Repeated DNA sequences and species relatedness in the genusEquisetum

The kinetics with which DNA reassociates and the thermal stability of rapidly reassociating (repetitive) DNA sequences have been monitored for six species in the genusEquisetum. Using the kinetic complexity for each of two repeated DNA sequence components as the basis for comparison, species in the subgenusEquisetum (E. arvense, E. fluviatile andE. telmateia) form one group and species in the subgenusHippochaete (E. hyemale, E. laevigatum andE. scirpoides) form another group. Using the difference in thermal stability between native and reassociated repetitive DNA for comparison, the same grouping of species is obtained.     

Size and structure of the bird genome. II. Repetitive DNA and sequence organization

1. Highly repetitive, middle repetitive and single copy DNA were evaluated in 19 species of birds, belonging to nine orders, by means of a reassociation kinetics method. 2. A rather uniform pattern is present in all the species studied (single copy = 60-75%; middle repetitive = 13-20% and highly repetitive 10-20%). 3. Reassociation kinetics of fragments of different length confirms the presence of a long period interspersion pattern. 4. Among different orders, no significant differences are observed. 5. DNA sequence organization seems to be related to genome size, with an inverse correlation between DNA nuclear content and amount of interspersed repetitive sequences.     

Exploration of long and short repetitive sequence relationships in the sea urchin genome.

Long and short repetitive sequences of sea urchin DNA were prepared by reassociation of 2000 nucleotide long fragments to Cot 4 and digestion with the single strand specific nuclease S1. The S1 resistant duplexes were separated into long repetitive and short repetitive fractions on Agarose A50. The extent of shared sequences was studied by reassociating a labeled preparation of short repetitive DNA with an excess of unlabeled long repetitive DNA. Less than 10% of the long repetitive DNA preparation was able to reassociate with the short repetitive DNA. Thus the long and short repetitive elements appear to be principally independent sequence classes in sea urchin DNA. Precisely reassociating repetitive DNA was prepared by four successive steps of reassociation and thermal chromatography on hydroxyapatite. This fraction (3% of the genome) was reassociated by itself or with a great excess of total sea urchin DNA. The thermal stability of the products was identical in both cases (Tm=81 degrees C), indicating that precisely repeated sequences do not have many imprecise copies in sea urchin DNA.     

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.     

Molecular structure of plant genomes

The genome structure of several species of Graminea and Drosophila was investigated by DNA renaturation method. Kinetics of DNA reassociation was studied by direct optical scanning and the data obout Cot curve were analized by an improved computer programm "Finger". Differences between structure DNA animals and plants are shown. Plant genomes have no unique fraction which exists in animal genomes. Slowly reassociating fraction in plants comprises about 20% DNA as compared with more than 60% in animal DNA. An analysis of kinetic complexity indicates that the relative content of the slowly reassociating fraction in the genome both of animal and of plants is much higher than that of the highly repeated DNA fraction.     

Analysis of plant genomes. V. Comparative study of molecular properties of DNAs of seven Allium species

The genomes of seven plant species belonging to the genus Allium and exhibiting a threefold variation in their nuclear DNA content were analyzed by studying their reassociation kinetics, equilibrium centrifugation behavior in neutral CsCl gradients, and melting properties. The reassociation kinetics experiments revealed the presence of 44–65% repeated DNA sequences. A comparison between DNA contents and the proportion of repeated DNA sequences indicated that, in Allium, increase in the genome size is not exclusively due to variations in the proportions of repetitive DNA. The total DNA as well as the various repetitive DNA fractions in all the Allium species examined exhibited, in spite of a few differences, a gross similarity in their behavior in neutral CsCl gradients and in their melting properties.     

DNA reassociation kinetics in diploid and phylogenetically tetraploid cyprinidae.

