Evolutionary divergence and length of repetitive sequences in sea urchin DNA

Summary The organization of repetitive and single copy DNA sequences in sea urchin DNA has been examined with the single strand specific nuclease Sl fromAspergillus. Conditions and levels of enzyme were established so that single strand DNA was effectively digested while reassociated divergent repetitive duplexes remained enzyme resistant. About 25% of sea urchin DNA reassociates with repetitive kinetics to form Sl resistant duplexes of two distinct size classes derived from long and short repetitive sequences in the sea urchin genome. Fragments 2,000 nucleotides long were reassociated to Cot 20 and subjected to controlled digestion with Sl nuclease. About half of the resistant duplexes (13% of the DNA) are short, with a mode size of about 300 nucleotide pairs. This class exhibits significant sequence divergence, and principally consists of repetitive sequences which were interspersed with single copy sequences. About one-third of the long duplexes (4% of the DNA) are reduced in size after extensive Sl nuclease digestion to about 300 nucleotide pairs. About two-thirds of the long resistant duplexes (8% of the DNA) remains long after extensive SI nuclease digestion. These long reassociated duplexes are precisely base paired. The short duplexes are imprecisely paired with a melting temperature about 9°C below that of precisely paired duplexes of the same length. The relationship between length of repetitive duplex and precision of repetition is confirmed by an independent method and has been observed in the DNA of a number of species over a wide phylogenetic area.Also Staff Member, Carnegie Institution of Washington     

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.     

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.     

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 organization in the mollusc Aplysia californica.

The sequence organization of the DNA of the mollusc Aplysia californica has been examined by a combination of techniques. Close-spaced interspersion of repetitive and single copy sequences occurs throughout the majority of the genome. Detailed examination of the DNA of this protostome reveals great similarities to the pattern observed in the two deuterostome organisms previously examined in detail in this laboratory, Xenopus laevis and Strongylocentrotus purpuratus. Labeled and unlabeled Aplysia DNA were prepared from developing embryos and sheared to a fragment length of 400 nucleotides. The kinetics of reassociation were studied by means of hydroxyapatite chromatography, single-strand-specific S1 nuclease, and optical methods of assay. Aplysia DNA of this fragment length contains at least five resolvable kinetic fractions. One classification of these fractions, listed with their reassociation rate constants (l M-1 sec-1) is: single copy (0.00057), slow (0.047), fast (2.58), very fast (4000), and foldback (greater than 10(5)). Sequence arrangement was deduced from: the kinetics of reassociation of DNA fragments of length 400 or 2000 nucleotides; the hyperchromicity of reassociated fragments containing duplex regions; the size of duplex regions resistant to S1 nuclease; and the reassociation of labeled fragments of various lengths with short driver fragments. More than 80% of the single copy DNA sequences are interspersed with repetitive sequences. The maximum spacing of the repeats is about 2000 nucleotides, and the average less than 1000. The very fast fraction does not show interspersion with single copy sequences or with other kinetic fractions. The foldback fraction sequences are fairly widely interspersed. The slow fraction sequences are interspersed with the fast fraction, and possibly also with the single copy DNA. The fast fraction is the dominant interspersed repetitive fraction. Its sequences are adjacent to the great majority of the single copy sequences and have an average length of about 300 nucleotides.     

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.     

The organization of the main component DNA of a crustacean genome with a paucity of middle repetitive sequences

