Sequence organization of the rat genome by electron microscopy.

The size and arrangement of repetitive and inverted repeat (foldback) sequences in rat DNA were studied by visualization of hybrid and heteroduplex structures in the electron microscope. The self-reassociation of repetitive sequence-bearing DNA strands often results in the formation of four-ended "H" structures, whose duplex regions equal the repetitive sequence length and can be measured in the electron microscope. In this way, it was determined that the average size of the class of numerous short repetitive sequences is 0.40 +/- 0.15 kbp. Heteroduplex structures were prepared between long whole DNA single strands and short repeat-sequence-bearing strands. The analysis of these structures confirms that the size of the repetitive sequences in 0.4 kbp on average. Length measurements between adjacent duplexes show that the average spacing between two interspersed repeats is at least 1.5-1.8 kbp. By examining 29.4-kbp single strands after brief renaturation, the size and distribution of foldback sequences were determined. There are 1.9 X 10(5) foldback apirs per rat genome, spaced an average of 9.7 kbp apart according to our measurement. Repetitive, inverted repeat and unique sequences are interspersed with each other in at least half the genome.     

Analysis of major repetitive DNA sequences in the dog (Canis familiaris) genome

A systematic screening and analysis of repeated DNA sequences from a dog genomic library composed of small DNA inserts enabled us to characterize abundant canine repetitive DNA families. Four main families were identified: i) a group of highly repeated tRNA-derived short interspersed repetitive DNA elements (tRNA-SINEs); ii) another type of SINE-like element that was mainly found inserted into long interspersed repetitive elements (LINEs); iii) LINEs of the L1 type; and iv) satellite or satellite-like DNA. Surprisingly, no SINEs derived from 7SL RNA were found in the dog genome. These data should help in the analysis of canine DNA sequences and in the design of canine genome mapping reagents. Received: 4 November 1998 / Accepted: 2 February 1999     

DNA sequence organization in the genomes of three related millet plant species

Summary A major portion of the genomes of three millet species, namely, barn yard millet, fox tail millet and little millet has been shown to consist of interspersed repeat and single copy DNA sequences. The interspersed repetitive DNA sequences are both short (0.15–1.0 kilo base pairs, 62–64% and long (>1.5 kilo base pairs, 36–38%) in barn yard millet and little millet while in fox tail millet, only long interspersed repeats (>1.5 kilo base pairs) are present. The length of the interspersed single copy DNA sequences varies in the range of 1.6–2.6 kilo base pairs in all the three species. The repetitive duplexes isolated after renaturation of 1.5 kilo base pairs and 20 kilo base pairs long DNA fragments exhibit a high thermal stability with Tms either equal to or greater than the corresponding native DNAs. The S1 nuclease resistant repetitive DNA duplexes also are thermally stable and reveal the presence of only 1–2% sequence divergence.The present data on the modes of sequence arrangement in millets substantiates the proposed trend in plants, namely, plants with 1C nuclear DNA content of less than 5 picograms have diverse patterns of sequence organization while those with 1C nuclear DNA content greater than 5 picograms have predominantly a short period interspersion pattern.Abbreviations kbp kilobase pairs NCL Communication No. 3606.     

DNA sequence organisation in avian genomes

By means of renaturation kinetics of DNA of the three avian species Cairina domestica, Gallus domesticus and Columba livia domestica the following major DNA repetition classes were observed: a very fast reannealing fraction comprising about 15% of the DNA, a fast or intermediate reannealing fraction that makes up 10%, and a slow reannealing fraction of about 70%, which apparently renatures with single copy properties. — Comparing the reassociation behaviour of short (0.3 kb) and long (>2 kb) DNA fragments of duck and chicken it becomes apparent that only 12% (duck) and 28% (chicken) of the single copy DNA are interspersed with repetitive elements on 2 to 3 kb long fragments. The lengths of the repetitive sequences were estimated by optical hyperchromicity measurements, by agarose A-50 chromatography of S₁ nuclease resistant duplexes and by electron microscopic measurements of the S₁ nuclease resistant duplexes. It was found that in the case of the chicken DNA the single copy sequences alternating with middle repetitive ones are at least 2.3 kb long; the interspersed moderate repeats have a length average of at least 1.5 kb. The sequence length of the moderate repeats in duck DNA is smaller. The results show that the duck and the chicken genomes do not follow the short period interspersion pattern of genome organisation, characteristic of the eucaryotic organisms studied so far.     

