Nucleotide sequences and stability of a Nicotiana nuclear DNA segment possessing autonomously replicating ability in yeast

The nucleotide sequence of a tobacco (Nicotiana tabacum) chromosomal DNA segment(t3-ars) capable of replication in yeast (ars: autonomously replicating sequences) is presented. The subcloned region (618 bp) contained 11 bp consensus (5 A/TTTTATP_uTTTA/T 3) essential for several yeast ars, and 73% A and T. Unique 70 bp repetitive sequences resided next to this sequence. Thirty-two bp AT repeats were also seen in the neighbourhood of the repetitive sequence. The hybrid plasmid containing t3-ars was mitotically stabilized by the help of yeast centromere (CEN4).     

Differential expansion of highly repeated DNA sequences in the swine subgenomes

Differences in highly repeated DNA sequences among three swine breeds genomes were detected by means of whole‐comparative genomic hybridization (W‐CGH). The results showed that Duroc, Iberian and Landrace/Large White breeds share similar DNA sequences in their centromeric regions, but the number of copies of the highly repeated DNA sequences building the blocks of heterochromatin in the metacentric chromosomes is differentially expanded among them. That is not the case in the acrocentric subgenome where the chromosomes share similar sequence composition and number of copies among the three breeds in the centromeric regions. The highly repeated DNA sequences in the chromosome Y also displayed differences among the breeds studied. The reported results are discussed in the light of the possible evolutionary tendencies of these particular DNA sequences.     

Genomic organization of Trypanosoma brucei kinetoplast DNA minicircles

The sequences of seven new Trypanosoma brucei kinetoplast DNA minicircles were obtained. A detailed comparative analysis of these sequences and those of the 18 complete kDNA minicircle sequences from T. brucei available in the database was performed. These 25 different minicircles contain 86 putative gRNA genes. The number of gRNA genes per minicircle varies from 2 to 5. In most cases, the genes are located between short imperfect inverted repeats, but in several minicircles there are inverted repeat cassettes that did not contain identifiable gRNA genes. Five minicircles contain single gRNA genes not surrounded by identifiable repeats. Two pairs of closely related minicircles may have recently evolved from common ancestors: KTMH1 and KTMH3 contained the same gRNA genes in the same order, whereas KTCSGRA and KTCSGRB contained two gRNA genes in the same order and one gRNA gene specific to each. All minicircles could be classified into two classes on the basis of a short substitution within the highly conserved region, but the minicircles in these two classes did not appear to differ in terms of gRNA content or gene organization. A number of redundant gRNAs containing identical editing information but different sequences were present. The alignments of the predicted gRNAs with the edited mRNA sequences varied from a perfect alignment without gaps to alignments with multiple mismatches. Multiple gRNAs overlapped with upstream gRNAs, but in no case was a complete set of overlapping gRNAs covering an entire editing domain obtained. We estimate that a minimum set of approximately 65 additional gRNAs would be required for complete overlapping sets. This analysis should provide a basis for detailed studies of the evolution and role in RNA editing of kDNA minicircles in this species.     

Sequence analysis of three fragments of maize nuclear DNA which replicate autonomously in yeast

There maize nuclear DNA fragments were isolated on the basis of their ability to confer replication on chimeric plasmids in yeast. These Eco RI fragments of 2.5, 2.8 and 5.5 kb are repeated elements within the maize genome. The 2.5 and 2.8 kb fragments represent a family of elements repeated 11 000 times in the maize haploid genome, while the 5.5 kb fragment is part of another family of 28 000 elements. These fragments were subcloned to further define the unique region of ARS activity. The sequence of each 550–650 bp ARS subclone is reported here, and compared to the flanking regions which do not show ARS activity. The ARS elements are 65–70% A+T as compared to 50–55% for the maize genome as a whole. There is approximately 15% sequence divergence, as well as variation of ARS efficiency, among family members. ARS subclones contain the proposed yeast consensus sequence.     

