Color-coding reveals tandem repeats in the Escherichia coli genome

Genomic DNA contains a wide variety of repetitive sequences. In Escherichia coli, there have been several classes of repetitive sequences reported, some of which cluster as tandem repeats. We propose a novel method for analyzing symbolic sequences by two-dimensional pattern formation with color-coding. We applied this method for searching tandem repeats in the E. coli genome and found approximately 50 repeats with periods longer than 30 bases. The longest repeat has a period of 1267 bases.     

Genetic mapping of 40 cDNA clones on the mouse genome by PCR

We recently proposed a new PCR-based genetic marker assay for the mouse genome that exploits sequence differences in the 3-untranslated region (UTR) of cDNAs between different mouse strains, called biallelic polymorphic expressed sequence tags (bESTs). The specific use of 3-UTR has several advantages: (1) frequent sequence polymorphism between different mouse strains, (2) most commonly uninterrupted by introns, (3) usually unique sequence even among closely related gene family members. In this paper, we identify additional genetic loci defined by bEST and determine their location on the mouse genetic map by using interspecific backross mapping panels between C57BL/6J and Mus spretus. Of 136 markers tested, 86 produced unique PCR products from C57BL/6J and M. spretus genomic DNAs. We then sequenced these 86 PCR products from C57BL/6J and M. spretus and found that 59 markers have sequence polymorphisms. Of these, we mapped 36 by restriction fragment length polymorphism (RFLP) of the PCR products and 4 by length polymorphism (LP) of the PCR products. We discuss the possibility of a large-scale application of this method for cDNA mapping.     

Detection of tandem repeats in the genome of Citellus genus using restrictases

DNA from ground squirrels of the Citellus genus (Rodentia, Sciuridae) were analysed by centrifugation in the presence of CsCl followed by digestion by restriction endonucleases. Digestion of DNA of two species C. undulatus and C. fulvus by 10 of the 16 restriction endonucleases used led to formation of electrophoretically discrete fragments that are multiple to 330 b.p. in length which points out the tandem organization of repetitive sequences similar to the satellite DNA of many mammal species. However, upon centrifugation we failed to reveal a satellite band in these species; hence the tandem repeats refer to the class of cryptic satellites in the ground squirrels and do not differ in base composition from the remaining part of DNA. The main fraction of the genome was revealed in the form of discrete fragments by cleavage with HindIII and AluI. Both of these restriction endonucleases were used for comparative analysis of DNA of 12 Citellus species. It has been shown that DNA of all species can be digested by HindIII and yields a series of fragments that are multiple to 330-30 b.p. in length and the total content of which varies from species to species within 4-22%. The fraction of the tandem repeats does not correlate with the systematic position of species nor with the amount of heterochromatin in the chromosomes. AluI cuts the DNA of 11 species yielding 110 and 220 b.p. fragments compared to only 60 and 280 b.p. in the DNA of C. dauricus. Under HindIII digestion we can also reveal the tandem repeats in marmot, which is phylogenetically close to the Citellus of the Marmota genus, but they have another periodicity--180 b.p. We propose that the age of ground squirrels repeats is 2-3 million years and they are significantly younger than the marmot repeats.     

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.     

Genome-wide analysis of transposable elements and tandem repeats in the compact placozoan genome

   

The placozoan Trichoplax adhaerens has a compact genome with many primitive eumetazoan characteristics. In order to gain a better understanding of its genome architecture, we conducted a detailed analysis of repeat content in this genome. The transposable element (TE) content is lower than that of other metazoans, and the few TEs present in the genome appear to be inactive. A new phylogenetic clade of the gypsy-like LTR retrotransposons was identified, which includes the majority of gypsy-like elements in Trichoplax. A particular microsatellite motif (ACAGT) exhibits unexpectedly high abundance, and also has strong association with its nearby genes.     

Genetic variation in mouse apolipoprotein A-IV due to insertion and deletion in a region of tandem repeats.

We have detected three unique apolipoprotein A-IV (apoA-IV) charge isoforms in strains of commensal mice. The cDNA sequences for one representative of each isoform (Mus domestesticus strains C57BL/6J and 129/J and Mus castaneus) revealed a polymorphism within a series of four imperfect repeats encoding the sequence Glu-Gln-Ala/Val-Gln. Insertions or deletions of 12 nucleotides within this repetitive region have given rise to three genotypes characterized by three (129), four (C57BL/6), or five (M. castaneus) copies of the repeat unit. To ascertain the extent of this variation among other species of the Mus genus, we sequenced this region of apoA-IV cDNAs from eight additional M. domesticus inbred strains and from five wild-derived Mus species. All eight additional M. domesticus strains examined had four repeat units, as found in C57BL/6. Among wild-derived mice, however, one species (Mus spretus) had three repeats, two species (Mus cookii and Mus cervicolor) had four repeats, and two species (Mus hortulanus and Mus minutoides) had five repeats. A lack of correlation between the number of repeat units and the phylogeny of Mus species indicates that independent mutations may have occurred throughout the evolution of specific mouse lineages. We suggest that the repetitive nature of the polymorphic sequence may predispose this region to slippage errors during DNA replication, resulting in frequent deletion/insertion mutations.     