Interspersion of repetitive and non-repetitive DNA sequences in the sea urchin genome

Measurements are reported which lead to the conclusion that repetitive and nonrepetitive sequences are intimately interspersed in the majority of the DNA of the sea urchin, Strongylocentrotus purpuratus. Labeled DNA was sheared to various lengths, reassociated with a great excess of 450 nucleotide-long fragments to cot 20, and the binding of the labeled DNA to hydroxyapatite was measured. Repetitive sequences measured in this way are present on about 42% of the 450 nucleotide-long fragments. As the DNA fragment length is increased, larger and larger fractions of the fragments contain repetitive sequences. Analysis of the measurements leads to the following estimate of the quantitative features of the pattern of interspersion of repetitive and nonrepetitive sequences. About 50% of the genome consists of a short-period pattern with 300–400 nucleotide average length repetitive segments interspersed with about 1000 nucleotide average length nonrepetitive segments. Another 20% or more consists of a longer period interspersed pattern. About 6% of the genome is made up of relatively long regions of repetitive sequences. The remaining 22% of the genome may be uninterrupted single copy DNA, or may have more widely spaced repeats interspersed. The similarity of these results to previous measurements with the DNA of an amphibian suggests that this interspersion pattern is of general occurrence and selective importance.     

Arrangement and size distribution of repeat and single copy DNA sequences in four species ofCucurbitaceae

DNA sequence organization patterns have been studied in fourCucurbitaceae plant species, namely,Luffa cylindrica (sponge gourd),L. acutangula (ridge gourd),Benincasa hispida (ash gourd) andCoccinia indica (ivy gourd). Extensive interspersion of repeat and single copy sequences has been observed in sponge gourd and ridge gourd. In ash gourd and ivy gourd, however, there is a limited interspersion of these sequences and a large portion of the single copy DNA remains uninterspersed. The interspersed repetitive sequences are composed of a major class (75–80%) of short repeats (300 base pairs long) and a minor class (15–20%) of long repeats (2 000–4 000 base pairs) in all the four species. The average length of single copy sequences dispersed among repeats is 1 800–2 900 base pairs. In spite of these gross similarities in the genome organization in the four species, the fraction of repeats and single copy sequences involved in short and long period interspersion patterns, and fraction of single copy sequences remaining uninterrupted by repeats are vastly different. The probable implications of these differences with respect to speciation events and rates of genome evolution are discussed.Molecular Analysis ofCucurbitaceae Genomes, III. — NCL Communication No.: 3595.     

Association of a truncated cytochrome c processed pseudogene with a similarly truncated member from a long interspersed repeat family of rat.

The cytochrome c multigene family of rat contains approximately 30 processed pseudogenes that represent genomic DNA copies of three alternate mRNAs. Here, the DNA sequence of an unusual processed pseudogene reveals that it has a complete 3' noncoding region including a short poly A tail but unlike the others is abruptly truncated at its 5' end, 19 amino acid codons from the translation terminator. At this position the pseudogene is fused through 17 consecutive adenylic acid residues to a 1.3 kb repetitive sequence. This repetitive element is flanked by direct repeats and represents a truncated member from a major long interspersed repeat family. The rat element is a composite of sequences observed in long interspersed repeats from both rodents and primates. Comparison to the equivalent mouse sequences shows that the 5' half of the repeat distal to the pseudogene has an open reading frame and is highly conserved whereas the half adjacent to the pseudogene is evolutionarily unstable. The proportion of cytochrome c pseudogene recombinant clones containing this repetitive DNA is 3 fold greater than observed in random isolates and may reflect a general tendency of processed pseudogenes to associate with other repetitive sequences in the genome.     

A chicken middle-repetitive DNA sequence which shares homology with mammalian ubiquitous repeats.