Four diploid and three phylogenetically tetraploid Cyprinidae (Ostariophysi) have been characterized as for nuclear DNA content, modal chromosome number and DNA reassociation kinetics (hydroxyapatite chromatography). Among the diploid species nuclear DNA content (10(-12) g DNA/2C) was 1.62 for Tinca tinca, 1.87 for Scardinius erythrophthalmus, 2.53 for Leuciscus cephalus and 2.75 for Alburnus alburnus, while the phylogenetically tetraploid species Carassius auratus, Barbus barbus and Cyprinus carpio attained 3.40, 3.66 and 3.80 respectively. Modal chromosome number was 2n = 48-50 for diploid individuals and 2n = 100-104 for phylogenetically tetraploid ones. In all the species 5--8% of the genome is represented by highly repetitive and foldback DNA. In DNA reassociation kinetics of phylogenetically tetraploid Cyprinidae a distinct plateau separates an intermediate reassociating sequence fraction (about 22% of the genome; with average repetition frequencies between 1,000 and 1,400) from a slow reassociating one (unique DNA; about 72% of the genome). These two genome fractions are not clearly distinguishable from each other in Cot curves of the diploid Cyprinidae, where a similar plateau is not evident. Since simple ploidy changes are not expected to affect DNA reassociation kinetics we suggest a different evolution in the genome organization of the two ploidy groups. Some possible hypotheses are discussed.     

Characterization of a SINE species from vicuna and its distribution in animal species including the family Camelidae

Twenty-six sequences of a short interspersed repetitive element (SINE) with a size of approximately 150 base pairs (bp) were isolated from the genomic DNA of Vicugna vicugna (vicuna). RNA polymerase III split promoter sequence was observed in most of them, and many had direct repeats flanking to SINEs as well as a poly(A)-like structure. The SINE sequences were designated as ``vic-1' sequences. Comparison of the vic-1 consensus sequence with sequences registered in the DNA database (DDBJ/EMBL/GENBANK) revealed that the vic-1 sequence had a 79% homology with mouse ala-tRNA gene. In addition, the tRNA-related region of the consensus sequence was folded into a cloverleaf structure as with mouse ala-tRNA. These findings strongly indicated that vic-1 was a retroposon derived from ala-tRNA gene. The vic-1 sequences were used as a probe for dot-blot hybridization to examine the distribution of their homologous sequences in the genomes of various animal species spanning 14 orders, of which, homologous sequences were found only in the Camelidae family. In order to examine the phylogenetical relationship among vicuna, llama, and camel, vic-1 insertion analysis and homology analysis of vic-1 sequences were performed at each locus. The analyses indicated that vic-1 sequences were generated in a common ancestor of the animal species, and that camels first branched off from the clade Camelidae, followed by vicunas and llamas. Received: 5 July 2000 / Accepted: 14 November 2000     

Correlation between animal radiosensitivity and kinetics of DNA reassociation

A study was made of DNA of different animal species with various radiosensitivity: guinea pig, man, rat and rabbit. It was shown that the radioresistance of the organism increases with increasing relative content of a rapidly reassociating fraction in DNA. As the kinetic complexity of moderately repetitive sequences increases and the total percentage of meaddle and unique DNA fractions grows, the radioresistance of the organism decreases.     

Small, repetitive DNAs contribute significantly to the expanded mitochondrial genome of cucumber

Closely related cucurbit species possess eightfold differences in the sizes of their mitochondrial genomes. We cloned mitochondrial DNA (mtDNA) fragments showing strong hybridization signals to cucumber mtDNA and little or no signal to watermelon mtDNA. The cucumber mtDNA clones carried short (30-53 bp), repetitive DNA motifs that were often degenerate, overlapping, and showed no homology to any sequences currently in the databases. On the basis of dot-blot hybridizations, seven repetitive DNA motifs accounted for >13% (194 kb) of the cucumber mitochondrial genome, equaling >50% of the size of the Arabidopsis mitochondrial genome. Sequence analysis of 136 kb of cucumber mtDNA revealed only 11.2% with significant homology to previously characterized mitochondrial sequences, 2.4% to chloroplast DNA, and 15% to the seven repetitive DNA motifs. The remaining 71.4% of the sequence was unique to the cucumber mitochondrial genome. There was <4% sequence colinearity surrounding the watermelon and cucumber atp9 coding regions, and the much smaller watermelon mitochondrial genome possessed no significant amounts of cucumber repetitive DNAs. Our results demonstrate that the expanded cucumber mitochondrial genome is in part due to extensive duplication of short repetitive sequences, possibly by recombination and/or replication slippage.     