Genomic organization of the canrep repetitive DNA in Brassica juncea

Canrep is a heterogeneous, tandemly repeated, 176 bp nucleotide sequence that contains a single Hind III site and is present in high copy numbers in the genomes of many Brassica species. Complete clusters of repeats of this DNA were cloned from the nuclear DNA of Brassica juncea. Restriction-fragment dimers and higher multimers of the 176 bp sequence have arisen by mutations within the Hind III recognition sequence. Adjacent repeats from within the same cluster usually have different nucleotide sequences with features indicating that diversity is generated by a mechanism that causes site-specific base substitutions. While most of the units of canrep DNA are clustered in long arrays of tandem repeats, some are dispersed throughout the genome as isolated copies or in small clusters. Regardless of the size of the arrays, each cluster begins and ends with a variable-length, truncated repeat and is flanked by inverted copies of the sequence 5-ATCTCAT3-,which is not part of the basic sequence of the canrep family of DNAs. Furthermore, some clusters are located close to nucleotide sequences related to those of known plant transposons. Thus, canrep elements may be dispersed by transposition. There are two distinct subfamilies of canrep sequences in B. juncea, and one of these is closely related to one of the two subfamilies of this type of DNA from B. napus, indicating that it originated from B. campestris, the common diploid ancestor of both amphidiploid species. Neither the repetitive DNA nor nucleotide sequences flanking canrep clusters are transcribed in seedlings, suggesting that even small arrays of repeats are located in heterochromatic regions and might be involved in chromatin condensation and/or chromosome segregation.     

Newly evolved highly repeated DNA sequences ofTupaia glis (Tupaiidae,Scandentia)

We have studied highly repeated DNA sequences ofTupaia glis (Tupaiidae, Scandentia) with restriction endonucleases and Southern blotting techniques. Five highly repeated DNA fragments have been isolated fromT. glis and hybridized with genomic DNAs (cleaved by different restriction enzymes) of several non-human primate species and one insectivore (E. europaeus), in order to highlight eventual differences or similarities of their highly repeated DNA sequences. Our first preliminary findings suggest that the newly isolated highly repeated DNA fragments ofT. glis are distinct from both non-human primates and insectivore, the two taxonomic groups considered most similar to the Tupaiidae.     

高等植物DNA重复序列的主要类型和特点

高等植物核基因组的一个显著特征是其内含有大量的ＤＮＡ重复序列,因此它们在核基因组结构和功能研究中居于举足轻重的地位。一些ＤＮＡ重复序列已日趋广泛地作为分子民用于构建遗传图谱、鉴别品种、研究进化和分离目标基因等。主要介绍高等植物几类重要ＤＮＡ重复序列,如卫星ＤＮＡ、微卫星ＤＮＡ、核糖体ＲＮＡ基因、端粒重复序列和转座子等的若干特点和用途。     

Sequence analysis of Vicia faba highly repeated DNA: the BamHI repeated sequence families

Cleavage of Vicia faba nuclear DNA with the restriction endonuclease BamHI yielded discrete size classes of 250, 850, 900, 990, 1 150, 1 500 and 1 750 bp of highly repetitive DNA. Each of these sequence families comprised about 3% of the total genomic DNA. Some sequence members from each sequence family were cloned in pBR322 and their primary structures determined. Computer analyses of nucleotide sequences suggested the existence of about 60 bp sequence periodicity within the repeating unit of the 990 bp sequence family, though the extent of homology among the surmised shorter subrepeat units was very low. With other BamHI sequence families, however, the data did not show any clear internal sequence periodicity. The repeat units of the 850 bp and 1 750 bp sequence families contained nucleotide sequences homologous to the 250 bp family sequence. No sequence relationship between or among other sequence families was observed. There was 13–25% sequence variation among 6 cloned members of the 250 bp family and probably also among those of other BamHI repeat families. DNA sequences homologous to these V. faba BamHI repeat families were detected in Pisum sativum DNA by Southern blot hybridization. Furthermore, very weak cross-hybridization was observed with plant DNAs from Phaseolus vulgaris, Triticum aestivum, Cucumis sativus and Trillium kamtschaticum.     

