Structural organization of alpha-satellite DNA in a single monkey chromosome

The organization of α-satellite sequences in a single monkey chromosome has been studied by restriction endonuclease analysis and molecular cloning. A somatic cell hybrid containing the monkey chromosome was isolated by cloning after fusion of the mouse L-cell line B82 (thymidine kinase minus) with primary African green monkey kidney cells and selective growth in HAT medium. Unlike the mouse cells, the hybrid cells contain DNA that hybridizes with the α-satellite DNA of the monkey. The presence of a single α-satellite containing monkey chromosome was demonstrated by Giemsa-11 staining and by the absence of both this chromosome and monkey α-satellite DNA sequences in cells after back-selection in bromodeoxyuridine. Hybridization of restriction endonuclease-digested hybrid cell DNA with a cloned segment of African green monkey α-satellite DNA showed distinctly different patterns from those observed with monkey total DNA. In particular, EcoRI and HaeIII restriction endonuclease sites are much more abundant in the satellite sequences in the thymidine kinase-carrying chromosome than they are in total satellite. A library of hybrid DNA was constructed in a λ bacteriophage. Analyses of purified recombinant phage that hybridized with α-satellite also indicated an abundance of EcoRI and HaeIII sites. Of nine phage studied in detail, no two showed identical distributions of the two restriction sites in the α-satellite sequences, suggesting the independent evolution of different domains within the single chromosome. These results indicate that the thymidine kinase-carrying chromosome contains distinct subsets (domains) of the α-satellite DNA of the whole monkey genome and further, that while the satellite sequence on the single chromosome is distinctive, it is also complex.     

A new approach to the study of nucleotide sequences in DNAs

The composition of the 3′terminal, 5′terminal and 5′penultimate nucleotides of the oligonucleotides released by spleen acid DNase and snail acid DNase from five `repetitive' DNAs (guinea pig, mouse and crab satellite DNAs, yeast mitochondrial DNA and poly (dAT:dAT)) and four `eukaryotic' DNAs (calf thymus, guinea pig and mouse liver DNAs, and yeast nuclear DNA) have been investigated and found to deviate in characteristic ways from those expected for bacterial DNAs having comparable base compositions. The deviation patterns obtained represent a novel way of characterizing and comparing different DNAs on the basis of the frequency of the nucleotide sequences they contain.     

Organization of African green monkey DNA at junctions between alpha-satellite and other DNA sequences

Segments of African green monkey DNA containing sequences of the highly reiterated cryptic satellite DNA called α-satellite were selected from a library in λ bacteriophage. This λ library was constructed to enrich for monkey segments that contain (1) irregular regions of α-satellite and (2) α-satellite linked to other monkey sequences. At least 11 of 15 cloned monkey segments between 13 × 10³ and 16 × 10³ base-pairs in length, selected by hybridization to α-satellite, also include other monkey sequences.In general, α-satellite sequences close to the junctions with non-α-satellite DNA contain an abundance of divergent forms compared to the average frequency of such forms within total α-satellite. Many of the cloned segments are missing some of the HinIII sites that occur once in most monomer units of α-satellite, and likewise several of the cloned segments contain restriction sites that rarely occur in α-satellite as a whole. In some segments HinIII sites occur that are spaced at distances other than the basic multiple of 172 base-pairs. At least one of the cloned segments, however, is composed mainly of typical 172 base-pair long α-satellite monomer units.Several of these cloned DNAs have been mapped by restriction endonuclease digestion and Southern blot analysis and the arrangements of α-satellite and non-α-satellite sequences have been determined. In addition to segments that contain a boundary where satellite meets other types of sequence, some contain two such boundaries and thus satellite flanks a non-α-satellite segment. Further, two different types of non-α-satellite sequence appear to be common to more than one phage, perhaps indicating some recurring organization at boundaries.     

