Structural Organization of the Human Genome: Distribution of Nucleotides,AluRepeats, and Exons in Chromosomes 21 and 22

Analysis of DNA sequences of the human chromosomes 21 and 22 performed using a specially designed MegaGene software allowed us to obtain the following results. Purine and pyrimidine nucleotide residues are unevenly distributed along both chromosomes, displaying maxima and minima (waves) with a period of about 3 Mbp. Distribution of G+C along both chromosomes has no distinct maxima and minima, however, chromosome 21 contains considerably less G+C than chromosome 22. Both exons and Alurepeats are unevenly distributed along chromosome 21: they are scarce in its left part and abundant in the right part, while MIR elements are quite monotonously spread along this chromosome. The Alurepeats show a wave-like distribution pattern similar for both repeat orientations. The number of the Alurepeats of opposite orientations was equal for both studied chromosomes, and this may be considered a new property of the human genome. The positive correlation between the exon and Aludistribution patterns along the chromosome, the concurrent distribution of Alurepeats in both orientations along the chromosome, and the equal copy numbers for Aluin direct and inverted orientations within an individual chromosome point to their important role in the human genome, and do not fit the notion that Alurepeats belong to parasitic (junk) DNA.     

Structural analysis of the Alu-containing DNA fragment with disperse distribution in human chromosomes

Nucleotide sequencing of two terminal subfragments of a cloned human DNA fragment has been done. The fragment cloned hybridized dispersively along all chromosomes except for Y chromosome and C heterochromatic chromosome regions. Both subfragments sequenced contain Alu repeats, whose structures differ partially from those of accurately determined sequences of human Alu repeats. The results obtained are discussed in respect of possible usage of Alu repeats containing sequences for construction of special polymorphic molecular markers of human chromosomes.     

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.     

In silico analysis of the restriction fragments length distribution in the human genome.]

The Restriction On Computer (ROC) program (freely available at http://www.mcb.harvard.edu/gilbert/ROC) was developed and used to analyze the restriction fragment length distribution in the human genome. In contrast to other programs searching for restriction sites, ROC simultaneously analyzes several long nucleotide sequences, such as the entire genomes, and in essence simulates electrophoretic analysis of DNA restriction fragments. In addition, this program extracts and analyzes DNA repeats that account for peaks in the restriction fragment length distribution. The ROC analysis data are consistent with the experimental data obtained via in vitro restriction enzyme analysis (taxonomic printing). A difference between the in vitro and in silico results is explained by underrepresentation of tandem DNA repeats in genomic databases. The ROC analysis of individual genome fragments elucidated the nature of several DNA markers, which were earlier revealed by taxonomic printing, and showed that L1 and Alu repeats are nonrandomly distributed in various chromosomes. Another advantage is that the ROC procedure makes it possible to analyze the nonrandom character of a genomic distribution of short DNA sequences. The ROC analysis showed that a low poly(G) frequency is characteristic of the entire human genome, rather than of only coding sequences. The method was proposed for a more complex in silico analysis of the genome. For instance, it is possible to simulate DNA restriction together with blot hybridization and then to analyze the nature of markers revealed.     

The Distribution of L1 and Alu Retroelements in Relation to GC Content on Human Sex Chromosomes Is Consistent with the Ectopic Recombination Model

The distribution of Alu and L1 retroelements in the human genome changes with their age. Active retroelements target AT-rich regions, but their frequency increases in GC- and gene-rich regions of the genome with increasing age of the insertions. Currently there is no consensus on the mechanism generating this pattern. In this paper we test the hypothesis that selection against deleterious deletions caused by ectopic recombination between repeats is the main cause of the inhomogeneous distribution of L1s and Alus, by means of a detailed analysis of the GC distribution of the repeats on the sex chromosomes. We show that (1) unlike on the autosomes and X chromosome, L1s do not accumulate on the Y chromosome in GC-rich regions, whereas Alus accumulate there to a minor extent; (2) on the Y chromosome Alu and L1 densities are positively correlated, unlike the negative correlation on other chromosomes; and (3) in gene-poor regions of chromosome 4 and X, the distribution of Alus and L1s does not shift toward GC-rich regions. In addition, we show that although local GC content of long L1 insertions is lower than average, their selective loss from recombining chromosomes is not the main cause of the enrichment of ancient L1s in GC-rich regions. The results support the hypothesis that ectopic recombination causes the shift of Alu and L1 distributions toward the gene-rich regions of the genome. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. Reviewing Editor: Dr. Deborah Charlesworth     