The frequency classes and organization of the main component (mc) DNA of a crustacean, the land crab, Gecarcinus lateralis, have been characterized. The reassociation kinetics of 380 nucleotide long mcDNA fragments show that approximately 50% contain sequences repeated more than 800 times. Present in few, if any, copies are sequences repeated from 2 to 800 times. The remainder of the DNA reassociates as single copy sequences with a rate constant consistent with the organism's genome size. The reassociation kinetics of highly sheared DNA fragments of every true crab studied (Vaughn, 1975; Christie et al., 1976) are similar to each other and different from those of other invertebrate DNAs (Goldberg et al., 1975). Each of these genomes has a paucity of sequences repeated from 10 to 800 times and an abundance of highly repeated sequences. To determine if sequences repeated more than 800 times are interspersed with single copy sequences, we examined the arrangement of repetitive and non-repetitive sequences in mcDNA. The reassociation and melting properties of partially duplex mcDNA fragments of increasing lengths show that at least 75% of the DNA is organized in an interspersed pattern. In this pattern, single copy sequences with an average length of 800–900 nucleotides are interspersed with repetitive sequences. S1 nuclease digestion of reassociated 3100 nucleotide fragments indicates that 44% of the mcDNA is repetitive and that one-third of the repetitive sequences (average length=285 nucleotides) are interspersed with single copy sequences. We conclude that repetitive sequencies are interspersed with most of the single copy sequences in an interspersion pattern similar to that of Xenopus rahter than to that of another arthropod, Drosophila.Operated by Union Carbide Corporation for the Energy Research and Development Administration     

DNA sequence organization in the genome of Cycas revoluta

The pattern of DNA sequence organization in the genome of Cycas revoluta was analyzed by DNA/DNA reassociation. Reassociation of 400 base pair (bp) fragments to various C₀t values indicates the presence of at least four kinetic classes: the foldback plus very highly repetitive sequences (15%), the fast repeats (24%), the slow repeats (44%), and the single copy (17%). The latter component reassociates with a rate constant 1×10^–4 M^–1S^–1 corresponding to a complexity of 1.6× 10⁶ kb per haploid genome. A haploid C. revoluta nucleus contains approximately 10.3 pg DNA. The single-copy sequences account for about 28% of the DNA, but only 17% reassociate with single-copy kinetics because of interspersion with repetitive sequences. — The interspersion of repetitive and single-copy sequences was examined by reassociation of DNA fragments of varying length to C₀t values of 70 and 500. A major (65%) and homogeneous class of single-copy sequences averaging 1,100 bp in length is interspersed in a short period pattern with repeated sequences. A minor (35%) heterogeneous single-copy component is interspersed in a long-period pattern. The majority of repetitive sequences have a length distribution of 100–350 bp with subclasses averaging 150 and 300 bp in length. Repeat sequences with a wide range in sizes exceeding 2 kilobase pair (kb) are also present in this genome. — The size and distribution of inverted repeat (ir) sequences in the DNA of C. revoluta were studied by electron microscopy. It is estimated that there are approximately 4 × 10⁶ ir pairs (one per 2.33 kb) that form almost equal numbers of looped and unlooped palindromes. This high value is 2.5 times that found in wheat DNA. These palindromes are in general randomly distributed in the genome with an average interpalindrome distance of 1.6 kb. The majority (about 85%) of ir sequences of both types of palindromes belong to a main-size class, with an average length of 210 bp in the unlooped and and 163 bp in the looped type. These values are comparable to those reported for some other plant and animal genomes. Distribution of length of single stranded loops showed a main-size class (75%) with an average length of 220 bp.     

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.     

Analysis of rat repetitive DNA sequences.

Parameters of repetitive sequence organization have been measured in the rat genome. Experiments using melting, hydroxylapatite binding, and single strand specific nuclease digestion have been used to measure the number, length, and arrangement of repeated DNA sequences. Renaturation and melting or S1 nuclease digestion of 1.0 kbp DNA fragment show about 20% of rat DNA sequences are 3000-fold repeated. Renatured duplexes from 4.0 kbp DNA fragments display two repetitive size fractions after nuclease digestion. About 60% of the repeated sequences are 0.2-0.4 kbp long while the remainder are longer than 1.5 kbp. The arrangement of the repeated sequences has been measured by hydroxylapatite fractionation of DNA fragments of varying lengths bearing a repeated sequence. Repeated DNA sequences are interspersed among 2.5 kbp long nonrepeated sequences throughout more than 70% of the rat genome. There are approximately 350 different 3000-fold short repeated sequences in the rat interspersed among 600,000 nonrepeated DNA sequences.     