We have identified and sequenced two members of a chicken middle repetitive DNA sequence family. By reassociation kinetics, members of this family (termed CRl) are estimated to be present in 1500-7000 copies per chicken haploid genome. The first family member sequenced (CRlUla) is located approximately 2 kb upstream from the previously cloned chicken Ul RNA gene. The second CRl sequence (CRl)Va) is located approximately 12 kb downstream from the 3' end of the chicken ovalbumin gene. The region of homology between these two sequences extends over a region of approximately 160 base pairs. In each case, the 160 base pair region is flanked by imperfect, but homologous, short direct repeats 10-15 base pairs in length. When the CRl sequences are compared with mammalian ubiquitous interspersed repetitive DNA sequences (human Alu and Mouse Bl families), several regions of extensive homology are evident. In addition, the short nucleotide sequence CAGCCTGG which is completely conserved in ubiquitous repetitive sequence families from several mammalian species is also conserved at a homologous position in the chicken sequences. These data imply that at least certain aspects of the sequence and structure of these interspersed repeats must predate the avian-mammalian divergence. It seems that the CRl family may possibly represent an avian counterpart of the mammalian ubiquitous repeats.     

DNA sequence organization in the genomes of five marine invertebrates

The arrangement of repetitive and non-repetitive sequence was studied in the genomic DNA of the oyster (Crassostrea virginica), the surf clam (Spisula solidissima), the horseshoe crab (Limulus polyphemus), a nemertean worm (Cerebratulus lacteus) and a jelly-fish (Aurelia aurita). Except for the jellyfish these animals belong to the protostomial branch of animal evolution, for which little information regarding DNA sequence organization has previously been available. The reassociation kinetics of short (250-300 nucleotide) and long (2,000-3,000 nucleotide) DNA fragments was studied by the hydroxyapatite method. It was shown that in each case a major fraction of the DNA consists of single copy sequences less than about 3,000 nucleotides in length, interspersed with short repetitive sequences. The lengths of the repetitive sequences were estimated by optical hyperchromicity and S1 nuclease measurements made on renaturation products. All the genomes studied include a prominent fraction of interspersed repetitive sequences about 300 nucleotides in length, as well as longer repetitive sequence regions.     

Absence of short period interspersion of repetitive and non-repetitive sequences in the DNA of Drosophila melanogaster

A sensitive search has been made in Drosophila melanogaster DNA for short repetitive sequences interspersed with single copy sequences. Five kinds of measurements all yield the conclusion that there are few short repetitive sequences in this genome: 1) Comparison of the kinetics of reassociation of short (360 nucleotide) and long (1,830 nucleotide) fragments of DNA; 2) reassociation kinetics of long fragments (2,200 nucleotide) with an excess of short (390 short nucleotide) fragments; 3) measurement of the size of S1 nuclease resistant reassociated repeated sequences; 4) measurement of the hyperchromicity of reassociated repetitive fragments as a function of length; 5) direct assay by kinetics of reassociation of the amount of single copy sequence present on 1,200 nucleotide long fragments which also contain repetitive sequences.     

Genome analysis of ground squirrels of the genus Citellus (Rodentia,Sciuridae) II. DNA sequence organization

The organization of the DNA sequences in five specics of Citellus (C. pygmaeus, C. fulvus, C. major, C. parryi and C. undulatus) was determined from the reassociation kineties of DNA fragments of various lengths and the size distribution of SI-nuclease-resistant duplexes of repetitive DNA. Only 15% of the genome of all the species studied consists of short unique and repeated sequences interspersed with a period less than 2 3 kb, whereas the major part of the genome is occupied by much more extensive sequences of two types, moderately long (3–15 kb) and very long (much more than 15 kb). On the basis of the number of moderately long single-copy sequences the species under study are divided into two groups, coinciding with their division into short-tailed and long-tailed ground squirrels: the short-tailed (C. pygmaeus, C. major and C. fulvus) possess far more such sequences (17–24%) than do the long-tailed ones (C. parryi and C. undulatus) (1–7%). The same division is observed in the amount of very long single-copy sequences. The repeated DNA sequences of Citellus vary widely in size, i.e. from 70 up to some thousands of nucleotide pairs, sequences of more than 1200 nucleotide pairs being most common. In addition, part of the repetitions contain between 70 and 150 base pairs. About one-third of C. parryi repeats (10% of the genome) are characterized by such very short sequences whereas their amont is much less in the other Citellus species (1–4% of the genome).     