An autonomously replicating sequence from HeLa DNA shows a similar organization to the yeast ARS1 element

Summary A HeLa DNA fragment, which may function as an anchorage point to the nuclear matrix for human chromosomes 1 and 2, also functions as an autonomously replicating sequence (ARS) in the yeast Saccharomyces cerevisiae. In the present report we show that this DNA fragment contains both bent DNA and an A-T rich region which appear to be associated with the ARS function. More interestingly, DNA sequence analysis shows that the spatial distribution of these features is strikingly similar to that found in the yeast ARS1 element.     

Genome deterioration: loss of repeated sequences and accumulation of junk DNA

A global survey of microbial genomes reveals a correlation between genome size, repeat content and lifestyle. Free-living bacteria have large genomes with a high content of repeated sequences and self-propagating DNA, such as transposons and bacteriophages. In contrast, obligate intracellular bacteria have small genomes with a low content of repeated sequences and no or few genetic parasites. In extreme cases, such as in the 650kb-genomes of aphid endosymbionts of the genus Buchnera all repeated sequences above 200bp have been eliminated. We speculate that the initial downsizing of the genomes of obligate symbionts and parasites occurred by homologous recombination at repeated genes, leading to the loss of large blocks of DNA as well as to the consumption of repeated sequences. Further sequence elimination in these small genomes seems primarily to result from the accumulation of short deletions within genic sequences. This process may lead to temporary increases in the genomic content of pseudogenes and junk DNA. We discuss causes and long-term consequences of extreme genome size reductions in obligate intracellular bacteria.     

Replication pattern of human repeated DNA sequences

Either aphidicolin- or thymidine-synchronized human HL-60 cells were used to study the replication pattern of a family of human repetitive DNA sequences, the EcoRI 340 bp family (αRI-DNA), and of the ladders of fragments generated in total human DNA after digestion with XbaI and HaeIII (alpha satellite sequences). DNAs replicated in early, middle-early, middle-late and late S periods were labelled with BUdR or with [³H]thymidine. The efficiency of the cell synchronization procedure was confirmed by the transition from a high-GC to a high-AT average base composition of the DNA synthesized going from early to late S periods. By hybridizing EcoRI 340 bp repetitive fragments to BUdR-DNAs it was found that this family of sequences is replicated throughout the entire S period. Comparing fluorograph densitometric scans of [³H]DNAs to the scans of ethidium bromide patterns of total HL-60 DNA digested with XbaI and HaeIII, it was observed that DNA synthesized in different S periods is characterized by approximately the same ladder of fragments, while the intensity of each band may vary through the S phase; in particular, the XbaI 2.4 kb fragment becomes undetectable in late S.     

First nuclear DNA C-values for 18 eudicot families

BACKGROUND AND AIMS: A key target set at the second Plant Genome Size Workshop, held at the Royal Botanic Gardens, Kew in 2003, was to produce first DNA C-value data for an additional 1 % of angiosperm species, and, within this, to achieve 75 % familial coverage overall (up from approx. 50 %) by 2009. The present study targeted eudicot families for which representation in 2003 (42.5 %) was much lower than monocot (72.8 %) and basal angiosperm (69.0 %) families. METHODS: Flow cytometry or Feulgen microdensitometry were used to estimate nuclear DNA C-values, and chromosome counts were obtained where possible. KEY RESULTS: First nuclear DNA C-values are reported for 20 angiosperm families, including 18 eudicots. This substantially increases familial representation to 55.2 % for angiosperms and 48.5 % for eudicots. CONCLUSIONS: The importance of targeting specific plant families to improve familial nuclear DNA C-value representation is reconfirmed. International collaboration will be increasingly essential to locate and obtain material of unsampled plant families, if the target set by the second Plant Genome Size Workshop is to be met.     

