineages during the evolutionary process (breakpoint reuse [5]).

Evolutionary implications of fragile sites

Although the exact number of fragile sites described in the human genome is a matter of interpretation, a recent revision lists 119 fragile sites, 88 of which are defined as common and 31 as rare [39]. Our data show that human chromosomal bands that express fragile sites (both common and rare combined) have a tendency to contain evolutionary breakpoints (Table 1), although the association is statistically supported only in the case of rare fragile sites. This association suggests an important role for fragile sites in genome reorganization, most likely by functioning as regions of chromosomal instability.

Although the mechanisms underlying the breakage at common fragile sites are still poorly understood, rare fragile sites are associated with the amplification of repeat motifs (CCG repeats and AT-rich regions). The molecular characterization of 13 common fragile sites has revealed that there are no simple repeat sequences responsible for their instability (for review, see Schwartz and coworkers [39] and Glover [55]). Rather they are enriched in A/T content, have the potential to form secondary structures, and contain clusters of flexible sequences (flexibility clusters). These are all features that may affect DNA replication and chromatin condensation, suggesting a common basis for fragility (presence of repeat sequences) that would characterize all fragile sites (both common and rare).

Previously, evolutionary studies involving fragile sites have attempted to address two important questions. First, because fragile sites are considered part of the chromosome structure, are the characteristics underlying their susceptibility to breakage conserved during evolution? Also, can fragile sites be considered 'targets' for evolutionary reorganization? In terms of the first question recent studies have shown that some human common fragile sites have been conserved in homologous regions in mouse and some primate species [29, 56, 57], suggesting that the characteristics governing a chromatid's susceptibility to breakage are conserved during evolution. The high degree of correspondence between the location of fragile sites and evolutionary breakpoints shown by our study has a bearing on the second question posed above, namely whether fragile sites are 'targets' for evolutionary reorganization. Comparative cytogenetic studies performed in primate families such as Hominidae, Cebidae, and Cercopithecidae [7, 16, 58–60] revealed that a high proportion of chromosomal bands implicated in evolutionary reorganization, centromeric shifts, and delimiting heterochromatic regions also contain fragile sites in the human genome. By increasing the number of species analyzed (mouse, rat, cattle, dog, pig, cat, horse, and chicken), as well as improving the resolution of evolutionary breakpoints using whole-genome comparisons, we have been able to draw more precise conclusions on the distribution of evolutionary breakpoints and their correspondence to human bands that are known to contain fragile sites. Our data show that fragile sites appear to be conserved as 'fragile chromosomal bands', in which evolutionary breakpoints accumulate in much the same way that human fragile sites may be considered to signal regions of chromosomal instability observed in cancer cells [61].

Repetitive DNA, fragile sites and chromosomal evolution

Given the 'hot spot' theory, one may question whether repetitive elements are driving chromosomal evolution by triggering reorganization in these regions (for instance, see the reports by Armengol [42] and Cáceres [62] and their coworkers) or, alternatively, that the repeats accumulate preferentially in these regions following reorganization. That our study shows that rare fragile sites in particular have a highly significant association (P = 0.01) with both evolutionary breakpoints and tandem repeats has important implications for the role of this particular type of fragile site in chromosomal instability, and hence genome evolution. The molecular characterization of chromosomal regions implicated in evolutionary breakpoints in human, mouse, and primate genomes has similarly shown that large-scale reorganization tends to occur at, or close to, regions rich in segmental duplications and some type of simple tandem repeat (for example, the dinucleotide [TA]n) [41, 63–65].

The analysis of the distribution of tandem repeats in human chromosomes and their spatial relationship to evolutionary breakpoints presented here highlights two important points. First, it emphasizes the high concentration of base pair repeats found at the telomeres and the pericentromeric areas (which is in agreement with previous reports on the distribution of duplicated regions; see Murphy and coworkers [5]), and the distribution of polymorphic minisatellites [49] throughout the human genome. The second, possibly more remarkable finding is the concentration of tandem repeats at evolutionary chromosomal bands. Although this is by no means ubiquitous, the correspondence is typified by human chromosome 3 (Table 2 and Additional data file 1). Bands with the greatest number of tandem repeats in this chromosome (3p25, 3p21.3, 3p12, 3q13.1, 3q21, and 3q29) are also chromosomal regions that have been implicated in evolutionary rearrangements. It is noteworthy that the chromosomal bands 3p25, 3p21, 3p12, and 3q21 have previously been identified as breakpoints in primate evolution [66], and that the evolutionary breakpoints at 3p25.1, 3p12.3, and 3q21.3 are associated with duplications in hominid evolution [67–69].