Assessments of DNA inhomogeneities in yeast chromosome III.

With the sequencing of the first complete eukaryotic chromosome, III of yeast (YCIII) of length 315 kb, several types of questions concerning chromosomal organization and the heterogeneity of eukaryotic DNA sequences can be approached. We have undertaken extensive analysis of YCIII with the goals of: (1) discerning patterns and anomalies in the occurrences of short oligonucleotides; (2) characterizing the nature and locations of significant direct and inverted repeats; (3) delimiting regions unusually rich in particular base types (e.g., G+C, purines); and (4) analyzing the distributions of markers of interest, e.g., delta (delta) elements, ARS (autonomous replicating sequences), special oligonucleotides, close repeats and close dyad pairings, and gene sequences. YCIII reveals several distinctive sequence features, including: (i) a relative abundance of significant local and global repeats highlighting five genes containing substantial close or tandem DNA repeats; (ii) an anomalous distribution of delta elements involving two clusters and a long gap; (iii) a significantly even distribution of ARS; (iv) a relative increase in the frequency of T runs and AT iterations downstream of genes and A runs upstream of genes; and (v) two regions of complex repetitive sequences and anomalous DNA composition, 29000-31000 and 291000-295000, the latter centered at the HMRa locus. Interpretations of these findings for chromosomal organization and implications for regulation of gene expression are discussed.     

Integration site preferences of the Alu family and similar repetitive DNA sequences.

Numerous flanking nucleotide sequences from two primate interspersed repetitive DNA families have been aligned to determine the integration site preferences of each repetitive family. This analysis indicates that both the human Alu and galago Monomer families were preferentially inserted into short d(A+T)-rich regions. Moreover, both primate repeat families demonstrated an orientation specific integration with respect to dA-rich sequences within the flanking direct repeats. These observations suggest that a common mechanism exists for the insertion of many repetitive DNA families into new genomic sites. A modified mechanism for site-specific integration of primate repetitive DNA sequences is provided which requires insertion into dA-rich sequences in the genome. This model is consistent with the observed relationship between galago Type II subfamilies suggesting that they have arisen not by mere mutation but by independent integration events.     

Composite transposable elements in the Xenopus laevis genome.

Members of two related families of transposable elements, Tx1 and Tx2, were isolated from the genome of Xenopus laevis and characterized. In both families, two versions of the elements were found. The smaller version in each family (Tx1d and Tx2d) consisted largely of two types of 400-base-pair tandem internal repeats. These elements had discrete ends and short inverted terminal repeats characteristic of mobile DNAs that are presumed to move via DNA intermediates, e.g., Drosophila P and maize Ac elements. The longer versions (Tx1c and Tx2c) differed from Tx1d and Tx2d by the presence of a 6.9-kilobase-pair internal segment that included two long open reading frames (ORFs). ORF1 had one cysteine-plus-histidine-rich sequence of the type found in retroviral gag proteins. ORF2 showed more substantial homology to retroviral pol genes and particularly to the analogs of pol found in a subclass of mobile DNAs that are supposed retrotransposons, such as mammalian long interspersed repetitive sequences, Drosophila I factors, silkworm R1 elements, and trypanosome Ingi elements. Thus, the Tx1 elements present a paradox by exhibiting features of two classes of mobile DNAs that are thought to have very different modes of transposition. Two possible resolutions are considered: (i) the composite versions are actually made up of two independent elements, one of the retrotransposon class, which has a high degree of specificity for insertion into a target within the other, P-like element; and (ii) the composite elements are intact, autonomous mobile DNAs, in which the pol-like gene product collaborates with the terminal inverted repeats to cause transposition of the entire unit.     

