How bats achieve a small C-value: frequency of repetitive DNA in Macrotus

Bats possess a genome approximately 50–87% the size of other eutherian mammals. We document that the events that have achieved or maintained a small genome size in the Mexican leaf-nosed bat Macrotus waterhousii have resulted in a lower copy number of interspersed and tandemly repetitive elements. These conclusions are based on examination of 1726 randomly chosen recombinant cosmids, with an average insert size of 35.7 kb and representing 2.6% of the haploid genome of M. waterhousii. Probes representative of microsatellites [(GT)_n, (CT)_n, (AT)_n, (GC)_n] and a tandem repeat (rDNA) were used to estimate frequency of repetitive elements in the M. waterhousii genome. Of the four dinucleotides, (GT)_n was present in 33.5% of the clones, (CT)_n was present in 31.0% of the clones, and (AT)_n and (GC)_n were not represented in any of the clones examined. The 28S rDNA and a repetitive element from M. californicus were found in three and four clones, respectively. The dinucleotides (GT)_n and (CT)_n occurred together in the same clone more frequently than expected from chance. Although our data do not allow us to empirically test which mechanisms are maintaining copy number of repetitive DNA in the bat genome, the nonrandom association of these different families of repetitive DNA may provide insight into a mechanism that proportionately reduces diverse families of repetitive DNA that are known to be amplified by very different mechanisms.     

Characterization of repetitive DNA in rye (Secale cereale)

Nuclear DNA of rye (Secale cereale), a plant species with a relatively large genome (i.e., 18 pg diploid), has been characterized by determination of its content in repetitive sequences, buoyant density, and thermal denaturation properties. The reassociation kinetics of rye DNA reveals the presence of 70 to 75% repeated nucleotide sequences which are grouped into highly (Cot 1) and intermediately repetitive (Cot 1–100) fractions. On sedimentation in neutral CsCl gradients, native, high molecular weight DNA forms an almost symmetrical band of density 1.702 g/cm³. The highly repetitive DNA (Cot 1), on the other hand, is separated into two distinct peaks; the minor component has a density of 1.703 g/cm³ corresponding to that of a very rapidly reassociating fraction (Cot 0.01) which comprises 10 to 12% of the rye genome. The latter DNA contains segments which are repeated 6×10⁵ to 6×10⁶ times. The major peak of the Cot 1 fraction shows a density of 1.707 g/cm³ and consists of fragments repeated about 3.7×10⁴ times. The intermediately repetitive DNA is much more heterogeneous than the Cot 1 fraction and has a low degree of repetition of the order of 8.5×10². The melting behavior of the Cot 1 fraction reveals the presence of a high degree of base pairing (i.e., 7% mismatching). When native rye DNA is resolved into fractions differing in GC content by hydroxyapatite thermal column chromatography and these fractions are analyzed for the presence of repetitive sequences, it is observed that the highly redundant DNA (Cot 1) is mostly located in the fraction denaturing between 80° and 90°C. This result suggests that highly repetitive rye DNA occurs in a portion of the genome which is neither very rich in AT nor in GC.     

Genome complexity of the maize rust fungus,Puccinia sorghi

The base composition and complexity of genomic DNA fromPuccinia sorghi have been estimated by thermal denaturation, analytical ultracentrifugation, and reassociation kinetics. The buoyant density of genomic DNA in CsCl was found to be 1.7021 g/ml, which corresponds to a GC content of 43%. From thermal denaturation curves the GC content was estimated to be 41%. The haploid genome size ofP. sorghi was estimated to be 4.7 × 10⁷ bp, half of which represented a moderately repetitive fraction. The size of theP. sorghi genome is similar to that of other basidiomycete fungi; however, the amount of repetitive DNA is greater than that reported for most other fungi.     

Evolution of genome size and DNA base composition in reptiles

The evolution of genome size and base composition of DNA from various reptiles has been studied. DNA amount was measured cytophotometrically and GC concentration estimated by thermal denaturation. The Reptilia appear to be a fairly homogeneous group with respect to DNA quantity, although chelonians stand out because of their higher inter- and intrafamilial variability and DNA content. Quantitative DNA variations do not show a single evolutionary trend, but rather seem to have followed different patterns within each group.The differences in genome size between related species seem to be mainly the result of duplication or loss of DNA sequences characterized by a similar mean denaturation temperature. This agrees with observations of other authors that quantitative variations in reptiles are mainly due to differences in the amount of repetitive DNA.Several hypotheses on the significance of quantitative DNA variations in reptiles are discussed.     