DNA reassociation kinetics in relation to genome size in four amphibian species

DNA reassociation kinetics were studied, by means of the hydroxyapatite chromatography method, for four species of Amphibians with different nuclear DNA content: Xenopus laevis (3 pg DNA per haploid genome) and Bufo bufo (7 pg) of the Anura subclass and Trituras cristatus (23 pg) and Necturus maculosus (52 pg) of the Urodela subclass.Within each subclass the two species studied were found to have about the same absolute amount of unique DNA. The differences of total nuclear DNA can be accounted for by quantitative variations of the repetitive sequence classes, at least in part due to changes in the number of copies of the various sequences. On the contrary the great difference in nuclear DNA between the two subclasses, Anura and Urodela, involves all sequence classes in parallel; the slowly reassociating fraction appears to be unique in spite of a tenfold difference in absolute amount.The dependence of reassociation kinetics on DNA fragment length for the four species indicates for all of them an interspersed organization of the various sequence classes.     

Interspersion of repetitive and nonrepetitive DNA sequences in the Drosophila melanogaster genome

Cot analysis shows that the haploid Drosophila genome contains 12% rapidly reassociating, highly reiterated DNA, 12% middle repetitive DNA with an average reiteration frequency of 70, and 70% single-copy DNA. The distribution of the middle repetitive sequences in the genome has been studied by an examination in the electron microscope of the structures obtained when middle repetitive sequences present on large DNA strands reassociate and by the hydroxyapatite binding methods developed by Davidson et al. (1973). At least one third by weight of the middle repetitive sequences are interspersed in single-copy sequences. These interspersed middle repetitive sequences have a fairly uniform distribution of lengths from less than 0.5 to 13 kb, with a number average value of 5.6 kb. The average distance between middle repetitive sequences is greater than 13 kb. The data do not exclude the possibility that essentially all of the middle repetitive sequences have the interspersion pattern described above; however, it is possible that some of the middle repetitive sequences of Drosophila are clustered in stretches of length much greater than 13 kb. The interspersion pattern of the middle repetitive sequences in Drosophila is quite different from that which occurs in the sea urchin, in Xenopus, in rat, and probably many other higher eucaryotes.     

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).     

Structure, organization, and regulation of a hamster proline-rich protein gene. A multigene family

Genomic DNA fragments bearing proline-rich protein (PRP) genes expressed specifically in hamster parotid glands have been isolated and characterized. Complete exonic sequences as well as intronic and a considerable portion of the flanking sequences are reported for a PRP gene, H29. H29 is interrupted by three intervening sequences, with consensus splice junctions, and it likely encodes the acidic hamster PRP Hp43a. Exceedingly high homology of the 5'-untranslated region and the sequence encoding the signal peptide is observed with other PRPs of all species studied. Significant homology was also detected among the repetitive sequences of the mature acidic PRPs from human, mouse, hamster, and rat. This conservation of the internal repeats of the PRPs suggested that proline-rich protein gene evolution involved intragenic duplication of internal repeats and gene duplication and conversion. Both hamster and mouse PRP genes (H29 and mouse proline-rich protein gene, respectively) share considerable sequence similarity in the 5'-flanking regions for about 100 base pairs upstream. The remainder of the upstream sequences were heterologous except for three oligonucleotide regions with 60-70% sequence conservation. These three regions are thought to be involved in the regulation of the tissue-specific PRP gene induction.     

