A highly repeated retropseudogene-like sequence in DNA of the redbreasted merganser (Mergus serrator)

Two highly repeated nucleotide sequences (RBMI and RBMII) cloned from an EcoRI digest of DNA of the redbreasted merganser (Mergus serrator) account for approx. 5 to 10% of the DNA of M. serrator and the closely related Mergus merganser. Complete DNA digestion of seven members of the Mergini with EcoRI produces distinct, relatively species-specific patterns of a few high-Mr (greater than 1.5 kb) fragments of RBMI-like material. In such digests RBMII forms ladder-type patterns with monomers of approx. 200 bp. The sequence of a cloned 2.6-kb RBMI fragment from M. serrator contains several extended (up to 70 bp) and modified poly(dA) sequences, two open reading frames in opposite orientation to the longest poly(dA) sequence and two direct 10-bp repeats suggesting that RBMI is a rearranged retropseudogene-like element.     

Insertion and amplification of a DNA sequence in satellite DNA of Cucumis sativus L. (cucumber)

Summary Another satellite DNA repeat (type IV) in the genome of Cucumis sativus (cucumber) was found and investigated with respect to DNA sequence, methylation, and evolution. This satellite shows a repeat length of 360 bp and a GC-content of 47%. The repeats of type IV are highly conserved among each other. Evidence for CG and CNG methylation is presented. By comparison to the previously described satellites (type I/II and type III) from cucumber, it is evident that this repeat is created by an insertion of a 180 bp DNA sequence similar to type I–III into another DNA sequence (or vice versa), and subsequent amplification forming a new satellite repeat. The different satellites of the type I/II, type III, and the 180 bp insert of type IV show a sequence homology of 60%–70%, indicating that the complex satellite DNA of cucumber is originated from a common progenitor by mutation, additional insertion, and amplification events. Copies of a sequence similar to a part of type IV are present in the genome of the related species Cucumis melo (melon).     

Mysticete (baleen whale) relationships based upon the sequence of the common cetacean DNA satellite.

The genomes of all extant cetaceans are characterized by the presence of the so-called common cetacean DNA satellite. In the mysticetes (whalebone whales) the repeat length of the satellite is 1,760 bp. In the odontocetes (toothed whales), other than the family Delphinidae, the repeat length is usually approximately 1,740 bp. The Delphinidae are characterized by a repeat length of approximately 1,580 bp. It has been shown in odontocetes that the satellite evolves in concert and that differences between species, with respect to the sequence of the satellite, correspond reasonably well to their evolutionary distances. In the present study the sequence of the satellite was determined in three repeats in each of seven mysticete species, and a consensus for each species established. Parsimony and neighbor-joining analyses based upon sequences of all repeats showed that the primary evolutionary distinction among the mysticetes is between the Balaenidae sensu stricto (i.e., the bowhead whale and the right whale) and all remaining species, including the pygmy right whale, a species that usually has been included in the Balaenidae. The comparisons also showed that the humpback whale and the gray whale were approximately equidistant from the blue whale and the fin whale (genus Balaenoptera). Concerted evolution of the satellite was also demonstrated among the mysticetes, but it appeared to evolve more slowly in the mysticetes than in the odontocetes.     

简单重复DNA序列在哺乳动物mtDNA D-loop区的分布及进化特征

简单重复序列广泛分布于从原核到真核生物的基因组中, 其形成的分子机理目前尚不明确。对NCBI数据库中已有256种哺乳动物线粒体DNA (mtDNA) D-loop区进行序列比对分析, 根据其所含有的简单重复序列类型分为3组, 分别是53种哺乳动物含有六核苷酸重复序列; 104种哺乳动物含有非六核苷酸重复序列(＞6 bp); 99种哺乳动物不含有任何重复序列。通过碱基序列分析比对, 发现六核苷酸重复序列集中分布在CSB1-CSB2间隔区, 而非六核苷酸重复可以分布于终止区(TAS)、中央保守区(Central domain)以及CSB(Central sequence block)区。通过比较含有重复序列与不含重复序列的功能保守区发现, 简单重复序列的存在并不明确影响D-loop区内的中央保守区以及CSB1、CSB2、CSB3三个功能保守区的碱基序列保守性。在此基础上, 利用N-J法构建了256种哺乳动物的进化树, 分析了哺乳动物D-Loop区内重复序列在进化过程中的可能变化规律, 发现简单重复序列随着物种的进化地位的升高而呈现消失趋势。     

Application of inter-simple sequence repeats to insect cell lines: identification at the clonal and tissue-specific level