The repeated DNA sequences of Microtinae : I. Microtus agrestis, Microtus pennsylvanicus and Ellobius lutescens

A comparison has been made of the repeated nucleotide sequences from 3 Microtinae which possess varying amounts of constitutive heterochromatin per cell nucleus. Eight repetitive fractions of DNA, ranging in C_ot values from 10⁻³ to 10⁻³, were obtained by reassociation of sheared, denatured DNA and fractionation on hydroxyapatite. At C_ot values of less than 1, 3 fractions were isolated that amounted to 18.7, 10.0 and 7.4 % of the total DNA of Microtus agrestis, Microtus pennsylvanicus and Ellobius lutescens, respectively, in agreement with the amounts of heterochromatin in these species. At C_ot values higher than 1, the amounts of repeated sequences were more comparable and constituted about 12 to 14 % of the DNA. Thermal denaturation profiles of all the repetitive fractions showed a good deal of order in the reassociated duplexes, with an average hyperchromicity of 20 %. Upon density gradient centrifugation in neutral CsCl, the fractions from M. pennsylvanicus and E. lutescens yielded almost identical patterns and differed significantly from those of M. agrestis. In M. agrestis a fraction of fast-intermediate repetitiveness (reassociating at C_ot values between 10⁻² and 1) was isolated, amounting to about 12 % of the total DNA. This fraction has a base composition comparable to that of total DNA and represents the major component of the constitutive heterochromatin of giant sex chromosomes that have been isolated by the disruption of brain and liver nuclei and differential centrifugation.     

Redundant DNA of Neurospora crassa

Approximately 20% of the DNA of Neurospora crassa consists of redundant sequences. This is calculated from the reassociation rate of fragmented, denatured DNA as measured by hydroxyapatite column chromatography. The redundant DNA has a complexity of 10⁵ base pairs and a repetition frequency of up to 60 copies per genome. Its buoyant density in CsCl is 1.720 g/ml and its hypochromicity 20–24%. Base composition determination shows 54% GC content like Neurospora nuclear DNA. DNA-RNA hybridization studies indicate that rRNA and tRNA cistrons make up 2.3 and 1.2%, respectively, of the redundant fraction. Pulse-labeled RNA is shown to hybridize with both redundant and unique DNA fractions, suggesting that both fractions are transcribed.This work is supported by a grant from National Science Foundation (GB 8058) and National Institute of Health Research Career Development Award (K3GM31-238).     

Contrasting DNA sequence organisation patterns in sauropsidian genomes

The genomic DNA organisation patterns of four sauropsidian species, namely Python reticularis, Caiman crocodilus, Terrapene carolina triungius and Columba livia domestica were investigated by reassociation of short and long DNA fragments, by hyperchromicity measurements of reannealed fragments and by length estimations of S₁-nuclease resistant repetitive duplexes. While the genomic DNA of the three reptilian species shows a short period interspersion pattern, the genome of the avian species is organised in a long period interspersion pattern apparently typical for birds. These findings are discussed in view of the close phylogenetic relationships of birds and reptiles, and also with regard to a possible relationship between the extent of sequence interspersion and genome size.     

Genome composition and tandemly repetitive sequence at some centromeres in the lizard Podarcis s. sicula Raf.

A detailed study on the genome of the lizard P. sicula has been carried out using restriction enzyme analysis followed by identification and cloning of a repetitive DNA fraction. The results show that P. sicula generally possesses a quite homogeneous genome composition, with a single tandemly repetitive sequence family that is easily visualized after digestion of genomic DNA with Taq I. The cloned repeating unit of this satellite (260 bp) has been designed pLCSl. In-situ hybridisation shows that this satellite is localized in the centromeric region. Dot blot experiments show that sequences similar to pLCSl are present in other species of the same family of lizards.     

The DNA of CAENORHABDITIS ELEGANS

Chemical analysis and a study of renaturation kinetics show that the nematode, Caenorhabditis elegans, has a haploid DNA content of 8 x 10(7) base pairs (20 times the genome of E. coli). Eighty-three percent of the DNA sequences are unique. The mean base composition is 36% GC; a small component, containing the rRNA cistrons, has a base composition of 51% GC. The haploid genome contains about 300 genes for 4S RNA, 110 for 5S RNA, and 55 for (18 + 28)S RNA.     

Characterization of nuclear DNA in 12 species of Chlorella (Chlorococcales, Chlorophyta) by DNA reassociation

Strains of 12 different species of the genus Chlorella were analyzed for amount, reiteration frequency and kinetic complexity of chromosomal DNA components by C0t analysis. The resulting C0t curves reveal at least two different DNA components consisting of single copy DNA (up to 95%) and of repetitive DNA with complexities of 4.1 x 10(3) base pairs (bp) to approximately 11.7 x 10(3) bp and a reiteration frequency of 100-760. The total amount of repetitive DNA is less than 9% of the nuclear genome and similar in all strains studied. In contrast, the total kinetic complexity varies in a wide range from 1.26 x 10(7) bp to 8.08 x 10(7) bp which is mainly due to differences in the size of single copy DNA. The genome sizes in Chlorella seem not to be correlated with biochemical and physiological characteristics and therefore are unlikely to be useful as a taxonomical marker. A comparison of thermal denaturation profiles showed that the melting points of repetitive and single copy DNA differ by approximately 7 degrees C which may result from base mismatch and/or from a distinct base composition of the repetitive DNA.     