Detection of polymorphic loci in complex genomes with synthetic tandem repeats.

Sixty synthetic probes mimicking minisatellite structures have been used on Southern blots bearing a set of DNA samples from a panel of complex genomes. They enable the detection of polymorphic loci in all the species tested and sometimes provide directly usable genetic markers. The general approach reported here should facilitate the study of genetic variability and the efficient development of genetic markers necessary for the mapping of complex genomes.     

Replication slippage versus point mutation rates in short tandem repeats of the human genome

Short tandem repeats (STRs) are subjected to two kinds of mutational modifications: point mutations and replication slippages. The latter is found to be the more frequent cause of STR modifications, but a satisfactory quantitative measure of the ratio of the two processes has yet to be determined. The comparison of entire genome sequences of closely enough related species enables one to obtain sufficient statistics by counting the differences in the STR regions. We analyzed human–chimpanzee DNA sequence alignments to obtain the counts of point mutations and replication slippage modifications. The results were compared with the results of a computer simulation, and the parameters quantifying the replication slippage probability as well as the probabilities of point mutations within the repeats were determined. It was found that within the STRs with repeated units consisting of one, two or three nucleotides, point mutations occur approximately twice as frequently as one would expect on the basis of the 1.2% difference between the human and chimpanzee genomes. As expected, the replication slippage probability is negligible below a 10-bp threshold and grows above this level. The replication slippage events outnumber the point mutations by one or two orders of magnitude, but are still lower by one order of magnitude relative to the mutability of the markers that are used for genotyping purposes.     

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.     

Detecting short tandem repeats from genome data: opening the software black box

Short tandem repeats, specifically microsatellites, are widely used genetic markers, associated with human genetic diseases, and play an important role in various regulatory mechanisms and evolution. Despite their importance, much is yet unknown about their mutational dynamics. The increasing availability of genome data has led to several in silico studies of microsatellite evolution which have produced a vast range of algorithms and software for tandem repeat detection. Documentation of these tools is often sparse, or provided in a format that is impenetrable to most biologists without informatics background. This article introduces the major concepts behind repeat detecting software essential for informed tool selection. We reflect on issues such as parameter settings and program bias, as well as redundancy filtering and efficiency using examples from the currently available range of programs, to provide an integrated comparison and practical guide to microsatellite detecting programs.     

Functional genome annotation through phylogenomic mapping

Accurate determination of functional interactions among proteins at the genome level remains a challenge for genomic research. Here we introduce a genome-scale approach to functional protein annotation--phylogenomic mapping--that requires only sequence data, can be applied equally well to both finished and unfinished genomes, and can be extended beyond single genomes to annotate multiple genomes simultaneously. We have developed and applied it to more than 200 sequenced bacterial genomes. Proteins with similar evolutionary histories were grouped together, placed on a three dimensional map and visualized as a topographical landscape. The resulting phylogenomic maps display thousands of proteins clustered in mountains on the basis of coinheritance, a strong indicator of shared function. In addition to systematic computational validation, we have experimentally confirmed the ability of phylogenomic maps to predict both mutant phenotype and gene function in the delta proteobacterium Myxococcus xanthus.     

Genetic analysis and genome mapping in Raphanus.

The first genetic map of the Raphanus genome was developed based on meiosis in a hybrid between Raphanus sativus (cultivated radish) and Raphanus raphanistrum (wild radish). This hybrid was used to produce a BC1 population of 54 individuals and an F2 population of 85 individuals. A total of 236 marker loci were assayed in these populations using a set of 144 informative Brassica RFLP probes previously used for genetic mapping in other crucifer species. The genetic maps derived from the BC1 and F2 populations were perfectly collinear and were integrated to produce a robust Raphanus map. Cytological observations demonstrated strict bivalent pairing in the R. sativus x R. raphanistrum hybrids. Productive pairing along the length of each chromosome was confirmed by the identification of nine extensive linkage groups and the lack of clustering of marker loci. Indeed, the distributions of both marker loci and crossovers was more random than those reported for other crop species. The genetic markers and the reference map of Raphanus will be of considerable value for future trait mapping and marker-assisted breeding in this crop, as well as in the intergenomic transfer of Raphanus genes into Brassica crops. The future benefits of comparative mapping with Arabidopsis and Brassica species are also discussed.     