Inter-simple sequence repeat (ISSR) primers designed to anneal to microsatellites were used to obtain deoxyribonucleic acid (DNA) fingerprint profiles to distinguish among 16 established insect cell lines derived from an assortment of lepidopteran, dipteran, and coleopteran species. Three different levels of cell line comparison were made: (1) between parents and their clones, (2) among cell lines derived from different tissues from the same species, and (3) among cell lines derived from different insect species. Of the 16 repeat oligonucleotide primers used in this study, nine primers generated several unique markers to distinguish between parental cell lines and their clones. Four of the 16 primers also generated DNA profiles with a number of unique bands, enabling the distinction among cell lines derived from specific tissues from the same species. In addition, ISSR-generated DNA profiles provided the greatest number of unique markers to distinguish easily among insect cell lines derived from different species.     

Conservation of (TTAGG)(n) telomeric sequences among ants (Hymenoptera,Formicidae)

To determine the telomere sequence in Tapinoma nigerrimum, we carried out in situ hybridization using TTAGGG and TTAGG repeat polymerase chain reaction (PCR)-generated probes. No hybridization signals were found when TTAGGG was used as a probe. However, strong signals were observed at the end of the chromosomes with the TTAGG probe. Southern blot analysis carried out on genomic DNA using TTAGG as a probe showed a strong hybridization signal even under highly stringent conditions. Similar results were obtained in Southern blot analysis carried out on genomic DNA of 19 species of ants belonging to three different subfamilies. In accordance with all the results shown in this article, the TTAGG repeat seems to be the major component of the telomere sequence in the majority of ant species.     

Characterization and organization of DNA sequences adjacent to the human telomere associated repeat (TTAGGG)n.

We present a strategy for the cloning of DNA sequences adjacent to the tandemly repeated DNA sequence (TTAGGG)n. Sequence analysis of 14 independently isolated clones revealed the presence of non-repetitive sequences immediately adjacent to or flanked by blocks of the simple repeat (TTAGGG)n. In addition, we provide sequence information on two previously undescribed tandemly repeated sequences, including a 9 bp repeat and a modification of the (TTAGGG)n repeat. Using different mapping approaches six sub-clones, free of the TTAGGG repeat, were assigned to a single human chromosome. Moreover, in situ hybridization mapped one of these subclones, G2 - 1H, definitively to the telomeric band on chromosome 4q. However, Bal 31 insensitivity suggests a location in a more subterminal region. All the (TTAGGG)n-adjacent unique sequences tested are highly conserved among primates but are not present in other mammalian species. Identification and mapping of TTAGGG-adjacent sequences will provide a refined insight into the genomic organization of the (TTAGGG)n repeat. The isolation of chromosome specific TTAGGG-adjacent sequences from subtelomeric regions of all human chromosomes will serve as important end points for the genetic maps and will be useful for the molecular characterization of chromosomal rearrangements involving telomeres.     

Lineage-Specific Tandem Repeats Riding on a Transposable Element of MITE in <Emphasis Type="Italic">Xenopus</Emphasis> Evolution: A New Mechanism for Creating Simple Sequence Repeats

Xstir is a repetitive DNA sequence element that is extremely amplified as a common component of two different structures: a tandem repeat (Xstir array) and a MITE (miniature inverted-repeat transposable element) in the genome of Xenopus laevis. To elucidate the origin and evolutionary history of Xstir-related sequences, we investigated their species specificity among three Xenopus species (X. laevis, X. borealis, and X. tropicalis). Analyses by sequence alignment and digestion with restriction enzymes of genomic Xstir-related sequences revealed that the MITE (Xmix MITE) was well conserved among the three Xenopus species, with small lineage-specific differences. On the other hand, the tandem repeat element (tropXstir) in X. tropicalis was different from the Xstir that X. laevis and X. borealis have in common. Both sequences of Xstir and tropXstir were, however, different segments of the Xmix MITE. The results suggest that these tandem repeats were formed by partial tandem duplication of the MITE internal sequence in each lineage of X. tropicalis and of X. borealis/X. laevis after their branching. A molecular mechanism for creating and elongating the tandem repeats from the MITE is proposed.Reviewing Editor: Dr. Jerzy Jurka     

Structure of the 5S rRNA genes in birch (Betula papyrifera) and alder (Alnus incana).