Interspecific “common” repetitive DNA sequences in salamanders of the genus Plethodon

Intermediate repetitive sequences of Plethodon cinereus which comprised about 30% of the genomic DNA were isolated and iodinated with ¹²⁵I. About 5% of the ¹²⁵I-repetitive fraction hybridized with a large excess of DNA from P. dunni at Cot 20. About half of the ¹²⁵I-DNA in the hybrids was resistant to extensive digestion with S-1 nuclease. The average molecular size of the S-1 nuclease-resistant fraction was about 100 nucleotide pairs. The melting temperature of the S-1 nuclease-resistant fraction was about 2° lower than that of the corresponding fraction made with P. cinereus DNA. These results are taken to indicate the presence in the genomes of P. cinereus and P. dunni of evolutionarily stable common repetitive sequences. The average frequency of repetition of the common repetitive sequences is about 6,000 × in both species. The common repetitive fraction is also present in the genomes of other species of Plethodon, although the general populations of intermediate repetitive sequences are markedly different from one species to another. The cinereus-dunni common repetitive sequences could not be detected in plethodontids belonging to different tribes, nor in more distantly related amphibians. The profiles of binding of the common repetitive sequences to CsCl or Cs₂SO₄-Ag⁺ density gradient fractions of P. dunni DNA suggested that these sequences consisted of heterogeneous components with respect to base compositions, and that they did not include large amounts of the genes for ribosomal RNA, 5S RNA, 4S RNA, or histone messenger RNA. — In situ hybridization of the ³H-labelled intermediate repetitive sequences of P. cinereus to male meiotic chromosomes of the same species gave autoradiographs after an exposure of seven days showing all 14 chromosomes labelled. The pattern of labelling appeared not to be random, but was impossible to analyse on account of the irregular shapes and different degrees of stretching of diplotene and prometaphase chromosomes. In situ hybridization of the same sequences to meiotic chromosomes from P. dunni gave autoradiographs after 60 d exposure in which all chromosomes were labelled. These heterologous in situ hybrids can only have involved the common repetitive sequences.     

Differential spreading of HinfI satellite DNA variants during radiation in Centaureinae

Background and Aims

Subtribe Centaureinae appears to be an excellent model group in which to analyse satellite DNA and assess the influence that the biology and/or the evolution of different lineages have had on the evolution of this class of repetitive DNA. Phylogenetic analyses of Centaureinae support two main phases of radiation, leading to two major groups of genera of different ages. Furthermore, different modes of evolution are observed in different lineages, reflected by morphology and DNA sequences.

Methods

The sequences of 502 repeat units of the HinfI satellite DNA family from 38 species belonging to ten genera of Centaureinae were isolated and compared. A phylogenetic reconstruction was carried out by maximum likelihood and Bayesian inference.

Key Results

Up to eight different HinfI subfamilies were found, based on the presence of a set of diagnostic positions given by a specific mutation shared by all the sequences of one group. Subfamilies V–VIII were mostly found in older genera (first phase of radiation in the subtribe, late Oligocene–Miocene), although some copies of these types of repeats were also found in some species of the derived genera. Subfamilies I–IV spread mostly in species of the derived clade (second phase of radiation, Pliocene to Pleistocene), although repeats of these subfamilies exist in older species. Phylogenetic trees did not group the repeats by taxonomic affinity, but sequences were grouped by subfamily provenance. Concerted evolution was observed in HinfI subfamilies spread in older genera, whereas no genetic differentiation was found between species, and several subfamilies even coexist within the same species, in recently radiated groups or in groups with a history of recurrent hybridization of lineages.