Highly repetitive component α and related alphoid DNAs in man and monkeys

The genomes of Old-World, New-World, and prosimian primates contain members of a large class of highly repetitive DNAs that are related to one another and to component DNA of the African green monkey by their sequence homologies and restriction site periodicities. The members, of this class of highly repetitive DNAs are termed the alphoid DNAs, after the prototypical member, component of the African green monkey which was the first such DNA to be identified (Maio, 1971) and sequenced (Rosenberg et al., 1978). The alphoid DNAs appear to be uniquely primate sequences. — From the restriction enzyme cleavage patterns and Southern blot hybridizations under different stringency conditions, the alphoid DNAs comprise multiple sequence families exhibiting varying degrees of homology to component DNA. They also share common elements in their restriction site periodicities (172 · n base-pairs), in the long-range organization of their repeating units, and in their banding behavior in CsCl and Cs₂SO₄ buoyant density gradients, in which they band within the bulk DNA as cryptic repetitive components. — In the three species from the Family Cercopithecidae examined, the alphoid DNAs represent the most abundant, tandemly repetitive sequence components, comprising about 24% of the African green monkey genome and 8 to 10% of the Rhesus monkey and baboon genomes. In restriction digests, the bulk of the alphoid DNAs among the Cercopithecidae appeared quantitatively reduced to a simple series of arithmetic segments based on a 172 base-pair (bp) repeat. In contrast with these simple restriction patterns, complex patterns were observed when human alphoid DNAs were cleaved with restriction enzymes. Detailed analysis revealed that the human genome contains multiple alphoid sequence families which differ from one another both in their repeat sequence organization and in their degree of homology to the African green monkey component DNA. — The finding of alphoid sequences in other Old-World primate families, in a New-World monkey, and in a prosimian primate attests to the antiquity of these sequences in primate evolution and to the sequence conservatism of a large class of mammalian highly repetitive DNA. In addition, the relative conservatism exhibited by these sequences may distinguish the alphoid DNAs from more recently evolved highly repetitive components and satellite DNAs which have a more restricted taxonomical distribution.     

Subunit structure of chromatin and the organization of eukaryotic highly repetitive DNA: recurrent periodicities and models for the evolutionary origins of repetitive DNA.

A restriction enzyme analysis of the repeat structure of mouse satellite, sheep satellite II, human highly repetitive fractions, calf satellite I, and a repetitive fraction of the rat indicates that those DNAs share repeat periodicites in common with one another and with the highly repetitive component α DNA of the African green monkey. The basic repeat periodicity of component α is 176 ± 4 nucleotide base-pairs: the repeat periodicities of the various highly repetitive fractions described here also seem based on this fundamental unit, but it is disguised by a superimposed, higher order repeat organization in each case. The higher orders of organization are based on integral multiples of the basic unit which may reflect the nucleosome spacing of constitutive heterochromatin. With the exception of component α DNA, which shows a repeat structure based on a monomer of 176 ± 4 nucleotide base-pairs, all of the highly repetitive DNAs examined showed a preference for even-numbered or geometric multiples of the basic unit in their higher order sequence organization. It is suggested that such organization is a relatively recent development in the hierarchical evolution of the sequences.Several models are discussed which may account for the higher order organization and expansion of these highly repetitive DNAs. Either a modified unequal crossover model (Smith, 1973) or a modified replicative loop model (Keyl, 1965a) seems consistent with many of the properties of highly repetitive DNAs. The models may have implications for the number, distribution and intranuclear rearrangements of transcribed sequences associated with such DNAs.     

Cae I: an endonuclease isolated from the African green monkey with properties indicating site-specific cleavage of homologous and heterologous mammalian DNA.

Component alpha DNA is a highly repetitive sequence that comprises nearly a quarter of the African green monkey (Cercopithecus aethiops) genome. A previous microbial restriction enzyme analysis showed that the repeat structure of component alpha DNA is based upon a monomeric unit of 176 +/- 4 base-pairs. An endonuclease, provisionally termed Case I, has been isolated from African green monkey testes that cleaves component alpha DNA into multimeric segments based upon the same repeat periodicity as that revealed by microbial restriction enzymes. The primary sites of Cae I cleavage in the component alpha sequence appear to be 120 +/- 6 base-pairs distant from the Hind III sites and 73 +/- 6 base-pairs distant from the Eco RI* sites. Cae I has been partially characterized with special reference to the effects of ATP and S-adenosylmethionine on the cleavage of component alpha DNA. Cae I may be a member of a class of similar site-specific nucleases present in mammalian cells. Cae I also cleaves mouse satellite DNA into a multimeric series of discrete segments: the periodicity of this series is shorter than that revealed by Eco RII retriction analysis of mouse satellite DNA.     

