Isolation of polymorphic AGC repeats located 3' to bovine SINEs

A bovine genomic library was screened for the presence of (AGC)n repeats. All isolated AGC repeats were located adjacent to the 3′ end of bovine short interspersed nuclear elements (SINE). Polymerase chain reactions (PCR) using either two unique primers or one unique and one SINE primer produced high-resolution products without the secondary artifact ladders typical of dinucleotide microsatellites. Four AGC microsatellites were found to be polymorphic with 2–4 alleles each and polymorphism information context (PIC) values ranging between 0.26 and 0.49. One microsatellite, AR025, was mapped to chromosome 26 with the CSIRO reference families. Because of their strong association with AGC repeats and high frequency in the genome, SINE-3′ PCR may prove to be a novel source of polymorphic trinucleotide markers in the bovine genome.     

Simple sequence repeats in different genome sequences of Shigella and comparison with high GC and AT-rich genomes.

Simple sequence repeats (SSRs) are omnipresent in prokaryotes and eukaryotes, and are found anywhere in the genome in both protein encoding and noncoding regions. In present study the whole genome sequences of seven chromosomes (Shigella flexneri 2a str301 and 2457T, Shigella sonnei, Escherichia coli k12, Mycobacterium tuberculosis, Mycobacterium leprae and Staphylococcus saprophyticus) have downloaded from the GenBank database for identifying abundance, distribution and composition of SSRs and also to determine difference between the tandem repeats in real genome and randomness genome (using sequence shuffling tool) of the organisms included in this study. The data obtained in the present study show that: (i) tandem repeats are widely distributed throughout the genomes; (ii) SSRs are differentially distributed among coding and noncoding regions in investigated Shigella genomes; (iii) total frequency of SSRs in noncoding regions are higher than coding regions; (iv) in all investigated chromosomes ratio of Trinucleotide SSRs in real genomes are much higher than randomness genomes and Di nucleotide SSRs are lower; (v) Ratio of total and mononucleotide SSRs in real genome is higher than randomness genomes in E. coli K12, S. flexneri str 301 and S. saprophyticus, while it is lower in S. flexneri str 2457T, S.sonnei and M. tuberculosis and it is approximately same in M. leprae; (vi) frequency of codon repetitions are vary considerably depending on the type of encoded amino acids.     

Prototypic sequences for human repetitive DNA

Summary We report a collection of 53 prototypic sequences representing known families of repetitive elements from the human genome. The prototypic sequences are either consensus sequences or selected examples of repetitive sequences. The collection includes: prototypes for high and medium reiteration frequency interspersed repeats, long terminal repeats of endogenous retroviruses, alphoid repeats, telomere-associated repeats, and some miscellaneous repeats. The collection is annotated and available electronically.[/ap ]Offprint requests to: J. Jurka     

Repetitive DNA, molecular cytogenetics and genome organization in the King scallop (Pecten maximus)

We studied the structure, organization and relationship of repetitive DNA sequences in the genome of the scallop, Pecten maximus, a bivalve that is important both commercially and in marine ecology. Recombinant DNA libraries were constructed after partial digestion of genomic DNA from scallop with PstI and ApaI restriction enzymes. Clones containing repetitive DNA were selected by hybridisation to labelled DNA from scallop, oyster and mussel; colonies showing strong hybridisation only to scallop were selected for analysis and sequencing. Six non-homologous tandemly repeated sequences were identified in the sequences, and Southern hybridisation with all repeat families to genomic DNA digests showed characteristic ladders of hybridised bands. Three families had monomer lengths around 40 bp while three had repeats characteristic of the length wrapping around one (170 bp), or two (326 bp) nucleosomes. In situ hybridisation to interphase nuclei showed each family had characteristic numbers of clusters indicating contrasting arrangements. Two of the repeats had unusual repetitions of bases within their sequence, which may relate to the nature of microsatellites reported in bivalves. The study of these rapidly evolving sequences is valuable to understand an important source of genomic diversity, has the potential to provide useful markers for population studies and gives a route to identify mechanisms of DNA sequence evolution.     