Contrasting patterns of DNA sequence arrangement in Apis mellifera (Honeybee) and Musca domestica (housefly)

We have examined the organization of the repeated and single copy DNA sequences in the genomes of two insects, the honeybee (Apis mellifera) and the housefly (Musca domestica). Analysis of the reassociation kinetics of honeybee DNA fragments 330 and 2,200 nucleotides long shows that approximately 90% of both size fragments is composed entirely of non-repeated sequences. Thus honeybee DNA contains few or no repeated sequences interspersed with nonrepeated sequences at a distance of less than a few thousand nucleotides. On the other hand, the reassociation kinetics of housefly DNA fragments 250 and 2,000 nucleotides long indicates that less than 15% of the longer fragments are composed entirely of single copy sequences. A large fraction of the housefly DNA therefore contains repeated sequences spaced less than a few thousand nucleotides apart. Reassociated repetitive DNA from the housefly was treated with S1 nuclease and sized on agarose A-50. The S1 resistant sequences have a bimodal distribution of lengths. Thirty-three percent is greater than 1,500 nucleotide pairs, and 67% has an average size about 300 nucleotide pairs. The genome of the housefly appears to have at least 70% of its DNA arranged as short repeats interspersed with single copy sequences in a pattern qualitatively similar to that of most eukaryotic genomes.     

CetSINEs and AREs are not SINEs but are parts of cetartiodactyl L1

Short interspersed repetitive elements (SINEs) are widely distributed among the genomes of eukaryotes. We proposed previously that a SINE should be defined by the presence of a region homologous to a tRNA or to 7SL RNA, together with A-box and B-box promoter sequences, in order to distinguish SINEs from other short repetitive sequences, such as short segments of LINEs (long interspersed repetitive elements; Okada et al. Gene 205, 229–243, 1997). Numerous SINE sequences have been deposited to date in DNA databases. In some cases, however, designation of a particular sequence is problematic when the short repetitive sequence has been defined as a SINE without reference to the presence or absence of promoter elements specific for RNA polymerase III. We demonstrate here that four different sequences, namely, ARE1p, ARE2p, CetSINE1, and CetSINE2, each of which has been reported as a SINE, are, in fact, only partial sequences of members of a new subfamily of L1. We also demonstrate that members of this subfamily are distributed specifically among the genomes of cetartiodactyls. Received: 3 May 2000 / Accepted: 22 August 2000     

An alternative view of mammalian DNA sequence organization: II. Short repetitive sequences are organized into scrambled tandem clusters in Syrian hamster DNA

Hyperchromicity, S₁ nuclease digestion, and reassociation studies of Syrian hamster repetitive DNA have led to novel conclusions about repetitive sequence organization. Re-evaluation of the hyperchromicity techniques commonly used to determine the average length of genomic repetitive DNA regions indicates that both the extent of reassociation, and the possibility of non-random elution of hyperpolymers from hydroxyapatite can radically affect the observed hyperchromicity. An alternative interpretation of hyperchromicity experiments, presented here, suggests that the average length of repetitive regions in Syrian hamster DNA must be greater than 4000 nucleotides.S₁ nuclease digestion of reassociated 3200 nucleotide Syrian hamster repetitive DNA, on the other hand, yields both long (>2000 nucleotides) and short (300 nucleotides) resistant DNA duplexes. Calculations indicate that the observed mass of short nuclease-resistant duplexes (>60%) is too large to have arisen only from independent short repetitive DNA sequences alternating with non-repetitive regions. Reassociation experiments using long and short S₁ nuclease-resistant duplexes as driver DNA indicate that all repetitive sequences are present in both fractions at approximately the same concentration. Isolated long S₁ nuclease-resistant duplexes, after denaturation, renaturation, and a second S₁ nuclease digestion, again produce both long and short DNA duplexes. Reassociation experiments indicate that all repetitive DNA sequences are still present in the “recycled” long S₁ nuclease-resistant duplexes. These experiments imply that many of the short S₁ nuclease-resistant repetitive DNA duplex regions present in reassociated Syrian hamster DNA were initially present in the genome as part of longer repetitive sequence blocks. This conclusion suggests that the majority of “short” repetitive regions in Syrian hamster DNA are organized into scrambled tandem clusters rather than being individually interspersed with non-repetitive regions.