Changes in DNA composition during cell differentiation in a green alga

In the coenobia-forming green alga, Hydrodictyon reticulatum, changes in DNA composition during growth and differentiation of reproductive cells were followed. A “loss” of DNA per nucleus could be attributed to underreplication of an amplified DNA fraction being part of a (GC)-rich satellite band in CsCl gradients of DNA from young coenobia. This (GC)-rich satellite DNA contains up to 3 % unique DNA sequences intermingled with repetitive DNA. It does not (or nearly not) contain ribosomal DNA. A possible role of this DNA fraction in differentiation is suggested.     

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.     

Changes in DNA composition in the evolution of Vicia species

Summary The composition of nuclear DNA in 3 Vicia species are compared. The species V. eriocarpa, V. johannis and V. melanops are from three separate subgeneric sections of Vicia and show a fourfold variation in their amounts of nuclear DNA. DNA melting experiments, buoyant density gradient analysis and Cot reassociation experiments show that the quantitiative change in nuclear DNA between the three species is achieved by changes in the amounts of both repetitive and nonrepetitive DNA sequences. It is suggested that while the increase in the repetitive fraction is achieved by the proliferation of repetitive base sequences the increase in the nonrepetitive fraction is due to the steady accretion of highly diverged base sequences resulting from mutations, deletions, insertions and base sequence rearrangements among families of repetitive 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.     

Effect of ethylene glycol, urea, and N-methylated glycines on DNA thermal stability: the role of DNA base pair composition and hydration

The accumulation of the cosolutes ethylene glycol, urea, glycine, sarcosine, and glycine betaine at the single-stranded DNA surface exposed upon melting the double helix has been quantified for DNA samples of different guanine-cytosine (GC) content using the local-bulk partitioning model [Record, M. T., Jr., Zhang, W., and Anderson, C. F. (1998) Adv. Protein Chem. 51, 281-353]. Urea and ethylene glycol are both locally accumulated at single-stranded DNA relative to bulk solution. Urea exhibits a stronger affinity for adenine (A) and thymine (T) bases, leading to a greater net dehydration of these bases upon DNA melting; ethylene glycol local accumulation is practically independent of base composition. However, glycine, sarcosine, and glycine betaine are not necessarily locally accumulated at single strands after melting relative to bulk solution, although they are locally accumulated relative to double-stranded DNA. The local accumulation of glycine, sarcosine, and glycine betaine at single strands relative to double-stranded DNA decreases with bulk cosolute molality and increases with GC content for all N-methylated glycines, demonstrating a stronger affinity for G and C bases. Glycine also shows a minimum in melting temperature T(m) at 1-2 m for DNA samples of 50% GC content or less. Increasing ionic strength attenuates the local accumulation of urea, glycine, sarcosine, and glycine betaine and removes the minimum in T(m) with glycine. This attenuation in local accumulation results in counterion release during the melting transition that is dependent on water activity and, hence, cosolute molality.     

Nuclear DNA changes within Helianthus annuus L.: variations in the amount and methylation of repetitive DNA within homozygous progenies

Complex alterations in the redundancy and methylation of repeated DNA sequences were shown to differentiate the nuclear genome of individuals belonging to single progenies of homozygous plants of the sunflower. DNA was extracted from seedlings obtained from seeds collected at the periphery of flowering heads (P DNA) or from seedlings obtained from seeds collected in their middle (M DNA). Three fractions of repeated sequences were isolated from genomic DNA: a highly repetitive fraction (HR), which reassociates within an equivalent Cot of about 2 × 10^-1, and two medium repetitive fractions (MR1 and MR2) having Cot ranges of about 2 × 10^-1-2 and 2-10², respectively. Denaturation kinetics allowed different sequence families to be recognized within each fraction of repetitive DNA, and showed significant differences in sequence redundancy to occur between P and M DNA, particularly as far as the MR2 fraction is concerned. Most DNA sequence families are more represented in P DNA than in M DNA. However, the redundancy of certain sequences is greater in the latter than in the former. Each repetitive DNA fraction was hybridized to Southern blots of genomic P or M DNA which was digested to completion by three pairs of isoschizomeric restriction endonucleases which are either insensitive or sensitive to the methylation of a cytosine in the recognition site. The results obtained showed that the repetitive DNA of H. annuus is highly methylated. Clear-cut differences in the degree of methylation of P and M DNA were found, and these differences were particularly apparent in the MR2 fraction. It is suggested that alterations in the redundancy of given DNA sequences and changes in their methylation patterns are complementary ways to produce continuous genotypic variability within the species which can be exploited in environmental adaptation.Research supported by National Research Council of Italy, Special Project RAISA, Sub-project No. 2     