Hybridization of a 5S rDNA probe to Southern transfers of birch (Betula papyrifera) or alder (Alnus incana) DNA digested with BamH1 reveals similar triple-band "ladder-like" patterns. The sizes of sequenced 5S repeat units from both plants ranges only from 471 to 490 base pairs, suggesting that the complexity detected by Southern analysis is not due to different size classes of 5S repeats as found in other species. Within the intercistronic spacer region, conservation of large blocks of sequence between birch and alder 5S is observed implying a close evolutionary relationship between these two species. In both species, a duplication of part of the coding sequence including a restriction site for BamH1 introduces a second BamH1 site into the repeat unit. Differential methylation of the two BamHI restriction sites can account for the observed triple-band pattern.     

The spread of sequence variants in Rattus satellite DNAs

The genus Rattus has two related families of satellite DNA: Satellite I consists of tandem arrays of a 370 base pair repeat unit which is a dimer of two 185 base pair portions (a, b) which are about 60% homologous. Satellite I' consists of tandem arrays of a 185 base pair repeat unit (a') which is about 85% homologous to a and 60% homologous to b. R. norvegicus contains only satellite I but R. rattus contains both satellites I and I'. We examined certain aspects of satellite DNA evolution by comparing the spacing at which variant repeat units of each satellite have spread among non-variant repeat units in these two species. With but one exception, in R. rattus, 15 different variant repeat units have spread among non-variant repeat units of satellite I, with a spacing equal to the length of the (a,b) dimer. Similarly, fourteen different variant repeat units of the monomeric satellite I' have mixed among non-variant repeat units with a spacing equal to the length of the (a') monomer. These results suggest that a mechanism involving homologous interaction among satellite sequences could account for the spread of variant family members. We also found that a sequence variant present in certain portions of the dimeric repeat unit of satellite I is more efficiently amplified (or less efficiently corrected) than variants occurring in other regions. This was not true for the monomeric repeat unit of satellite I'.     

Distinguishing Anuran species by high‐resolution melting analysis of the COI barcode (COI‐HRM)

Taxonomic identification can be difficult when two or more species appear morphologically similar. DNA barcoding based on the sequence of the mitochondrial cytochrome c oxidase 1 gene (COI) is now widely used in identifying animal species. High‐resolution melting analysis (HRM) provides an alternative method for detecting sequence variations among amplicons without having to perform DNA sequencing. The purpose of this study was to determine whether HRM of the COI barcode can be used to distinguish animal species. Using anurans as a model, we found distinct COI melting profiles among three congeners of both Lithobates spp. and Hyla spp. Sequence variations within species shifted the melting temperature of one or more melting domains slightly but do not affect the distinctness of the melting profiles for each species. An NMDS ordination plot comparing melting peak profiles among eight Anuran species showed overlapping profiles for Lithobates sphenocephala and Gastrophryne carolinensis. The COI amplicon for both species contained two melting domains with melting temperatures that were similar between the two species. The two species belong to two different families, highlighting the fact that COI melting profiles do not reveal phylogenetic relationships but simply reflect DNA sequence differences among stretches of DNA within amplicons. This study suggests that high‐resolution melting analysis of COI barcodes (COI‐HRM) may be useful as a simple and rapid method to distinguish animal species that appear morphologically similar.     

Internal Eliminated Segments (IESs) of Oxytrichidae1

ABSTRACT Internal eliminated segments (IESs) are sequences that interrupt coding and noncoding regions of germline (micronuclear) genes of ciliated protozoa. IESs are flanked by short, unique repeat sequences, which are presumably required for precise IES excision during macronuclear development. Coding and noncoding segments of genes separated by IESs are called macronuclear-destined segments, or MDSs. We have compiled the characteristics of 89 individual IESs in 12 micronuclear genes in the Oxytricha and Stylonychia genera to define the IES phenomenon precisely, a first step in determining the origin, function and significance of IESs. Although all 89 IESs among the 12 different genes are AT-rich, they show no other similarity in sequence, length, position or number. Two main types of IESs are present. IESs that separate scrambled MDSs are significantly shorter and more frequent and have longer flanking repeat sequences than IESs that intervene between nonscrambled MDSs. A comparison of the nonscrambled gene encoding β-telomere binding protein in three species of hypotrichs shows that even in the same gene IESs are not conserved in sequence, length, position, or number from species to species. A comparison of IESs in the scrambled gene encoding actin I in the three species shows that the evolutionary behavior of IESs in a scrambled gene may be more constrained. However, IESs in the scrambled actin I gene have shifted along the DNA molecule during evolution. In total, the various studies show that IESs are hypermutable in sequence and length. They insert, excise, and shift along DNA molecules more or less randomly during evolution, with no discernible function or consequences.     