Unusual genome organization of the marine invertebrate Rapana thomasiana Grosse (Gastropoda)

The genome organization of the marine snail Rapana thomasiana Grosse (Gastropoda), genome size 2.7 pg, was studied by reassociation kinetics, S₁-nuclease assay, and restriction enzyme analysis. The slow-reassociating (single-copy) fraction represented only 21% of the genome. The average length of 80% of the single-copy sequences was less than 700 bp and the remaining 20% no longer than 1,400 bp. Longer stretches of unique DNA were not observed. The genome contained an unusually high percent-age of inverted repeats: at standard fragment length the zero-time binding fraction amounted to 25% of the genome. Foldback structures ranging from 200 bp to more than 10 kb were observed after S₁-nuclease treatment. They were randomly distributed throughout at least 85% of the genome, and the spacings between them were estimated to be about 1,600 bp on the average. The middle-repetitive DNA (45% of the genome) contained two kinetic components, repeated 430 and 65,000 times per genome, respectively. It was found that the majority of the repetitive sequences are about 300 bp long. Longer repeats (about 2,000 bp) were also observed, comprising a small portion of the genome. The inverted repeats, the middle-repetitive, and the singly-copy sequences were fully interspersed in the genome, thus indicating that R. thomasiana DNA is not organized in either the Xenopus or the Drosophila pattern type. — R. thomasiana is the only mollusc so far in which a satellite DNA has been found. It is organized in tandem repeats of 1,460 bp with a very complex organization but a low degree of divergence.     

DNA sequence organization in Phycomyces blakesleeanus

Reassociation analysis shows that the genome of the Zygomycete Phycomyces blakesleeanus consists of repetitive and single copy sequences arranged in a long period interspersion pattern. The average lengths of the interspersed repetitive (16 kb) and single copy (25 kb) sequences appear to be very large. The sequence organization resembles that reported for the Oomycete Achlya (Hudspeth et al., 1977).     

Sequence organization in Xenopus DNA studied by the electron microscope.

Xenopus laevis DNA was extracted from red blood cells and sheared to a mean length of 2780 nucleotides. The DNA was stripped of foldback-containing fragments and incubated to C₀t 10 (mol · s · l⁻¹), allowing most repetitive sequences to form duplex structures. Duplex-containing fragments were eluted from an hydroxylapatite column and visualized for electron microscopy by spreading from 57% formamide according to the modified Kleinschmidt technique of Davis et al. (1971). The mean length of the fragments observed was 2445 nucleotides. A total of 1700 DNA strands were photographed and studied. Less than 5% of the total strand length was in uninterpretable structures. Every molecule falling within the confines of the plates was included in the sample. Over 50% of the total strand length in the sample was found in structures bearing at least one interspersed repetitive sequence duplex terminated by four single-strand regions. The fraction of DNA present in duplex regions was almost exactly that predicted if the duplex regions represent all the interspersed middle repetitive sequence in the Xenopus genome. Direct measurement of visualized duplexes shows that the mean length of interspersed repetitive sequence elements in this genome is 345 nucleotides. Duplex length was shown to be independent of the length of the strands bearing the duplexes. These observations provide direct confirmation of the length of approximately 300 nucleotides indicated for interspersed repetitive sequences by earlier physical-chemical studies 011 Xenopus DNA. In strands carrying two duplexes terminated by single-strand regions the interduplex, or single-copy sequence element length could be measured. Sequence interspersion curves generated from these data are roughly consistent with those derived earlier from measurements of hydroxylapatite binding as a function of fragment length.     

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.     