In particular, human chromosome 7 (Figure 2a) is interesting both from the evolutionary as well as clinical perspective. Our analysis shows that there are six bands on this chromosome that contain the greatest concentration of tandem repeats in the human genome: 7p22, 7p13, 7p11, 7q11, 7q22, and 7q36. All six bands incorporate fragile sites (FRA7B, FRA7D, FRA7A, FRA7J, FRA7F, and FRA7I) and all but one of them (7p13) correspond to regions where evolutionary breakpoints tend to concentrate, as indicated by comparisons of the human genome with those of mouse, rat, cattle, pig, dog, cat, chicken (present study), and different primate species [8]. Three of these chromosomal bands (7p22, 7q11, and 7q22) appear to be the boundaries for mammalian ancestral chromosomes 7a and 7b (Figure 2a) and have been implicated in almost all mammalian species studied to date by comparative chromosome painting using human painting probes [8, 54]. A recent study of the evolutionary history of human chromosome 7 [70] demonstrated that this chromosome may be derived from the orangutan homolog by two inversions (one paracentric and another pericentric) that involved three chromosomal breakpoints that map to 7p22.1, 7q11.23, and 7q22.1 in human (one of these, 7q22.1, is common to both rearrangements). All three bands have the greatest number of tandem repeats (present study) and are particularly rich in segmental duplications [40]. Moreover, they are considered 'hot spots' for human diseases such as the Williams-Beuren syndrome [71, 72] and leukemias [73].

Figure 2
figure 2

Multispecies alignments to human chromosomes. Shown are the multispecies alignments of human chromosomes (a) 7 and (b) 12. Red bars represent the homology synteny blocks (HSBs) in the seven eutherian species that were compared in our analyses. Black bars represent the regions of homology to the chicken genome [74]. Segments 7a (red), 7b (blue), 12a (green), and 12b (pink) are portions of human chromosomes comprising the ancestral eutherian karyotype [8,22]. The location of human fragile sites (FRA) is given to the left of the ideogram of each human chromosome: red for common fragile sites and blue for rare fragile sites. The distribution of tandem repeats along these human chromosomes is shown on the extreme right. The high concentrations of tandem repeats in the pericentromeric and telomeric areas of each chromosome have been the omitted to provide clearer resolution of the distribution of repeats elsewhere on the chromosomes (see text for details).

Other notable associations between tandem repeats, fragile site location, and evolutionary breakpoints include the greatest concentration of tandem repeats found in the human genome - those in bands 12q13.1 and 12q24. The band 12q13.1 contains one fragile site (FRA12A) and two evolutionary breakpoints, whereas 12q24 contains three fragile sites (FRA12C, FRA12D, and FRA12E) and seven evolutionary breakpoints (Figure 2b). Human chromosome 12 is considered to be the result of the fusion of two ancestral chromosomal segments 12a and 12b (Figure 2b) that are thought to have occurred in the Simiiformes (Catarrhini and Platyrrhini) ancestor. Chromosomal band 12q24 forms the boundary of these segments [8], once again highlighting a chromosomal region that is characterized both by its fragility and involvement in evolutionary change.

Conclusion

Our results provide clear evidence of the existence of chromosomal regions in the human genome that have been repeatedly used in the evolutionary process, thus confirming and extending earlier observations [2, 5, 8]. As a consequence, the human genome can be considered a mosaic comprising regions of fragility that are prone to reorganization that have been conserved in different lineages during the evolutionary process, and regions that do not exhibit the same levels of evolutionary plasticity. Although we cannot unequivocally suggest a mechanistic role for tandem repeats and fragile sites in sculpting modern genomes, our data will serve to focus further detailed investigations on this fundamental aspect of genome evolution.

Materials and methods

Whole-genome comparisons and breakpoints analysis

The Ensembl genome browser of Sanger Center and EMBL [74] as well as published data [5] were used as sources for determining homologies between the human genome and those of the mouse, rat, cattle, pig, dog, cat, horse, and chicken. We used the sequence coordinates described by Murphy and coworkers [5] to delimit homologous synteny blocks (HSBs), where the data from cattle, pig, cat, and horse are based on RH maps; the homologous regions between human, rat, and mouse are based on whole-genome assemblies. To determine syntenic regions between the human genome (NCBI Build 35) and that of the dog and chicken, we used the completed human/chicken (WASHUC 1) and human/dog (CanFam 1.0) whole-genome sequence assemblies available from the Ensembl genome browser. In the case of the dog and chicken we analyzed homologous syntenic blocks that varied in size between 0.1 Mb and 84 Mb (Additional data file 4), according to the Ensembl genome browser.

For all species analyzed, we follow Murphy and coworkers [5] in viewing an 'evolutionary breakpoint region' as the interval between two syntenic blocks. As did those authors, we use evolutionary breakpoint regions that are 4 Mb in size or less in order to avoid problems of low comparative coverage. 'Evolutionary breakpoints' are defined by sequence coordinates in any of the seven mammalian species compared with human plus the chicken. They serve to delimit the start and end of each breakpoint region. Likewise, the limits of each chromosomal band in the human karyotype can be defined by sequence coordinates using the Ensembl database [74]. Following this procedure, evolutionary breakpoints of each homologous segment were mapped to the human ideogram at the 550 band resolution, allowing us to identify 'evolutionary chromosomal bands' (E bands), which are defined as any band in the human ideogram that contains at least one evolutionary breakpoint in any of the eight species compared with the human genome (Figure 1). We used the JMP software (version 5.1.2; SAS Institute Inc., Cary, NC, USA) to investigate the distribution of evolutionary breakpoints.