Satellite DNA repeat sequence variation is low in three species of burying beetles in the genus Nicrophorus (Coleoptera: Silphidae)

Three satellite DNA families were identified in three species of burying beetles, Nicrophorus orbicollis, N. marginatus, and N. americanus. Southern hybridization and nucleotide sequence analysis of individual randomly cloned repeats shows that these satellite DNA families are highly abundant in the genome, are composed of unique repeats, and are species-specific. The repeats do not have identifiable core elements or substructures that are similar in all three families, and most interspecific sequence similarity is confined to homopolymeric runs of A and T. Satellite DNA from N. marginatus and N. americanus show single-base-pair indels among repeats, but single-nucleotide substitutions characterize most of the repeat variability. Although the repeat units are of similar lengths (342, 350, and 354 bp) and A + T composition (65%, 71%, and 71%, respectively), the average nucleotide divergence among sequenced repeats is very low (0.18%, 1.22%, and 0.71%, respectively). Transition/transversion ratios from the consensus sequence are 0.20, 0.69, and 0.70, respectively.      

Cross-species transferability of G. arboreum-derived EST-SSRs in the diploid species of Gossypium

Diploid species with a common Gossypium origin are highly diverse in morphology and have been classified into eight genomic groups designated A–G and K. In this study, the transferability of 207 Gossypium arboreum-derived expressed sequence tag-simple sequence repeat (EST-SSR) primer pairs was examined among 25 different diploid accessions representing 7 genomes and 23 Gossypium species. We found that 124 of the 207 (60%) primer pairs produced amplification products in all 25 accessions. The remaining 83 (40%) primer pairs produced amplification in only a subset of species, ranging from 13 to 22 species, which is consistent with some genome- and species-specific amplification. The cross-species amplification of these EST-SSRs in 22 diploid species was 96.5% in 4,554 combinations (207 SSRs×22 species), indicative of a high transferability among the Gossypium species. Furthermore, a high level of polymorphism with an average number of 6.53 alleles per SSR marker was detected. No correlation was found between the repeat motif type and cross-species amplification. DNA sequencing showed that the high-level polymorphism findings was mainly due to changes in the number of repeat motifs and that the high transferability can be attributed to a higher-level conservation in the flanking regions among these diploid Gossypium species. The transferability among these different diploid species presented here can increase the efficiency of transferring genetic information across species and further enhance their introgression into cultivated cotton species by the molecular tagging of important genes existing in these diploid species using the EST-SSR markers.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Structural and transcriptional analysis of a human subtelomeric repeat

A human subtelomeric repeat (designated as the HST repeat) has been isolated and characterized from a yeast artificial chromosome containing one human telomere. This repeat is located immediately adjacent to the telomeric T2AG3 repeats at the extreme termini of the human chromosomes. The DNA sequence of 3.6 kb of the HST repeat has been determined. The HST repeat spans over 3.6 kb in length, and contains one evolutionarily conserved CpG-rich region. The copy number of the HST repeat varies among telomeres. Genomic hybridization experiments suggest that the HST repeat consists of two distinct segments, and the distal portions of the HST repeat are also distributed elsewhere in the genome. In HeLa cells, the HST repeat sequence appears to be transcribed into a 6 kb polyadenylated RNA and a variety of non-polyadenylated RNA species.     

Extensive Direct-Tandem Organization of a Long Repeat DNA Sequence on the Y Chromosome of Chinook Salmon (Oncorhynchus tshawytscha)

A long repetitive DNA sequence (OtY8) has been cloned from male chinook salmon and its genomic organization has been characterized. The repeat has a unit length of 8 kb and is present approximately 300 times per diploid male nucleus. All internal fragments within the 8-kb repeat segregate from father to son, suggesting that the entire repeat unit is located on the Y chromosome. The organization of this sequence into an 8-kb repeat unit is restricted to the Y chromosome, as are several male-specific repeat subtypes identified on the basis of restriction-site variation. The repeat possesses only weak internal sequence similarities, suggesting that OtY8 has not arisen by duplication of a smaller repeat unit, as is the case for other long tandem arrays found in eukaryotes. Based on a laddered pattern arising from partial digestion of genomic DNA with a restriction enzyme which cuts only once per repeat unit, this sequence is not dispersed on the Y chromosome but is organized as a head-to-tail tandem array. Pulse-gel electrophoresis reveals that the direct-tandem repeats are organized into at least six separate clusters containing approximately 12 to 250 copies, comprising some 2.4 Mb of Y-chromosomal DNA in total. Related sequences with nucleotide substitutions and DNA insertions relative to the Y-chromosomal fragment are found elsewhere in the genome but at much lower copy number and, although similar sequences are also found in other salmonid species, the amplification of the repeat into a Y-chromosome-linked tandem array is only observed in chinook salmon. The OtY8 repetitive sequence is genetically tightly associated with the sex-determination locus and provides an opportunity to examine the evolution of the Y chromosome and sex determination process in a lower vertebrate. Received: 4 April 1997 / Accepted: 22 July 1997     