Genome wide survey of microsatellites in ssDNA viruses infecting vertebrates

Microsatellites or Simple Sequence Repeats (SSRs) are tandem iterations of one to six base pairs, non-randomly distributed throughout prokaryotic and eukaryotic genomes. Limited knowledge is available about distribution of microsatellites in single stranded DNA (ssDNA) viruses, particularly vertebrate infecting viruses. We studied microsatellite distribution in 118 ssDNA virus genomes belonging to three families of vertebrate infecting viruses namely Circoviridae, Parvoviridae, and Anelloviridae, and found that microsatellites constitute an important component of these virus genomes. Mononucleotide repeats were predominant followed by dinucleotide and trinucleotide repeats. A strong positive relationship existed between number of mononucleotide repeats and genome size among all the three virus families. A similar relationship existed for the occurrence of DTTPH (di-, tri-, tetra-, penta- and hexa-nucleotide) repeats in the families Anelloviridae and Parvoviridae only. Relative abundance and relative density of mononucleotide repeats showed a strong positive relationship with genome size in Circoviridae and Parvoviridae. However, in the case of DTTPH repeats, these features showed a strong relationship with genome size in Circoviridae only. On the other hand, relative microsatellite abundance and relative density of mononucleotide repeats were negatively correlated with GC content (%) in Parvoviridae genomes. On the basis of available annotations, our analysis revealed maximum occurrence of mononucleotide as well as DTTPH repeats in the coding regions of these virus genomes. Interestingly, after normalizing the length of the coding and non-coding regions of each virus genome, we found relative density of microsatellites much higher in the non-coding regions. We understand that the present study will help in the better characterization of the stability, genome organization and evolution of these virus classes and may provide useful leads to decipher the etiopathogenesis of these viruses.     

Purification and characterization of two transcribed repetitive DNA fractions from the pigeon genome

Two fractions of the repeats belonging to intermediate frequency repetitive DNA were isolated from the total pigeon nuclear DNA fragmented to about 450 nucleotides. One fraction was designated as rare repeats (repetition frequency about 35 per haploid genome) and another termed as moderate repeats (repetition frequency about 2500 per haploid genome). The rare repeats, which constitute about 7% of the total DNA, include at least 75% of the repetitive DNA sequences transcribed into the high molecular fraction (>45S) of HnRNA in erythroid cells. These repeats have properties compatible with the characteristics of the class of low frequency interspersed DNA found in genomes of many other Metazoan species. The moderate repeats contribute only about 10–20% of the total repetitive DNA copies present in >45S HnRNA and differ from the rare repeats in some other properties. — The possible role of the rare repeats in the genome is discussed.     

Two new families of tandem repeats isolated from genus Vicia using genomic self-priming PCR

A modified genomic self-priming technique was used for rapid isolation of tandem repeats from several Vicia species. Based on homologies of their nucleotide sequences the newly isolated clones were assigned to two repeat families named VicTR-A and VicTR-B. Both families are rich in AT (74%) and are organized as long blocks of tandemly repeated units. The VicTR-A repeats are characterized by a monomer size of 69 bp, whereas the VicTR-B repeat monomer is about 38 bp long, and the two families do not share significant sequence homology. VicTR sequences show different degrees of amplification (up to 10⁶–10⁷ copies/haploid genome) in individual Vicia species and are not amplified in other legumes. The abundances of these repeats do not correlate with genome sizes but are similar in species that belong to the same taxonomic section within the genus Vicia. Primed in situ (PRINS) labeling of metaphase chromosomes of V. pannonica revealed that VicTR-A sequences are located predominantly in the telomeric regions of the short arms of all chromosomes. In contrast, labeling of VicTR-B repeats in V. sativa resulted in mainly intercalary bands of various intensities and only weak telomeric signals. Received: 15 December 1999 / Accepted: 8 March 2000     

Long perfect dinucleotide repeats are typical of vertebrates, show motif preferences and size convergence

Microsatellites are simple sequence repeats (SSRs) showing complex patterns of length, motif sizes, motif sequences, and repeat perfection. We studied the structure of the dinucleotide SSR population at the genome level by analyzing assembled DNA sequence across species. Three dinucleotide populations were distinguished when SSR genome frequency was analyzed as a function of repeat length and repeat perfection. A population of low-perfection SSRs was identified, which is constituted by short repeats and represents the vast majority of genomic dinucleotide SSRs across eukaryotic genomes. In turn, the highly perfect repeats are 30 to 50 times less frequent and, in addition to short repeats, also contain a long repeat population that is uniquely represented in vertebrate species. Distinctive features of this population include the modal peak in the frequency distribution of repeat length and the strong preferential usage of the repeat motifs AC and AG. These results raise the hypothesis that the ability of carrying a distinct population of long, highly perfect dinucleotide repeats in the genome is a late acquisition in chordate evolution. Our analysis also suggests that different dinucleotide repeat populations have different dynamics and are likely to be underlined by different molecular mechanisms of generation and maintenance in the genome. Thus, these observations imply that caution should be taken in extrapolating results from studies on SSR mutability and on SSR phylogenetic comparisons that do not take into account the stratification of dinucelotide populations in the eukaryotic genome.     