Fragile site analysis

The data reported by Schwartz and coworkers [39] were used as reference for the location, classification, and number of fragile sites described in the human genome. Human fragile sites may be classified into two groups based on frequency of occurrence and mechanisms of expression, and are generally referred to as either common or rare fragile sites [17]. In this investigation we considered a total of 119 fragile sites [39], of which 88 are defined as common and 31 as rare fragile sites (Additional data file 7). These were mapped to specific chromosomal bands on the human ideogram at the 550 band resolution (Table 1). The evolutionary chromosome breakpoint boundaries, each identified by human reference coordinates (see above), were similarly treated in order to determine whether these fell within a specific chromosomal band region that is known to express fragility. It is important to note that in some cases a chromosomal band described as containing a fragile site in the literature can, at higher resolution (for example, the 550 band ideogram), be shown to comprise several sub-bands. For example, the common fragile site FRAJ is mapped to 7q11, which corresponds to four sub-bands in the 550 band ideogram (7q11.1, 7q11.21, 7q11.22, and 7q11.23).

We defined the chromosomal location of 12 autosomal common fragile sites that have been characterized at the molecular level by the position provided by the Ensembl [74] and NIH databases [75] for the molecular markers and/or the BAC clones described in the original papers (Additional data file 8). These fragile sites were examined to determine whether any evolutionary breakpoint spanned these regions in at least one of the species compared herein.

Tandem repeat analysis

We analyzed the distribution of tandem repeats in the human genome sequence (NCBI Build 35) using the 'Tandem Repeats Finder' (TRF) algorithm (version 3.21 [76]) in all human chromosomes (HSA) except HSA X and HSA Y. The complete sequences of each chromosome were scanned for tandem repeats using the program TRF with the parameters established by default (+2 -7 -7 0.80 0.10 50 500).

We scrutinized each chromosome's complete sequence using moving non-overlapping windows of 0.250 Mb in order to analyze the density and distribution of tandem repeats in the human genome. Given the high incidence of repeats at the telomeres/subtelomeric and the centromeric/pericentromeric areas [49] (confirmed by our study; Additional data file 9), we excluded a 3 Mb section at each of these localities, which are referred to herein as the T (telomeric) and C (centromeric) regions. A further classification involves chromosomal bands that contain evolutionary breakpoints in at least one of the eight species compared with the human genome (E bands); all remaining bands were designated as B bands (for example, non-evolutionary chromosomal bands). Additionally, the presence/absence of a fragile site (rare or common) was recorded for each chromosomal band based on their published location [39], as defined in the human ideogram at the 550 band resolution (Additional data file 9). Tukey-Kramer tests were used (JMP package version 5.1.2; SAS Institute Inc.) to evaluate whether tandem repeats concentrate significantly (P ≤ 0.05) in evolutionary chromosomal bands (E bands) and/or fragile sites (FS bands). In both cases, the centromeric and telomeric regions were excluded before statistical analysis because they had much higher repeat values overall.

Additional data files

The following additional data are available with the online version of this paper. Additional data file 1 is a figure showing the multispecies alignments of all human chromosomes. Additional data file 2 is a figure showing the distribution of base pair tandem repeats along all human chromosomes represented as windows of 250,000 bp each. Additional data file 3 is a figure showing base pairs implicated in tandem repeats per chromosome. Additional data file 4 is a table listing all of the homologous syntenic blocks (HSB) detected. Additional data file 5 is a table listing evolutionary breakpoint regions (EBR) less than 4 Mb and their chromosomal positions in the human genome. Additional data file 6 is a table listing the evolutionary chromosomal bands detected. Additional data file 7 is a table listing all human fragile sites described in the literature. Additional data file 8 is a table listing common human fragile sites that have been cloned and analyzed at the molecular level. Additional data file 9 is a table showing the human genome divided into windows of 0.250 Mb.

References

  1. Nadeau JH, Taylor BA: Lengths of chromosomal segments conserved since divergence of man and mouse. Proc Natl Acad Sci USA. 1984, 81: 814-818. 10.1073/pnas.81.3.814.

    Article  PubMed  PubMed Central  Google Scholar 

  2. Pevzner P, Tesler G: Human and mouse genomic sequences reveal extensive breakpoint reuse in mammalian evolution. Proc Natl Acad Sci USA. 2003, 100: 7672-7677. 10.1073/pnas.1330369100.

    Article  PubMed  PubMed Central  Google Scholar 

  3. Zhao S, Shetty J, Hou L, Delcher A, Zhu B, Osoegawa K, de Jong P, Nierman WC, Strausberg RL, Fraser CM: Human, mouse, and rat genome large-scale rearrangements: stability versus speciation. Genome Res. 2004, 14: 1851-1860. 10.1101/gr.2663304.