DNA sequence organization and transcription of the chicken genome

A new approach has been used to examine DNA sequence organization in the chicken genome. The interspersion pattern was determined by studying the fraction of labelled DNA fragments of different lengths that hybridized to an excess of short chicken repeated DNA sequences. The results indicate that chicken DNA has a pattern of sequence organization quite different than the standard ‘Xenopus’ or ‘Drosophila’ patterns. Two classes of unique sequences are found. One, 34% of the genome, consists of unique sequences approx. 4 kb long interspersed with repeated sequences. The second, non-interspersed fraction, 38% of the genome, consists of unique sequences found in long tracts, a minimum of approx. 22 kb in length. In an attempt to determine whether a relationship exists between DNA sequence organization and the distribution of structural genes we have isolated chicken DNA sequences belonging to different interspersion classes and tested each for the presence of structural genes by hybridization to excess poly(A)⁺ mRNA. Sequences complementary to poly(A)⁺ mRNA can be found with approximately the same frequency in both the non-interspersed fraction of the genome and a repeat-contiguous fraction enriched for interspersed sequences.     

DNA sequence organization in the genome of Nicotiana tabacum

The genome of Nicotiana tabacum was investigated by DNA/DNA reassociation for its spectrum of DNA repetition components and pattern of DNA sequence organization. The reassociation of 300 nucleotide DNA fragments analyzed by hydroxyapatite chromatography reveals the presence of three major classes of DNA differing in reiteration frequency. Each class of DNA was isolated and characterized with respect to kinetic homogeneity and thermal properties on melting. These measurements demonstrate that the genome of N. tabacum has a 1C DNA content of 1.65 pg and that DNA sequences are represented an average of 12,400, 252, and 1 times each. — The organization of the DNA sequences in the N. tabacum genome was determined from the reassociation kinetics of long DNA fragments as well as S1 nuclease resistance and hyperchromicity measurements on DNA fragments after annealing to C₀t values at which only repetitive DNA sequences will reassociate. At least 55% of the total DNA sequences are organized in a short period interspersion pattern consisting of an alternation of single copy sequences, averaging 1400 nucleotides, with short repetitive elements approximately 300 nucleotides in length. Another 25% of the genome contains long repetitive DNA sequences having a minimal genomic length of 1500 nucleotides. These repetitive DNA sequences are much less divergent than the short interspersed DNA sequence elements. These results indicate that the pattern of DNA sequence organization in the tobacco genome bears remarkable similarity to that found in the genomes of most animal species investigated to date.     

Base sequence studies of 300 nucleotide renatured repeated human DNA clones

A band of 300 nucleotide long duplex DNA is released by treating renatured repeated human DNA with the single strand-specific endonuclease S₁. Since many of the interspersed repeated sequences in human DNA are 300 nucleotides long, this band should be enriched in such repeats. We have determined the nucleotide sequences of 15 clones constructed from these 300 nucleotide S₁-resistant repeats. Ten of these cloned sequences are members of the Alu family of interspersed repeats. These ten sequences share a recognizable consensus sequence from which individual clones have an average divergence of 12.8%. The 300 nucleotide Alu family consensus sequence has a dimeric structure and was evidently formed from a head to tail duplication of an ancestral monomeric sequence. Three of the remaining clones are variations on a simple pentanucleotide sequence previously reported for human satellite III DNA. Two of the 15 clones have distinct and complex sequences and may represent other families of interspersed repeated sequences.     

Characterization of the nuclear genome of pearl millet.

The nuclear genome of pearl millet has been characterized with respect to its size, buoyant density in CsCl equilibrium density gradients, melting temperature, reassociation kinetics and sequence organization. The genome size is 0.22 pg. The mol percent G + C of the DNA is calculated from the buoyant density and the melting temperature to be 44.9 and 49.7%, respectively. The reassociation kinetics of fragments of DNA 300 nucleotides long reveals three components: a rapidly renaturing fraction composed of highly repeated and/or foldback DNA, middle repetitive DNA and single copy DNA. The single copy DNA consists of 17% of the genome. 80% of the repetitive sequences are at least 5000 nucleotide pairs in length. Thermal denaturation profiles of the repetitive DNA sequences show high Tm values implying a high degree of sequence homogeneity. About half of the single copy DNA is short (750--1400 nucleotide paris) and interspersed with long repetitive DNA sequences. The remainder of the single copy sequences vary in size from 1400 to 8600 nucleotide pairs.