Repetitive sequences in complete and defective genomes of Herpesvirus saimiri.

Two types of Herpesvirus saimiri genomes can be isolated from purified virions: (i) the M genome is a double-stranded, liniear DNA molecule with a mean contour length corresponding to 89 times 10-6 daltons. The M genome contains about 70% of unique sequences (light DNA, 36% guanine plus cytosine) and 30% reiterated sequences (heavy DNA, 71% guanine plus cytosine). (ii) the H genome is composed of heavy DNA only and is more heterogeneous in size. The sequences in the H genome are up to 40-fold reiterated, indicating defectiveness of this type of genome. The repetitions in the H genome and the M genome cross-hybridize almost completely and have identical kinetic complexity (2.8 times 10-6 daltons). DNA infectivity studies by using the calcium phosphate and the DEAE-dextran method gave further evidence that H genomes are defective: no infectious virus was recovered from permissive cells treated with heavy DNA, whereas M genome-infected cells developed cytopathic changes after 11 to 56 days. Defective H genomes were present in the progeny virus two passages after transfection.     

Diversity of Olea genotypes and the origin of cultivated olives

Tandem repeats belonging to three DNA sequence families (OeTaq80, OeTaq178, and OeGEM86) were isolated from the nuclear DNA of Olea europaea cv. Carolea and dot-hybridized to the genomic DNA of 14 hypothetically different Olea species, 78 olive cultivars, and 14 wild olives. The copy number per unreplicated haploid genome of OeTaq80- and OeTaq178-related sequences was in the 10⁷-10⁶ range and that of OeGEM86-related sequences was in the 10⁵ range in cultivars, wild olives and some Olea species. A large variation in the frequency of repeats belonging to each sequence family was observed within each group of plants. Positive correlations existed in each genome between the frequencies of repeats belonging to each family, and their overall frequency was positively correlated to the genome size. Duncan grouping showed that the frequency variation of tandem repeats within each group of plants was not continuous. Two main groups and several subgroups of genotypes could be separated within both the olive cultivars and the wild olives. Discrete areas in the Mediterranean Basin could be delimited by the geographic distribution of cultivated olives with different genotypes and the wild plants were associated with the cultivars in these areas according to genotypic similarity. The Olea species could be divided into four genotypic groups. Three of these, comprising accessions from Asia and North Africa, showed similarity with the genotypes of cultivars and wild olives. These results suggest a polyphyletic origin of cultivated olives from different wild Olea forms distributed throughout the Mediterranean Basin.     

The MB1 family of repeats in clones from the genomes of mammals]

Members of MB1 family repeats are revealed in genomes of many mammals (cow, rabbit, opossum, horse, ...). The MB1 repeats from cow and rabbit genomes are mirror-reflected about the SINE families repeats from cow and rabbit genomes. The life time of MB1 repeats are no less than 100 million years. Classification of MB1 repeats from human genome using the information similarity was performed. This classification has revealed two subfamily MB1 repeats in human genome. Possible processes of creation of MB1 family repeats common for many mammals are discussed.     

家蚕LTR逆转录转座子的鉴定、分类及系统发育分析

转座子是真核生物基因组的重要组成成分。为了研究家蚕Bombyx mori长末端重复序列 (long terminal repeat, LTR)逆转录转座子的分类及进化, 本研究采用de novo预测和同源性搜索相结合的方法, 在家蚕基因组中共鉴定出了38个LTR逆转录转座子家族, 序列长度占整个基因组的0.64%, 远小于先前预测的11.8%, 其中有6个家族为本研究的新发现。38个家族中, 26个家族有表达序列标签 (expression sequence tag, EST)证据, 表明这些家族具有潜在的活性。对有EST证据的6个家族和没有EST证据的5个家族用RT-PCR进行了组织表达谱实验, 结果表明这11个家族在一些组织中有表达, 这进一步证实了这些家族具有转录活性, 基于此我们推测家蚕中大部分的LTR逆转录转座子家族很可能具有潜在活性。对转座子的插入时间进行估计, 结果表明绝大部分元件都是最近1百万年内插入到家蚕基因组中的。我们还比较了黑腹果蝇Drosophila melanogaster、 冈比亚按蚊Anopheles gambiae和家蚕B. mori中Ty3/Gypsy超家族分支的差异, 结果表明不同枝在不同昆虫中有着不同的扩张。家蚕中LTR逆转录转座子的鉴定和系统分析有助于我们理解逆转录转座子在昆虫进化中的作用。     