Highly repeated DNA sequences and systematics of malagasy primates

We have analyzed highly repeated DNA sequences of Malagasy lemurs with restriction enzymes, Southern blotting and nucleotide sequencing to assess relatedness among repeated DNA fragments from different species. We have focused our studies on two prosimian families:Lemuridae andCheirogaleidae. Our results have allowed us to draw the following conclusions: confirmation of the separation based on molecular biology data ofEulemur species from theLemur catta/Hapalemur group; classification ofVarecia in a genus clearly separated from the otherLemuridae genera; confirmation of the specific status ofHapalemur aureus; confirmation of cytogenetic data in favour of the subdivision of the familyCheirogaleidae into two subfamilies:Cheirogaleinae andPhanerinae. Finally a cladogram has been constructed by numbering all the highly repeated DNA fragments (obtained by Southern blotting) and analyzing the inferred systematic relationships between the Lemuridae and Cheirogaleidae species.     

Distribution and clustering of two highly repeated sequences in the A and B chromosomes of maize

Summary Clones from a family of highly repeated sequences present in a heterochromatin rich maize line have been characterized by sequencing and chromosome location. The repeats differ from each other in length and degree of sequence homology, and show areas rich in purine and pyrimidine. In situ hybridization experiments indicate that the repeats are mainly located in the knob heterochromatin of the A chromosomes and the centromeric heterochromatin of the B chromosome. However, in addition to previously published data, some copies are also distributed in euchromatic regions of the A chromosomes and in the distal heterochromatic block of the B chromosome. The results are discussed in relation to the centromeric activity of maize heterochromatin.Research work is sponsored by C.N.R. Italy, Special grant I.P.R.A., Subproject 1, Paper No. 300     

Genomic organization of ribosomal DNA and related sequences inTriturus

The ribosomal RNA genes ofTriturus vulgaris meridionalis are clustered at variable and often multiple chromosomal loci. The rDNA repeats exhibit only a limited and discrete length heterogeneity which is accounted for by the non-transcribed spacer (NTS). Interestingly, sequences homologous to the NTS are clustered outside the ribosomal loci. Clones containing such non ribosomal sequences have been isolated from a genomic library ofT. v. meridionalis and analyzed by restriction mapping. These sequences appear to consist mostly of repetitive Bam HI fragments ranging from 500 bp to 1000 bp. The Bam HI fragments are internally repetitious and highly homologous to each other.     

Characterization of a family of tandemly repeated DNA sequences in Triticeae

The recombinant plasmid dpTa1 has an insert of relic wheat DNA that represents a family of tandemly organized DNA sequences with a monomeric length of approximately 340 bp. This insert was used to investigate the structural organization of this element in the genomes of 58 species within the tribe Triticeae and in 7 species representing other tribes of the Poaceae. The main characteristic of the genomic organization of dpTa1 is a classical ladder-type pattern which is typical for tandemly organized sequences. The dpTa1 sequence is present in all of the genomes of the Triticeae species examined and in 1 species from a closely related tribe (Bromus inermis, Bromeae). DNA from Hordelymus europaeus (Triticeae) did not hybridize under the standard conditions used in this study. Prolonged exposure was necessary to obtain a weak signal. Our data suggest that the dpTa1 family is quite old in evolutionary terms, probably more ancient than the tribe Triticeae. The dpTa1 sequence is more abundant in the D-genome of wheat than in other genomes in Triticeae. DNA from several species also have bands in addition to the tandem repeats. The dpTa1 sequence contains short direct and inverted subrepeats and is homologous to a tandemly repeated DNA sequence from Hordeum chilense.     

Molecular organization of great millet (Sorghum vulgare) DNA

Approximately 52% of the nuclear genome of great millet(Sorghum vulgare) consists of repetitive DNA which can be grouped into very fast, fast and slow components. The reiteration frequencies of the fast and slow reassociating components are {dy7000} and 92 respectively. Approximately 90% of the genome consists of repeated sequences interspersed amongst themselves and with single copy sequences. The interspersed repeat sequences are of three sizesviz. > 1·5 kilobase pairs, 0·5–1·0 kilobase pairs and 0·15–0·30 kilobase pairs while the size of the single copy sequences is 3·0 kilobase pairs. Hence the genome organization of great millet is essentially of a mixed type NCL communication No. 3527.