    Article  PubMed  PubMed Central  Google Scholar 

  4. Peng Q, Pevzner PA, Tesler G: The fragile breakage versus random breakage models of chromosome evolution. PLoS Comput Biol. 2006, 2: e14-10.1371/journal.pcbi.0020014.

    Article  PubMed  PubMed Central  Google Scholar 

  5. Murphy WJ, Larkin DM, Everts-van der Wind A, Bourque G, Tesler G, Auvil L, Beever JE, Chowdhary BP, Galibert F, Gatzke L, et al: Dynamics of mammalian chromosome evolution inferred from multispecies comparative maps. Science. 2005, 309: 613-617. 10.1126/science.1111387.

    Article  PubMed  Google Scholar 

  6. Robinson TJ, Ruiz-Herrera A, Froenicke L: Dissecting the mammalian genome - new insights into chromosomal evolution. Trends Genet. 2006, 22: 297-301. 10.1016/j.tig.2006.04.002.

    Article  PubMed  Google Scholar 

  7. Ruiz-Herrera A, Ponsà M, García F, Egozcue J, Garcia M: Fragile sites in human and Macaca fascicularis are breakpoints in chromosome evolution. Chromosome Res. 2002, 10: 33-44. 10.1023/A:1014261909613.

    Article  PubMed  Google Scholar 

  8. Ruiz-Herrera A, García F, Mora L, Egozcue J, Ponsà M, Garcia M: Evolutionary chromosomal segments in the human karyotype are bounded by unstable chromosome bands. Cytogenet Genome Res. 2005, 108: 161-174. 10.1159/000080812.

    Article  PubMed  Google Scholar 

  9. Sutherland GR: Heritable fragile sites on human chromosomes I. Factors affecting expression in lymphocyte culture. Am J Hum Genet. 1979, 31: 125-135.

    PubMed  PubMed Central  Google Scholar 

  10. Robinson TJ, Elder FF: Multiple common fragile sites are expressed in the genome of the laboratory rat. Chromosoma. 1987, 96: 45-49. 10.1007/BF00285882.

    Article  PubMed  Google Scholar 

  11. Stone DM, Stephens KE: Bromodeoxyuridine induces chromosomal fragile sites in the canine genome. Am J Med Genet. 1993, 46: 198-202. 10.1002/ajmg.1320460220.

    Article  PubMed  Google Scholar 

  12. Kubo K, Matsuyama S, Sato K, Shiomi A, Ono K, Ito Y, Ohashi F, Takamori Y: Novel putative fragile sites observed in feline fibroblasts treated with aphidicolin and fluorodeoxyuridine. J Vet Med Sci. 1998, 60: 809-813. 10.1292/jvms.60.809.

    Article  PubMed  Google Scholar 

  13. Ronne M: Putative fragile sites in the horse karyotype. Hereditas. 1992, 117: 127-136.

    Article  PubMed  Google Scholar 

  14. Rodríguez V, Llambi S, Postiglioni A, Guevara K, Rincon G, Fernan G, Mernies B, Arruga MV: Localisation of aphidicolin-induced break points in Holstein-Friesian cattle (Bos taurus) using RBG-banding. Genet Sel Evol. 2002, 34: 649-656. 10.1051/gse:2002029.

    Article  PubMed  PubMed Central  Google Scholar 

  15. Smeets DF, van de Klundert FA: Common fragile sites in man and three closely related primate species. Cytogenet Cell Genet. 1990, 53: 8-14.

    Article  PubMed  Google Scholar 

  16. Ruiz-Herrera A, García F, Giulotto E, Attolini C, Egozcue J, Ponsà M, Garcia M: Evolutionary breakpoints are co-localized with fragile sites and intrachromosomal telomeric sequences in primates. Cytogenet Genome Res. 2005, 108: 234-247. 10.1159/000080822.

    Article  PubMed  Google Scholar 

  17. Sutherland GR, Richards RI: Fragile sites-cytogenetic similarity with molecular diversity. Am J Hum Genet. 1999, 64: 354-359. 10.1086/302267.

    Article  PubMed  PubMed Central  Google Scholar 

  18. Kremer EJ, Pritchard M, Lynch M, Yu S, Holman K, Baker E, Warren ST, Schlessinger D, Sutherland GR, Richards RI: Mapping of DNA instability at the fragile X to a trinucleotide repeat sequence p(CCG)n. Science. 1991, 252: 1711-1714. 10.1126/science.1675488.

    Article  PubMed  Google Scholar 

  19. Knight SJ, Flannery AV, Hirst MC, Campbell L, Christodoulou Z, Phelps SR, Pointon J, Middleton-Price HR, Barnicoat A, Pembrey ME, et al: Trinucleotide repeat amplification and hypermethylation of a CpG island in FRAXE mental retardation. Cell. 1993, 74: 127-134. 10.1016/0092-8674(93)90300-F.

    Article  PubMed  Google Scholar 

  20. Parrish JE, Oostra BA, Verkerk AJ, Richards CS, Reynolds J, Spikes AS, Shaffer LG, Nelson DL: Isolation of a GCC repeat showing expansion in FRAXF, a fragile site distal to FRAXA and FRAXE. Nat Genet. 1994, 8: 229-235. 10.1038/ng1194-229.