Isolation of giant DNA fragments from flow-sorted human chromosomes

We have established a method using a conventional cell sorter equipped with a single argon laser to sort intact human chromosomes that can be used as a source for the production of giant DNA fragments. Various improvements were made to both the equipment and sorting method to enhance the sorting resolution and avoid destruction of chromosomal DNA. Using this improved method chromosomes 21 and 22 were sorted from the B-lymphoblastoid line GM00130B, digested with the rare cutting restriction endonuclease NotI, and analyzed by pulsed field gel electrophoresis followed by Southern hybridization using the Alu repetitive sequence as a probe. More than 25 discrete NotI giant DNA fragments ranging from 50 kb to longer than 2.5 Mb were separated and the size distribution pattern was unique for each chromosome, indicating successful sorting of intact chromosomes. The cumulative size of these Alu-positive NotI DNA fragments were 22.7 Mb and 25.5 Mb for chromosomes 21 and 22, respectively. These values are 47% and 49% of the estimated size of chromosomes 21 (48 Mb) and 22 (52 Mb).     

Distribution of Alu and L1 repeats in human YAC recombinants

Evidence is accumulating that the two major families of interspersed repeated human DNA sequences, Alu and L1, are not randomly distributed. However, only limited information is available on their relative long-range distribution. We have analyzed a set of randomly selected, human Chromosome (Chr) 11-specific YAC recombinants constituting a total length of about 2 Mbp for the local and global distribution of Alu and L1 repeats: the data show a strong asymmetry in the distribution of these two repeat classes and give weight, at the long-range molecular level, to previous studies indicating their partition in the human genome; they also suggest a strong tendency for L1 repeats to cluster, with a higher proportion of full-length elements than expected.     

No isochores in the human chromosomes 21 and 22?

The human genome is described in the literature as being composed of the isochores, i.e., long (hundreds of kilobases) segments with a homogeneous (G + C) content. We calculated the (G + C) content variations along the DNA molecules of the human chromosomes 21 and 22 and found the variations to be higher everywhere compared to the randomized sequences. Hence the (G + C) content is certainly not homogeneous on the isochore scale in the two human chromosomes. In addition, we found no significant difference between the two human molecules and the genome of E. coli regarding the (G + C) content variations. Hence no isochores are either present in the DNA molecules of the human chromosomes 21 and 22, or the isochores are also present in the genome of Escherichia coli. In any case, the present communication demonstrates that the isochores should be defined in unambiguous molecular terms if they are to be used for an up-to-date genome structure characterization.     

Non-random distribution of Alu-family repeats in human chromosomes

A phage lambda recombinant clone containing at least 8 Alu-family repeats (AFRs) has been isolated from a human genomic library, and DNA from the phage was used as a probe for in situ hybridization on G-banded human metaphase chromosomes of healthy donors and leukemic patients. Some chromosome bands show prominent clusters of silver grains in all individuals examined: 1p34, 1q23, 2q21–22, 10p14, 11p14, 10q21 and 11q14. The data suggest non-random distribution of AFRs in the human genome.     

点带石斑鱼染色体显带技术及其描绘研究

点带石斑鱼(Epinephelus malabaricus)属于鲈形目, 科、石斑鱼亚科、石斑鱼属, 是中国东南沿海暖水性礁栖的名贵海产经济鱼类. 采用PHA活体注射结合秋水仙素培养, 取点带石斑鱼全肾, 低渗处理, 空气干燥制片法制作染色体标本, 利用Alu I 限制性内切酶介导的原位切口平移显带技术, 在点带石斑鱼有丝分裂中期染色体上诱导出带纹清晰、分散良好的多重带. 结果显示, 多数染色体显现出8-10条带纹, 最少的一对染色体也有4条带纹, 同源染色体带纹基本一致, 在每对染色体上的数目及其分布具明显特征性且相对稳定, 同时发现不同分裂相的同一号染色体上, 特征带纹鲜明一致, 带纹数目基本吻合, 具有可重复性和可操作性; 然后用人X和Y染色体文库特异DNA为探针, 对点带石斑鱼的有丝分裂中期分裂相染色体进行了描绘研究. 结果表明, 点带石斑鱼染色体组中测出了人X染色体特异DNA同源片段的3个保守同线群, 分别在点带石斑鱼的第7、第13和第22号同源染色体上, 它们的杂交信号最近边距着丝粒的百分比距离分别大约为62.3%、43.4%及44.4%; 人X染色质同源片段的大小约占点带石斑鱼基因组的4.63％. 但用人Y染色体DNA描绘点带石斑鱼染色体时, 没有检测出可见的同源片段. 研究结果可以为从低等脊椎动物到人类性染色体的进化过程提供一种新的研究思路.       