The use of synthetic tandem repeats to isolate new VNTR loci: cloning of a human hypermutable sequence.

Synthetic tandem repeats (STRs) of oligonucleotides have previously been shown to detect polymorphic loci in the human genome. Here, we report results from the use of three such probes to screen a human cosmid library. Nine of the 45 positive clones that were analyzed appear to contain highly polymorphic minisatellite or VNTR loci. The degree of enrichment for minisatellite sequences varied with the choice of STR: one provided a 15- to 20-fold enrichment (4 polymorphic loci among 10 clones), whereas 2 others gave a 3- to 5-fold enrichment (5 polymorphic probes in a total of 35 clones) compared to random screening. The 9 VNTR markers have been localized by linkage analysis in the CEPH panel and/or by in situ hybridization. Eight probes identify new loci, one of which maps to an interstitial region. One of the VNTR loci (identified by probe CEB1) was found to be hypermutable, with 52 mutation events identified among 310 children characterized in 40 CEPH families. The parental origin of the mutation could be identified in all instances, and only one mutation was found to be of maternal origin. The mutation rate in males was estimated to be approximately 15%. Segregation analysis of flanking markers suggests that mutations are not associated with crossing over. As the only previously described hypermutable minisatellite loci in humans have equal rates of male and female mutations, these observations establish that a second type of hypermutable minisatellite exists in the human genome. In neither case does the generation of new alleles appear to be associated with unequal crossing over.     

Genetic analysis of a Sicilian population using 15 short tandem repeats

The genetic structure of the population of Alia (Sicily, Italy) was analyzed using 15 short tandem repeats: TPOX, D2S1338, D3S1358, FIBRA, D5S818, CSF1PO, D7S820, D8S1179, TH01, VWA, D13S317, D16S539, D18S51, D19S433, and D21S11. Two of these markers, D2S1338 and D19S433, have never before been used in research on population genetics and only recently have they been put to use in forensic medicine. Results of the analysis underline the genetic isolation of the Alia population and show it to be a recent bottleneck as a consequence of a cholera epidemic in 1837. While comparing the Alia population with other populations from Sicily, a genetic heterogeneity within Sicily was uncovered, thus confirming previous results obtained from the analysis of classical markers. This heterogeneity underlines the existence of genetic boundaries within the island. Comparisons with other Italian, Mediterranean, and European populations highlight the differentiation of the Sicilian population, reflecting the presence of a genetic boundary that separates Sicily from northern and central Italy and from the western Mediterranean basin.     

Additional microsatellite markers for mouse genome mapping

Mouse sequence information from the EMBL and GenBank databases, published sequences and genomic clones have been analyzed for simple repetitive elements or microsatellites. Each microsatellite has been amplified by the polymerase chain reaction (PCR) as a single locus marker. PCR primers were designed from unique sequence flanking each repeat. Size variation of PCR products less than 750 base pairs (bp) between mouse strains has been determined using ethidium bromide-stained acrylamide or agarose gels. A further 74 newly characterized microsatellites are presented in this paper, bringing to 185 the total we have analyzed. Of these, 157/185 (85%) have more than one allele, 143/178 (80%) vary in length between C57BL/6J and Mus spretus, and 82/168 (49%) vary between DBA/2J and C57BL/6J. Microsatellites provide informative single locus probes for linkage analysis in the construction of a genetic map of the mouse genome.     

TRbase: a database relating tandem repeats to disease genes for the human genome

MOTIVATION: Tandem repeats are associated with disease genes, play an important role in evolution and are important in genomic organization and function. Although much research has been done on short perfect patterns of repeats, there has been less focus on imperfect repeats. Thus, there is an acute need for a tandem repeats database that provides reliable and up to date information on both perfect and imperfect tandem repeats in the human genome and relates these to disease genes. RESULTS: This paper presents a web-accessible relational tandem repeats database that relates tandem repeats to gene locations and disease genes of the human genome. In contrast to other available databases, this database identifies both perfect and imperfect repeats of 1-2000 bp unit lengths. The utility of this database has been illustrated by analysing these repeats for their distribution and frequencies across chromosomes and genomic locations and between protein-coding and non-coding regions. The applicability of this database to identify diseases associated with previously uncharacterized tandem repeats is demonstrated.     