    Article  PubMed  Google Scholar 

  21. Sarafidou T, Kahl C, Martinez-Garay I, Mangelsdorf M, Gesk S, Baker E, Kokkinaki M, Talley P, Maltby EL, French L, et al: Folate-sensitive fragile site FRA10A is due to an expansion of a CGG repeat in a novel gene, FRA10AC1, encoding a nuclear protein. Genomics. 2004, 84: 69-81. 10.1016/j.ygeno.2003.12.017.

    Article  PubMed  Google Scholar 

  22. Hewett DR, Handt O, Hobson L, Mangelsdorf M, Eyre HJ, Baker E, Sutherland GR, Schuffenhauer S, Mao JI, Richards RI: FRA10B structure reveals common elements in repeat expansion and chromosomal fragile site genesis. Mol Cell. 1998, 1: 773-781. 10.1016/S1097-2765(00)80077-5.

    Article  PubMed  Google Scholar 

  23. Jones C, Slijepcevic P, Marsh S, Baker E, Langdon W, Richards RI, Tunnacliffe A: Physical linkage of the fragile site FRA11B and a Jacobsen syndrome chromosome deletion breakpoint in 11q23.3. Hum Mol Genet. 1994, 3: 2123-2130.

    Article  PubMed  Google Scholar 

  24. Yu S, Mangelsdorf M, Hewett D, Hobson L, Baker E, Eyre HJ, Lapsys N, Le Paslier D, Doggett NA, Sutherland GR, Richards RI: Human chromosomal fragile site FRA16B is an amplified AT-rich minisatellite repeat. Cell. 1997, 88: 367-374. 10.1016/S0092-8674(00)81875-9.

    Article  PubMed  Google Scholar 

  25. Nancarrow J, Kremer E, Holman K, Eyre H, Doggett NA, Le Paslier D, Callen DF, Sutherland GR, Richards RI: Implications of FRA16A structure for the mechanism of chromosomal fragile site genesis. Science. 1994, 264: 1938-1941. 10.1126/science.8009225.

    Article  PubMed  Google Scholar 

  26. Hormozian F, Schmitt JG, Sagulenko E, Schwab M, Savelyeva L: FRA1E common fragile site breaks map within a 370 kilobase pair region and disrupt the dihydropyrimidine dehydrogenase gene (DPYD). Cancer Lett. 2006

    Google Scholar 

  27. Limongi MZ, Pelliccia F, Rocchi A: Characterization of the human common fragile site FRA2G. Genomics. 2003, 81: 93-97. 10.1016/S0888-7543(03)00007-7.

    Article  PubMed  Google Scholar 

  28. Wilke CM, Hall BK, Hoge A, Paradee W, Smith DI, Glover TW: FRA3B extends over a broad region and contains a spontaneous HPV16 integration site: direct evidence for the coincidence of viral integration sites and fragile sites. Hum Mol Genet. 1996, 5: 187-195. 10.1093/hmg/5.2.187.

    Article  PubMed  Google Scholar 

  29. Rozier L, El-Achkar E, Apiou F, Debatisse M: Characterization of a conserved aphidicolin-sensitive common fragile site at human 4q22 and mouse 6C1: possible association with an inherited disease and cancer. Oncogene. 2004, 23: 6872-6880. 10.1038/sj.onc.1207809.

    Article  PubMed  Google Scholar 

  30. Denison SR, Callahan G, Becker NA, Phillips LA, Smith DI: Characterization of FRA6E and its potential role in autosomal recessive juvenile parkinsonism and ovarian cancer. Genes Chromosomes Cancer. 2003, 38: 40-52. 10.1002/gcc.10236.

    Article  PubMed  Google Scholar 

  31. Morelli C, Karayianni E, Magnanini C, Mungall AJ, Thorland E, Negrini M, Smith DI, Barbanti-Brodano G: Cloning and characterization of the common fragile site FRA6F harboring a replicative senescence gene and frequently deleted in human tumors. Oncogene. 2002, 21: 7266-7276. 10.1038/sj.onc.1205573.

    Article  PubMed  Google Scholar 

  32. Zlotorynski E, Rahat A, Skaug J, Ben-Porat N, Ozeri E, Hershberg R, Levi A, Scherer SW, Margalit H, Kerem B: Molecular basis for expression of common and rare fragile sites. Mol Cell Biol. 2003, 23: 7143-7151. 10.1128/MCB.23.20.7143-7151.2003.

    Article  PubMed  PubMed Central  Google Scholar 

  33. Hellman A, Zlotorynski E, Scherer SW, Cheung J, Vincent JB, Smith DI, Trakhtenbrot L, Kerem B: A role for common fragile site induction in amplification of human oncogenes. Cancer Cell. 2002, 1: 89-97. 10.1016/S1535-6108(02)00017-X.