Human genome organization: Alu, lines, and the molecular structure of metaphase chromosome bands

Combining high resolution in situ hybridization with quantitative solid state imaging, we show that human metaphase chromosome Giemsa/Quinacrine and Reverse bands are each characterized by distinct families of interspersed repeated sequences: the SINES, Alu family dominates in Reverse bands, and the LINES, L1 family dominates in Giemsa/Quinacrine positive bands. Alu is 56% guanine plus cytosine, and L1 is 58% adenine plus thymine, and each may comprise 13%-18% of the total DNA in a chromosome band. Therefore, the distribution of these sequences alone may account for a large part of human chromosome banding seen with fluorescent dyes. With the exception of some telomeric regions, and the chromosomal regions of simple sequence DNA, Alu and L1 are precisely inversely distributed, suggesting an inverse functional relationship. This finding links genome organization with chromosome structure and function.     

Distribution of Alu repeats along the human genome: formation of clusters and features of insertion regions

The contextual analysis of nucleotide sequences of 22 Alu repeats arrangement regions in the human genome has been carried out and some of their peculiarities have been revealed. In particular, the occurrence of marked and statistical non-random homology between the repeats and the regions of their integration has been shown. A mechanism of choosing the Alu repeats insertion regions in the genome has been suggested taking into account these peculiarities. Using a sample of the 80 human Alu repeats sequences peculiarities of these repeats location within the genome has been investigated. A tendency to the formation of Alu repeats clusters in various regions of the genome was revealed. A range of possible mechanisms on such Alu clusters emergence is considered. On the basis of the data obtained an "attraction" mechanism, according to which integration of Alu repeats into the definite region of the genome increases the insertion probability of other Alu repeats into the same region, are proposed.     

An isochore map of the human genome based on the Z curve method

The distribution of the G+C content in the human genome has been studied by using a windowless technique derived from the Z curve method. The most important findings presented in this paper are twofold. First, abrupt variations of the G+C content along human chromosome sequences are the main variation patterns of G+C content. It is found that at some sites, the G+C content undergoes abrupt changes from a G+C-rich region to a G+C-poor region alternatively and vice versa. Second, it is shown that long domains with relatively homogeneous G+C content along each chromosome do exist. These domains are thought to be isochores, which usually have sharp boundaries. Consequently, 56 isochores longer than 3 Mb have been identified in chromosomes 1-22, X and Y. Boundaries, size and G+C content of each isochore identified are listed in detail. As an example to demonstrate the power of the method, the boundary between the Classes III and II isochores of the MHC sequence has been determined and found to be at 2,477,936, which is in good agreement with the experimental evidence. A homogeneity index is introduced to measure the homogeneity of G+C content in isochores. We emphasize that the homogeneity of G+C content is relative. The isochores in which the G+C content keeps absolutely constant do not exist. Isochore structures appear to be a basic organization of the human genome. Due to the relevance to many important biological functions, the clarification of isochore structures will provide much insight into the understanding of the human genome.     

The distribution of interspersed repetitive DNA sequences in the human genome

The distribution of interspersed repetitive DNA sequences in the human genome has been investigated, using a combination of biochemical, cytological, computational, and recombinant DNA approaches. "Low-resolution" biochemical experiments indicate that the general distribution of repetitive sequences in human DNA can be adequately described by models that assume a random spacing, with an average distance of 3 kb. A detailed "high-resolution" map of the repetitive sequence organization along 400 kb of cloned human DNA, including 150 kb of DNA fragments isolated for this study, is consistent with this general distribution pattern. However, a higher frequency of spacing distances greater than 9.5 kb was observed in this genomic DNA sample. While the overall repetitive sequence distribution is best described by models that assume a random distribution, an analysis of the distribution of Alu repetitive sequences appearing in the GenBank sequence database indicates that there are local domains with varying Alu placement densities. In situ hybridization to human metaphase chromosomes indicates that local density domains for Alu placement can be observed cytologically. Centric heterochromatin regions, in particular, are at least 50-fold underrepresented in Alu sequences. The observed distribution for repetitive sequences in human DNA is the expected result for sequences that transpose throughout the genome, with local regions of "preference" or "exclusion" for integration.     