Repetitive sequences in the genome ofAnemone blanda: Identification of tandem arrays and of dispersed repeats

A tandemly repetitive sequence family (AbS1) and a repetitive sequence (Hd) forming part of a larger dispersed element (dorf-1) ofAnemone blanda were characterised. TheAbS1 satellite sequence family is located in all 4,6-diamidino-2-phenylindole (DAPI) positive intercalary heterochromatic bands and in the DAPI positive heterochromatic terminal region of chromosome 3, while the dispersedHd homologous sequences are preferentially associated with euchromatic chromosome regions. The major component of theAbS1 satellite isAbS1-H1 with a basic repeat unit of 1640 bp; a minor fraction (AbS1-H5) consists of 320 bp units. A subsection of theAbS1-H1 repeat unit exhibits homologies to the 25S rRNA gene of flowering plants suggesting that the 1.64 kb satellite was generated by amplification of a precursor satellite and/or single copy sequence together with an rDNA fragment. The rDNA homologous region is considered to evolve at a rate similar to pseudogenes and thus the age of this satellite DNA fraction can be roughly estimated as about 27 million years.The dispersed repeated sequenceHd (about 1300 bp) is associated with the 8 kb elementdorf-1. A. blanda dorf-1 constitutes about 0.2% of the genome (3×10⁴ copies), is bounded by identical long terminal repeats, and exhibits partial homology to theLilium gypsy-type elementdell, but has yet to be confirmed as a retrotransposon. In contrast to theAbS1 satellite sequence family,Hd homologous sequences were found not only inA. apennina, the closest relative ofA. blanda, but also inA. nemorosa andA. ranunculoides indicating that a progenitor sequence ofdorf-1 was present in a common ancestor before speciation ocurred.     

Identification and characterization of short tandem repeats in the Tibetan macaque genome based on resequencing data

The Tibetan macaque, which is endemic to China,is currently listed as a Near Endangered primate species by the International Union for Conservation of Nature(IUCN)(2017). Short tandem repeats(STRs) refer to repetitive elements of genome sequence that range in length from 1–6 bp. They are found in many organisms and are widely applied in population genetic studies. To clarify the distribution characteristics of genome-wide STRs and understand their variation among Tibetan macaques,we conducted a genome-wide survey of STRs with next-generation sequencing of five macaque samples.A total of 1077 790 perfect STRs were mined from our assembly, with an N50 of 4 966 bp. Mono-nucleotide repeats were the most abundant, followed by tetraand di-nucleotide repeats. Analysis of GC content and repeats showed consistent results with other macaques. Furthermore, using STR analysis software(lob STR), we found that the proportion of base pair deletions in the STRs was greater than that of insertions in the five Tibetan macaque individuals(P0.05, t-test). We also found a greater number of homozygous STRs than heterozygous STRs(P0.05,t-test), with the Emei and Jianyang Tibetan macaques showing more heterozygous loci than Huangshan Tibetan macaques. The proportion of insertions and mean variation of alleles in the Emei and Jianyang individuals were slightly higher than those in the Huangshan individuals, thus revealing differences in STR allele size between the two populations.The polymorphic STR loci identified based on the reference genome showed good amplification efficiency and could be used to study population genetics in Tibetan macaques. The neighbor-joining tree classified the five macaques into two different branches according to their geographical origin,indicating high genetic differentiation between the Huangshan and Sichuan populations. We elucidated the distribution characteristics of STRs in the Tibetan macaque genome and provided an effective method for screening polymorphic STRs. Our results also lay a foundation for future genetic variation studies of macaques.     

DNA typing and genetic mapping with trimeric and tetrameric tandem repeats.

Tandemly reiterated sequences represent a rich source of highly polymorphic markers for genetic linkage, mapping, and personal identification. Human trimeric and tetrameric short tandem repeats (STRs) were studied for informativeness, frequency, distribution, and suitability for DNA typing and genetic mapping. The STRs were highly polymorphic and inherited stably. A STR-based multiplex PCR for personal identification is described. It features fluorescent detection of amplified products on sequencing gels, specific allele identification, simultaneous detection of independent loci, and internal size standards. Variation in allele frequencies were explored for four U.S. populations. The three STR loci (chromosomes 4, 11, and X) used in the fluorescent multiplex PCR have a combined average individualization potential of 1/500 individuals. STR loci appear common, being found every 300-500 kb on the X chromosome. The combined frequency of polymorphic trimeric and tetrameric STRs could be as high as 1 locus/20 kb. The markers should be useful for genetic mapping, as they are sequence based, and can be multiplexed with the PCR. A method enabling rapid localization of STRs and determination of their flanking DNA sequences was developed, thus simplifying the identification of polymorphic STR loci. The ease by which STRs may be identified, as well as their genetic and physical mapping utility, give them the properties of useful sequence tagged sites (STSs) for the human genome initiative.