Using a pericentromeric interspersed repeat to recapitulate the phylogeny and expansion of human centromeric segmental duplications

Despite considerable advances in sequencing of the human genome over the past few years, the organization and evolution of human pericentromeric regions have been difficult to resolve. This is due, in part, to the presence of large, complex blocks of duplicated genomic sequence at the boundary between centromeric satellite and unique euchromatic DNA. Here, we report the identification and characterization of an approximately 49-kb repeat sequence that exists in more than 40 copies within the human genome. This repeat is specific to highly duplicated pericentromeric regions with multiple copies distributed in an interspersed fashion among a subset of human chromosomes. Using this interspersed repeat (termed PIR4) as a marker of pericentromeric DNA, we recovered and sequence-tagged 3 Mb of pericentromeric DNA from a variety of human chromosomes as well as nonhuman primate genomes. A global evolutionary reconstruction of the dispersal of PIR4 sequence and analysis of flanking sequence supports a model in which pericentromeric duplications initiated before the separation of the great ape species (>12 MYA). Further, analyses of this duplication and associated flanking duplications narrow the major burst of pericentromeric duplication activity to a time just before the divergence of the African great ape and human species (5 to 7 MYA). These recent duplication exchange events substantially restructured the pericentromeric regions of hominoid chromosomes and created an architecture where large blocks of sequence are shared among nonhomologous chromosomes. This report provides the first global view of the series of historical events that have reshaped human pericentromeric regions over recent evolutionary time.     

High variation in repetitive DNA fragment length for white spot syndrome virus (WSSV) isolates in Thailand

White spot syndrome virus (WSSV) presently causes the most serious losses to shrimp farmers worldwide. Earlier reports of high DNA sequence homology among isolates from widely separated geographical regions suggested that a single virus was the cause. However, we have found surprisingly high variation in the number of 54 bp DNA repeats in ORF94 (GenBank AF369029) from 55 shrimp ponds (65 shrimp samples) experiencing WSSV outbreaks in Thailand in 2000 and 2002. These were detected by PCR amplification using primers ORF94-F and ORF94-R flanking the repeat region. Altogether, 12 different repeat groups were found (from 6 to 20 repeats) with 8 repeats being most frequent (about 32%). Extracts prepared from individual shrimp in the same outbreak pond belonged to the same repeat group while those collected at the same time from separate WSSV outbreak ponds, or from the same ponds at different times, usually belonged to different repeat groups. This suggested that different outbreaks were caused by different WSSV isolates. In contrast to the highly variable numbers of repeats, sequence variation within the repeat region was confined to either T or G at Position 36. These variations may be useful for epidemiological studies on the local and global movement of WSSV, since there is high variation in the number of repeats (good for local studies) but little sequence change (good for global studies).     

The 5.8S RNA gene sequence and the ribosomal repeat of Schizosaccharomyces pombe

We have characterized the rRNA gene repeat in Schizosaccharomyces pombe. This repeat, which does not contain the 5S RNA gene, is found in a 10.4 kb HindIII DNA fragment. We have determined the nucleotide sequences of the S. pombe 5.8S RNA gene and intergenic spacers from two different 10.4 kb DNA fragments. Analysis of isolated total cellular 5.8S RNA revealed the presence of eight species of 5.8S RNA, differing in the number of nucleotides at the 5'-end. The eight 4.8S RNA species vary in length from 158 to 165 nucleotides. Apart from the heterogeneity observed at the 5'-end, the sequence of the eight 5.8S RNA species appears to be identical and is the same sequence as coded for by the 5.8S genes. The gene sequence shows great homology to the 5.8S RNA genes or S. cerevisiae and N. crassa. Most of the base differences are confined to the highly variable stem though to be involved in co-axial helix stacking with the 25S RNA, where base pairing is nearly identical despite the sequence differences. Secondary structure models are examined in light of 5.8S RNA oligonucleotide conservation across species from yeasts to higher eukaryotes.