    Article  PubMed  Google Scholar 

  34. Mishmar D, Rahat A, Scherer SW, Nyakatura G, Hinzmann B, Kohwi Y, Mandel-Gutfroind Y, Lee JR, Drescher B, Sas DE, et al: Molecular characterization of a common fragile site (FRA7H) on human chromosome 7 by the cloning of a simian virus 40 integration site. Proc Natl Acad Sci USA. 1998, 95: 8141-8146. 10.1073/pnas.95.14.8141.

    Article  PubMed  PubMed Central  Google Scholar 

  35. Callahan G, Denison SR, Phillips LA, Shridhar V, Smith DI: Characterization of the common fragile site FRA9E and its potential role in ovarian cancer. Oncogene. 2003, 22: 590-601. 10.1038/sj.onc.1206171.

    Article  PubMed  Google Scholar 

  36. Savelyeva L, Sagulenko E, Schmitt JG, Schwab M: The neurobeachin gene spans the common fragile site FRA13A. Hum Genet. 2006, 118: 551-558. 10.1007/s00439-005-0083-z.

    Article  PubMed  Google Scholar 

  37. Krummel KA, Roberts LR, Kawakami M, Glover TW, Smith DI: The characterization of the common fragile site FRA16D and its involvement in multiple myeloma translocations. Genomics. 2000, 69: 37-46. 10.1006/geno.2000.6321.

    Article  PubMed  Google Scholar 

  38. Arlt MF, Miller DE, Beer DG, Glower TW: Molecular characterization of FRAXB and comparative common fragile site instability in cancer cells. Genes Chromosomes Cancer. 2002, 33: 82-92. 10.1002/gcc.10000.

    Article  PubMed  Google Scholar 

  39. Schwartz M, Zlotorynski E, Kerem B: The molecular basis of common and rare fragile sites. Cancer Lett. 2006, 232: 13-26. 10.1016/j.canlet.2005.07.039.

    Article  PubMed  Google Scholar 

  40. Bailey JA, Baertsch R, Kent WJ, Haussler D, Eichler EE: Hotspots of mammalian chromosomal evolution. Genome Biol. 2004, 5: R23-10.1186/gb-2004-5-4-r23.

    Article  PubMed  PubMed Central  Google Scholar 

  41. Kehrer-Sawatzki H, Sandig CA, Goidts V, Hameister H: Breakpoint analysis of the pericentric inversion between chimpanzee chromosome 10 and the homologous chromosome 12 in humans. Cytogenet Genome Res. 2005, 108: 91-97. 10.1159/000080806.

    Article  PubMed  Google Scholar 

  42. Armengol L, Marques-Bonet T, Cheung J, Khaja R, Gonzalez JR, Scherer SW, Navarro A, Estivill X: Murine segmental duplications are hot spots for chromosome and gene evolution. Genomics. 2005, 86: 692-700. 10.1016/j.ygeno.2005.08.008.

    Article  PubMed  Google Scholar 

  43. Bailey JA, Gu Z, Clark RA, Reinert K, Samonte RV, Schwartz S, Adams MD, Myers EW, Li PW, Eichler EE: Recent segmental duplications in the human genome. Science. 2002, 297: 1003-1007. 10.1126/science.1072047.

    Article  PubMed  Google Scholar 

  44. Stankiewicz P, Shaw CJ, Withers M, Inoue K, Lupski JR: Serial segmental duplications during primate evolution result in complex human genome architecture. Genome Res. 2004, 14: 2209-2220. 10.1101/gr.2746604.

    Article  PubMed  PubMed Central  Google Scholar 

  45. Kehrer-Sawatzki H, Sandig C, Chuzhanova N, Goidts V, Szamalek JM, Tanzer S, Muller S, Platzer M, Cooper DN, Hameister H: Breakpoint analysis of the pericentric inversion distinguishing human chromosome 4 from the homologous chromosome in the chimpanzee (Pan troglodytes). Hum Mutat. 2005, 25: 45-55. 10.1002/humu.20116.

    Article  PubMed  Google Scholar 

  46. Puttagunta R, Gordon LA, Meyer GE, Kapfhamer D, Lamerdin JE, Kantheti P, Portman KM, Chung WK, Jenne DE, Olsen AS, Burmeister M: Comparative maps of human 19p13.3 and mouse chromosome 10 allow identification of sequences at evolutionary breakpoints. Genome Res. 2000, 10: 1369-1380. 10.1101/gr.145200.

    Article  PubMed  PubMed Central  Google Scholar 

  47. Kurahashi H, Shaikh TH, Emanuel BS: Alu-mediated PCR artifacts and the constitutional t(11;22) breakpoint. Hum Mol Genet. 2000, 9: 2727-2732. 10.1093/hmg/9.18.2727.

    Article  PubMed  Google Scholar 

  48. Kato T, Inagaki H, Yamada K, Kogo H, Ohye T, Kowa H, Nagaoka K, Taniguchi M, Emanuel BS, Kurahashi H: Genetic variation affects de novo translocation frequency. Science. 2006, 311: 971-10.1126/science.1121452.