应用涂染技术研究人和猕猴染色体的同源性

用２４种人类染色体探针对人和猕猴Ｇ－显带染色体进行涂染。结果显示：人类所有染色体在猕猴的染色体组里都有其同源染色体或染色体片段。     

DNA synthesis and endomitoses in the giant nuclei of the silkgland of Bombyx mori.

At the first symptoms of organisation of the silkgland in the embryo, mitoses stop and nuclei start to grow. Through autoradiographic studies, performed after sequenced labeling with [3H] and [14C] thymidine, the durations of the different phases of DNA synthesis cycles (T = 42 to 48 h, S = 22 to 25 h, G = 20 to 23 h) are established. These durations are in fact identical during the second and the third instar, and the same, whatever region is concerned : posterior, middle or anterior parts. A model has been established to account for the distribution of the S phases during the second and third instars. The DNA synthesis in all nuclei of a given region has been followed during the first four instars by labelling with [3H]thymidine. The activity goes through maxima and minima, depending on the percent of nuclei synthesizing DNA and their synchronism, both being characteristic of each region; long resting periods are observed during the molting stages of the first three instars in the middle and the anterior parts. The coincidence is obvious between the maxima and minima and respectively the S and G phases of the model. DNA assays agree with the distribution of cycles established by autoradiography if one admits that each cycle does lead to a doubling of the amount of DNA. The overall DNA synthesis from the diploid value is estimated to correspond to 18-19 endomitoic cycles in the nucleic of the posterior part, 19-20 cycles of those of the middle part and 13 in those of the anterior part. The analysis of chromosome structures, by squashing the nuclear content, shows that existence of a complete endomitotic cycle: the doubling of chromosomes is associated with condensed structures, alternating with a decondensed state of chromatin, responsible for the DNA synthesis. The female heterochromatin undergoes a restricted morphological cycle delayed with respect to bulk chromatin. It is characterized by a late DNA duplication and by non dispersed daughter chromosomes. Some of these aspects are, to a lesser extent, reproduced in groups of autosomic chromosomes.     

Similarities in the chromosomal distribution of AG and AC repeats within and between Drosophila, human and barley chromosomes

Two simple sequence repeats (SSRs), AG and AC, were mapped directly in the metaphase chromosomes of man and barley (Hordeum vulgare L.), and in the metaphase and polytene chromosomes of Drosophila melanogaster. To this end, synthetic oligonucleotides corresponding to (AG)(12) and (AC)(8) were labelled by the random primer technique and used as probes in fluorescent in situ hybridisation (FISH) under high stringency and strict washing conditions. The distribution and intensity of the signals for the repeat sequences were found to be characteristic of the chromosomes and genomes of the three species analysed. The AC repeat sites were uniformly dispersed along the euchromatic segments of all three genomes; in fact, they were largely excluded from the heterochromatin. The Drosophila genome showed a high density of AC sequences on the X chromosome in both mitotic and polytene nuclei. In contrast, the AG repeats were associated with the euchromatic regions of the polytene chromosomes (and in high density on the X chromosome), but were only seen in specific heterochromatic regions in the mitotic chromosomes of all three species. In Drosophila, the AG repeats were exclusively distributed on the tips of the Y chromosome and near the centromere on both arms of chromosome 2. In barley and man, AG repeats were associated with the centromeres (of all chromosomes) and nucleolar organizer regions, respectively. The conserved chromosome distribution of AC within and between these three phylogenetically distant species, and the association of AG in specific chromosome regions with structural or functional properties, suggests that long clusters of these repeats may have some, as yet unknown, role.     

High-resolution characterization of CPD hotspot formation in human fibroblasts

Repair of DNA lesions must occur within the chromatin landscape and is associated with alterations in histone modifications and nucleosome rearrangement. To directly associate these chromatin features with DNA damage and repair, it is necessary to be able to map DNA adducts. We have developed a cyclobutane pyrimidine dimer (CPD)-specific immunoprecipitation method and mapped ultraviolet damage hotspots across human chromosomes 1 and 6. CPD hotspots occur almost equally in genic and intergenic regions. However, these hotspots are significantly more prevalent adjacent to repeat elements, especially Alu repeats. Nucleosome mapping studies indicate that nucleosomes are consistently positioned at Alu elements where CPD hotspots form, but by 2 h post-irradiation, these same regions are significantly depleted of nucleosomes. These results indicate that nucleosomes associated with hotspots of CPD formation are readily rearranged, potentially making them accessible to DNA repair machinery. Our results represent the first chromosome scale map of ultraviolet-induced DNA lesions in the human genome, and reveal the sequence features and dynamic chromatin changes associated with CPD hotspots.