Conclusions

The results suggest that the eight HinfI subfamilies were present in the common ancestor of Centaureinae and that each spread differentially in different genera during the two main phases of radiation following the library model of satellite DNA evolution. Additionally, differential speciation pathways gave rise to differential patterns of sequence evolution in different lineages. Thus, the evolutionary history of each group of Centaureinae is reflected in HinfI satellite DNA evolution. The data reinforce the value of satellite DNA sequences as markers of evolutionary processes.     

5 S DNAs of Xenopus laevis and Xenopus mulleri: evolution of a gene family

The 5 S DNA which contains the genes for 5 S RNA has been purified from the frog Xenopus mulleri and compared with the 5 S DNA of Xenopus laevis. Both DNAs contain highly repetitive sequences in which the gene sequence that codes for 5 S RNA alternates with a spacer sequence. The 5 S DNAs of X. laevis and X. mulleri comprise about 0.7% of the total DNA or about 24,000 and 9000 repeating sequences, respectively. The average repeat length within native X. laevis and X. mulleri 5 S DNA is about 0.5 to 0.6 and 1.2 to 1.5 × 10⁶ daltons, respectively, each repeat of which contains a single gene sequence for 5 S RNA (0.08 × 10⁶ daltons). The two DNAs differ in the average length of their spacers and no cross homology can be detected by heterologous hybridization of the two DNAs, except within the 5 S RNA gene regions. Despite their differences, the spacer sequences of X. laevis and X. mulleri 5 S DNA resemble each other enough to conclude that they have diverged from a common ancestral sequence.The multiple repeating sequences of 5 S DNA in each species have evolved as a family of similar, but not identical sequences. It is known that 5 S DNA is located at the ends (telomeres) of the long arms of most, if not all, X. laevis chromosomes. It is proposed that multiple gene sequences located on the ends of many chromosomes can evolve together as a family if there is extensive and unequal exchange of DNA sequences between homologous and non-homologous chromosomes at their ends.     

Restriction fragment length polymorphism analysis of Cryptosporidium parvum isolates of bovine and human origin.

Cryptosporidium parvum oocysts isolated from different hosts and geographical areas were compared by restriction endonuclease analysis of repetitive DNA: Iowa (bovine), Florida (bovine), New York (bovine), Peru (human), Brazil (human), and Mexico (human). Southern blot hybridization analysis was performed using the restriction endonuclease enzyme Eco RI and the DNA probe pV47-2. The probe hybridized with 18 bands present in all the isolates. The Brazilian, Mexican, and Peruvian human isolates had an additional common band of 4.3 kbp that was absent in the bovine isolates. Two extra bands of 14 and 12 kbp were present in the Brazilian isolate whereas the Mexican isolate had an extra band of 14 kbp. When the Iowa and Peru C. parvum isolates were passed twice through calves, oocysts recovered from both passages showed identical banding patterns, suggesting that recombination of the repetitive sequences was not altered during sexual reproduction. The DNA digested with other restriction endonucleases were tested confirming differences between isolates. A genomic DNA library is currently being produced to better define isolate variation in C. parvum.     

Repetitive DNA in differentiating chick tissues

Embryonic chick DNA from different tissues was examined for differences in relative content of highly repetitive DNA which might indicate specific DNA amplification in somatic cells. The content of repetitive sequences in DNA isolated from cerebrum, muscle, and neural retina tissues, at the same and at different embryonic stages, was determined by hydroxyapatite fractionation of partially reassociated DNA samples. An unrenatured marker DNA (C14-labeled E. coli DNA) was added to each chick DNA sample in order to monitor the nonspecific single-stranded DNA retention by each hydroxyapatite column. When chick DNA samples were sheared to a double-stranded length of 1,300 nucleotide pairs, an average of 20.2% +/- 2.2% of the DNA was found to reassociate at a Cot value of 10. The quantity of the fast reassociating sequences was found to constitute the same fraction of the DNA in all the tissues studied. In addition, all the reassociated DNA samples exhibited the same CsCl density classes. The studies also indicated that most chick DNA repetitive sequences are interspersed with nonrepetitive sequences.