    Article  PubMed  PubMed Central  Google Scholar 

  49. Näslund K, Saetre P, von Salome J, Bergstrom TF, Jareborg N, Jazin E: Genome-wide prediction of human VNTRs. Genomics. 2005, 85: 24-35. 10.1016/j.ygeno.2004.10.009.

    Article  PubMed  Google Scholar 

  50. Boby T, Patch AM, Aves SJ: TRbase: a database relating tandem repeats to disease genes for the human genome. Bioinformatics. 2005, 21: 811-816. 10.1093/bioinformatics/bti059.

    Article  PubMed  Google Scholar 

  51. Castresana J: Genes on human chromosome 19 show extreme divergence from the mouse orthologues and a high GC content. Nucleic Acids Res. 2002, 30: 1751-1756. 10.1093/nar/30.8.1751.

    Article  PubMed  PubMed Central  Google Scholar 

  52. Castresana J, Guigó R, Alba MM: Clustering of genes coding for DNA binding proteins in a region of atypical evolution of the human genome. J Mol Evol. 2004, 59: 72-79. 10.1007/s00239-004-2605-z.

    Article  PubMed  Google Scholar 

  53. Eichler EE, Sankoff D: Structural dynamics of eukaryotic chromosome evolution. Science. 2003, 301: 793-797. 10.1126/science.1086132.

    Article  PubMed  Google Scholar 

  54. Froenicke F: Origins of primate chromosomes - as delineated by Zoo-FISH and alignments of human and mouse draft genome sequences. Cytogenet Genome Res. 2005, 108: 122-138. 10.1159/000080810.

    Article  PubMed  Google Scholar 

  55. Glover TW: Common fragile sites. Cancer Lett. 2006, 232: 4-12. 10.1016/j.canlet.2005.08.032.

    Article  PubMed  Google Scholar 

  56. Glover TW, Hoge AW, Miller DE, Ascara-Wilke JE, Adam AN, Dagenais SL, Wilke CM, Dierick HA, Beer DG: The murine Fhit gene is highly similar to its human orthologue and maps to a common fragile site region. Cancer Res. 58: 3409-3414.

  57. Ruiz-Herrera A, García F, Froenicke L, Ponsà M, Egozcue J, Garcia M, Stanyon R: Conservation of aphidicolin-induced fragile sites in Papionini (Primates) species and man. Chromosome Res. 2004, 12: 683-690. 10.1023/B:CHRO.0000045753.88789.ea.

    Article  PubMed  Google Scholar 

  58. Miró R, Clemente IC, Fuster C, Egozcue J: Fragile sites, chromosome evolution, and human neoplasia. Hum Genet. 1987, 75: 345-349. 10.1007/BF00284105.

    Article  PubMed  Google Scholar 

  59. Clemente IC, Garcia M, Ponsà M, Egozcue J: High resolution chromosome banding in Cebus apella, Cebus albifrons and Lagothrix lagothricha: comparison with the human karyotype. Am J Primatol. 1987, 13: 23-36. 10.1002/ajp.1350130105.

    Article  Google Scholar 

  60. Clemente IC, Ponsà M, Garcia M, Egozcue J: Chromosome evolution in the Cercopithecidae and its relationship to human fragile sites and neoplasia. Int J Primatol. 1990, 11: 377-398. 10.1007/BF02193007.

    Article  Google Scholar 

  61. Casper AM, Nghiem P, Arlt MF, Glover TW: ATR regulates fragile site stability. Cell. 2002, 111: 779-789. 10.1016/S0092-8674(02)01113-3.

    Article  PubMed  Google Scholar 

  62. Cáceres M, Ranz JM, Barbadilla A, Long M, Ruiz A: Generation of a widespread Drosophila inversion by a transposable element. Science. 1999, 285: 415-418. 10.1126/science.285.5426.415.

    Article  PubMed  Google Scholar 

  63. Fan Y, Linardopoulou E, Friedman C, Williams E, Trask BJ: Genomic structure and evolution of the ancestral chromosome fusion site in 2q13-2q14.1 and paralogous regions on other human chromosomes. Genome Res. 2002, 12: 1651-1662. 10.1101/gr.337602.

    Article  PubMed  PubMed Central  Google Scholar 

  64. Kehrer-Sawatzki H, Schreiner B, Tanzer S, Platzer M, Muller S, Hameister H: Molecular characterization of the pericentric inversion that causes differences between chimpanzee chromosome 19 and human chromosome 17. Am J Hum Genet. 2002, 71: 375-388. 10.1086/341963.

    Article  PubMed  PubMed Central  Google Scholar 

  65. Locke DP, Archidiacono N, Misceo D, Cardone MF, Deschamps S, Roe B, Rocchi M, Eichler EE: Refinement of a chimpanzee pericentric inversion breakpoint to a segmental duplication cluster. Genome Biol. 2003, 4: R50-10.1186/gb-2003-4-8-r50.