Base Composition Skews, Replication Orientation, and Gene Orientation in 12 Prokaryote Genomes

Variation in GC content, GC skew and AT skew along genomic regions was examined at third codon positions in completely sequenced prokaryotes. Eight out of nine eubacteria studied show GC and AT skews that change sign at the origin of replication. The leading strand in DNA replication is G-T rich at codon position 3 in six eubacteria, but C-T rich in two Mycoplasma species. In M. genitalium the AT and GC skews are symmetrical around the origin and terminus of replication, whereas its GC content variation has been shown to have a centre of symmetry elsewhere in the genome. Borrelia burgdorferi and Treponema pallidum show extraordinary extents of base composition skew correlated with direction of DNA replication. Base composition skews measured at third codon positions probably reflect mutational biases, whereas those measured over all bases in a sequence (or at codon positions 1 and 2) can be strongly affected by protein considerations due to the tendency in some bacteria for genes to be transcribed in the same direction that they are replicated. Consequently in some species the direction of skew for total genomic DNA is opposite to that for codon position 3. Received: 2 February 1998 / Accepted: 15 June 1998     

Construction of a small Mus musculus repetitive DNA library: identification of a new satellite sequence in Mus musculus.

We report the construction of a small library of recombinant plasmids containing Mus musculus repetitive DNA inserts. The repetitive cloned fraction was derived from denatured genomic DNA by reassociation to a Cot value at which repetitive, but not unique, sequences have reannealed followed by exhaustive S1 nuclease treatment to degrade single stranded DNA. Initial characterizations of this library by colony filter hybridizations have led to the identification of a previously undetected M. musculus minor satellite as well as to clones containing M. musculus major satellite sequences. This new satellite is repeated 10-20 times less than the major satellite in the M. musculus genome. It has a repeat length of 130 nucleotides compared with the M. musculus major satellite with a repeat length of 234 nucleotides. Sequence analysis of the minor satellite has shown that it has a 29 base pair region with extensive homology to one of the major satellite repeating subunits. We also show by in situ hybridization that this minor satellite sequence is located at the centromeres and possibly the arms of at least half the M musculus chromosomes. Sequences related to the minor satellite have been found in the DNA of a related Mus species, Mus spretus, and may represent the major satellite of that species.     

DNA sequence organization in the genome of Petroselinum sativum (Umbelliferae)

The genome of parsley was studied by DNA/DNA reassociation to reveal its spectrum of DNA reiteration frequencies and sequence organization. The reassociation of 300 nucleotide DNA fragments indicates the presence of four classes of DNA differing in repetition frequency. These classes are: highly repetitive sequences, fast intermediate repetitive sequences, slow intermediate repetitive sequences, and unique sequences. The repeated classes are reiterated on average 136,000, 3000, and 42 times respectively. A minor part of the genome is made up of palindromes. — The organization of DNA sequences in the P. sativum genome was determined by the reassociation kinetics of DNA fragments of varying length. Further information was derived from S1 nuclease resistance and from hyperchromicity measurements on DNA fragments reassociated to defined C₀t values. — The portion of the genome organized in a short period interspersion pattern amounts to 47%, with the unique sequences on an average 1000 nucleotides long, and most of the repetitive sequences about 300 nucleotides in length, whereas the weight average length may be up to 600 nucleotides. — About 5% unique DNA and 11% slow intermediate repetitive DNA consist of sequences from 10³ up to 10⁴ nucleotides long; these are interspersed with repetitive sequences of unknown length. Long repetitive sequences constitute 33% of the genome, 13% are satellite-like organized, and 20% in long stretches of intermediate repetitive DNA in which highly divergent sequences alternate with sequences that show only minimal divergence. — The results presented indicate remarkable similarities with the genomes of most animal species on which information is available. The most intriguing pecularity of the plant genome derives from its high content of repetitive DNA and the presumed organization of the latter.     

Classification of the genus Humicola Traaen: II. The DNA base composition of some strains within the genus

The base composition of DNA (GC content) of 25 strains, morphologically referred to the genusHumicola Traaen, is studied. The range of GC% variation is about 23 % (from 28,5 % to 51,6). Two prominent groups of strains with similar GC content may be distinguished: one ranging from 28 % to 37 % and the other ranging from 40 % to 49 %. The aleuriospore size is not related to the DNA base composition, but a group of strains with prevalently coloured hyphae, with aleuriospores of similar size and with high GC content is recognized. Several previous literature reports on the taxonomy ofHumicola are discussed.