Comparative analysis of nucleotide sequences of chromosomal DNA isolated from nuclear envelopes and cores of rosette-like structures of murine interphase chromosomes]

Six DNA fragments of interphase chromosomes isolated from nuclear envelopes of murine hepatocytes were cloned and sequenced. Analysis of their structural-functional organization suggests that these fragments are highly specified protein-nonencoding fractions of a eukaryotic genome. In the evolutionary process, they appear already in archaebacteria and may be "ancestral" for DNA sequences involved in structuring chromosomal domains (rosette-like structures) of tissue-specific genes. In their composition, these fragments have nucleotide sequences homologous to the repeats of the SINE and LINE families and to the satellite DNA of murine centromeres.     

Structural families of genomic microsatellites

We present an analysis of tandem repeats of short sequence motifs (microsatellites) in twelve eukaryotes for which a large part of the genome has been sequenced and assembled. The pattern of motif abundance varies significantly in different species, but it is very similar in different chromosomes of the same species. The most abundant repeats can be classified in two main families. The first family has a rigid conformation, with purines in one strand and pyrimidines in the complementary strand, mainly A(n)/T(n) and (AG)(n)/(CT)(n). The second family has alternating, flexible sequences, such as (AT)(n), (AC)(n) and related sequences. In the pluricellular organisms the relative frequency of both families is rather constant. These observations indicate that microsatellites have structural information and may be involved in the organization of chromatin fibers and in chromosome architecture in general. An additional intriguing finding is the absence of microsatellites with sequences which appear to be forbidden, such as (AATT)(n).     

DNA sequence organization in soybean investigated by electron microscopy

An electron microscopic analysis of the DNA sequence organization in the soybean genome is reported. This analysis employed the gene 32 proteinethidium bromide spreading technique, a procedure which produces striking contrast between double and single-stranded DNA regions. To investigate the arrangement of repetitive sequences differing in genomic frequency, three kinetic fractions of 5 kb DNA fragments were isolated by reassociation and hydroxyapatite chromatography. Renatured structures in each fraction were then visualized in the electron microscope. The majority of repeated sequences, irrespective of frequency, were shown to be relatively non-divergent, to exceed 1.5 kbp in length (number-average), and to be organized primarily into long regularly repeating tandem or clustered arrays. Duplex regions >5 kbp were commonly visualized. A small fraction of low frequency repeats (<100 copies per genome), however, was observed to have a distinctly different form of arrangement. These repeats averaged 0.2 kbp in length, contained divergent sequences, and were contiguous to single copy DNA sequences having an average length of 1.15 kbp. Repeats which flanked a given single copy sequence did not appear to be homologous. Neither short clustered permuted repeats nor interspersion of repeats which differed significantly in reiteration frequency were found to be major features of soybean genome organization.     

Characterization of the terminal inverted repeats and their neighboring tandem repeats in the Chlorella CVK1 virus genome

A unique group of large icosahedral viruses that infect a unicellular green alga (Chlorella sp. NC64A) were isolated from freshwater sources in Japan. These viruses contain a linear double-stranded DNA (dsDNA) genome with hairpin ends. A physical map was constructed for the genomic DNA of CVK1 (Chlorella virus isolated in Kyoto, no. 1) by pulsed-field gel electrophoresis of restriction fragments. The nucleotide sequences around both termini of the CVK1 DNA revealed the presence of inverted terminal repeats (ITR) of approximately 1.0 kb. Adjacent to the ITR, unique sequence elements of 10 to 20 by were directly repeated 20 to 30 times in tandem array. Several copies of these repeat elements were deleted in virus mutants that were occasionally generated from Chlorella cells that were in a putative CVK1 carrier state. These repeats might represent a hot spot of rearrangement in the CVK1 genome.