    Article  PubMed  PubMed Central  Google Scholar 

  66. Tsend-Ayush E, Grutzner F, Yue Y, Grossmann B, Hansel U, Sudbrak R, Haaf T: Plasticity of human chromosome 3 during primate evolution. Genomics. 2004, 83: 193-202. 10.1016/j.ygeno.2003.08.012.

    Article  PubMed  Google Scholar 

  67. Yue Y, Grossmann B, Ferguson-Smith M, Yang F, Haaf T: Comparative cytogenetics of human chromosome 3q21.3 reveals a hot spot for ectopic recombination in hominoid evolution. Genomics. 2005, 85: 36-47. 10.1016/j.ygeno.2004.10.007.

    Article  PubMed  Google Scholar 

  68. Yue Y, Grossmann B, Tsend-Ayush E, Grutzner F, Ferguson-Smith MA, Yang F, Haaf T: Genomic structure and paralogous regions of the inversion breakpoint occurring between human chromosome 3p12.3 and orangutan chromosome 2. Cytogenet Genome Res. 2005, 108: 98-105. 10.1159/000080807.

    Article  PubMed  Google Scholar 

  69. Yue Y, Tsend-Ayush E, Grutzner F, Grossmann B, Haaf T: Segmental duplication associated with evolutionary instability of human chromosome 3p25.1. Cytogenet Genome Res. 2006, 112: 202-207. 10.1159/000089871.

    Article  PubMed  Google Scholar 

  70. Müller S, Finelli P, Neusser M, Wienberg J: The evolutionary history of human chromosome 7. Genomics. 2004, 84: 458-467. 10.1016/j.ygeno.2004.05.005.

    Article  PubMed  Google Scholar 

  71. Antonell A, de Luis O, Domingo-Roura X, Perez-Jurado LA: Evolutionary mechanisms shaping the genomic structure of the Williams-Beuren syndrome chromosomal region at human 7q11.23. Genome Res. 2005, 15: 1179-1188. 10.1101/gr.3944605.

    Article  PubMed  PubMed Central  Google Scholar 

  72. Perez-Jurado LA, Wang YK, Peoples R, Coloma A, Cruces J, Francke U: A duplicated gene in the breakpoint regions of the 7q11.23 Williams-Beuren syndrome deletion encodes the initiator binding protein TFII-I and BAP-135, a phosphorylation target of BTK. Hum Mol Genet. 1998, 7: 325-334. 10.1093/hmg/7.3.325.

    Article  PubMed  Google Scholar 

  73. Curtiss NP, Bonifas JM, Lauchle JO, Balkman JD, Kratz CP, Emerling BM, Green ED, Le Beau MM, Shannon KM: Isolation and analysis of candidate myeloid tumor suppressor genes from a commonly deleted segment of 7q22. Genomics. 2005, 85: 600-607. 10.1016/j.ygeno.2005.01.013.

    Article  PubMed  Google Scholar 

  74. The Ensembl genome browser of Sanger Center and EMBL database. [http://www.ensembl.org]

  75. The NIH database. [http://www.ncbi.nlm.nih.gov]

  76. Benson G: Tandem repeats finder: a program to analyze DNA sequences. Nucleic Acids Res. 1999, 27: 573-580. 10.1093/nar/27.2.573.

    Article  PubMed  PubMed Central  Google Scholar 

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Acknowledgements

Financial support to TJR (GUN 2053812) from the National Research Foundation, South Africa is gratefully acknowledged. ARH is a postdoctoral fellow in the Evolutionary Genomics Group, and is supported by grants from the University of Stellenbosch and the Spanish Ministry of Education and Science (MEC). We thank Drs L Froenicke and M Garcia Caldès, and two anonymous reviewers for providing insightful comments on an earlier version of this paper.

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Additional data file 1: Multispecies alignments to all human chromosomes. (PDF 144 KB)

13059_2006_1383_MOESM2_ESM.pdf

Additional data file 2: Distribution of base pair tandem repeats along all human chromosomes represented as windows of 250,000 bp each. (PDF 184 KB)

Additional data file 3: Base pairs implicated in tandem repeats per chromosome. (PDF 134 KB)

Additional data file 4: List of all of the homologous syntenic blocks (HSB) detected. (PDF 179 KB)

13059_2006_1383_MOESM5_ESM.pdf

Additional data file 5: List of evolutionary breakpoint regions (EBR) less than 4 Mb and their chromosomal positions in the human genome. (PDF 133 KB)

Additional data file 6: List of evolutionary chromosomal bands detected. (PDF 108 KB)

Additional data file 7: List of all human fragile sites described in the literature. (PDF 86 KB)

13059_2006_1383_MOESM8_ESM.pdf

Additional data file 8: List of common human fragile sites that have been cloned and analyzed at the molecular level. (PDF 123 KB)

Additional data file 9: Human genome divided into windows of 0.250 Mb. (PDF 387 KB)

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Ruiz-Herrera, A., Castresana, J. & Robinson, T.J. Is mammalian chromosomal evolution driven by regions of genome fragility?. Genome Biol 7, R115 (2006). https://doi.org/10.1186/gb-2006-7-12-r115

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