Conservation of repetitive DNA sequences in deer species studied by Southern blot transfer

Summary The Cervidae show one of the largest variations in chromosome number found within a mammalian family. The five species of the deer family which are the subject of this study vary in chromosome number from 2n=70 to 2n=6. Digestion with the restriction enzymes EcoRI, HpaII, HaeIII and MspI reveals that there is a series of highly repetitive sequences forming similar band patterns in the different species. To obtain information on the degree of homology among these conserved sequences we isolated a HpaII restriction fragment of approximately 990 base pairs from reindeer DNA. This DNA sequence was³²P-labelled and hybridized by the Southern blot technique to DNAs cleaved with HpaII and HaeIII from the reindeer and four other Cervidae species. Hybridization to specific restriction fragments was recorded in all species. The patterns of hybridization showed a higher degree of similarity between reindeer, elk and roe deer than between reindeer and the Asiatic species (fallow deer and muntjac). Homologies are still present between the highly repetitive sequences of the five species despite the drastic reorganization that led to a change in chromosome number from 6 to 70.     

Comparative analysis of three guinea pig satellite DNA's by restriction nucleases.

The structures of guinea pig satellite DNAs I, II, and III have been analyzed by digestion with seven restriction nucleases. From the cleavage patterns it is obvious that the long-range periodicities in these three satellites differ rather characteristically Satellite I is fairly resistant to six nucleases and gives only a number of weak discrete bands which do not show a simple regularity. By the restriction nuclease from Arthrobacter luteus, however, it is cleaved extensively and yields very heterogeneous breakdown products. This is consistent with the high extent of divergence previously found for this satellite, e. g. by sequence analysis. Satellite II is almost completely resistant to all nucleases, indicative of a high degree of sequence homogeneity of this satellite. Satellite III is completely broken by the restriction nuclease from Bacillus subtilis into fragments which form a novel, highly regular series of bands in gel electrophoresis. The patterns show that the satellite is composed of tandem repeats ofapproximately 215 nucleotide pairs length, each repeat unit containing two cleavage sites for this nuclease. The data are consistent with the assumption that 30--40% of all cleavage sites have been eliminated by a random process. Satellite III DNA yields weak degradation patterns of the same periodicity with a number of other restriction nucleases. Cleavage sites for these nuclease are clustered on separatesmall segments of the satellite DNA. In this respect, the satellite is similar to others, notably the mouse satellite DNA. The three guinea pig satellites are examples of more general types of satellite structures also found in othe organisms. Similarities and differences to other satellites are discussed with special consideration to theories on the evolution of this class of DNA.     

Cloning and expression of a mouse adenine phosphoribosyltransferase gene

A functional mouse adenine phosphoribosyltransferase (APRT) gene was identified and cloned by screening a mouse sperm genomic DNA library in lambda Charon 4A. The probe utilized for screening was a restriction fragment encoding much of the hamster APRT gene. Six recombinants that hybridized with the probe were identified, and after digestion with restriction enzymes EcoRI and PvuII revealed three different patterns of digestion for each enzyme. Of the six recombinants, five representing two of the restriction patterns possessed transforming activity. A sixth recombinant, which has a unique restriction pattern, lacks transforming activity but hybridizes well with hamster APRT coding sequences and is a possible candidate for a pseudogene. We used three criteria for conclusively identifying the mouse APRT genes. (1) DNA from the recombinant lambda phage hybridizes with DNA encoding hamster APRT. (2) The recombinant lambda phages and their DNAs transform mouse, hamster and human APRT- cells to the APRT+ phenotype. (3) The hamster and human transformants display APRT activity that migrates with a mobility characteristic of mouse APRT and not of hamster or human. A 3.1-kb EcoRI-SphI restriction fragment which retains transforming activity has been subcloned into the plasmid pBR328. Comparison of restriction enzyme sites with those contained in a mouse APRT cDNA, coupled with loss of transforming activity after enzyme digestion, indicates that the mouse APRT gene is larger than 1.8 kb and contains at least three introns.     

Labeling deoxyribonucleic acid to high specific activity in vitro by nick translation with DNA polymerase I

Circular (e.g. simian virus 40) and linear (e.g. λ phage) DNAs have been labeled to high specific radioactivities (>10⁸ cts/min per μg) in vitro using deoxynucleoside [α-³²P]triphosphates (100 to 250 Ci/mmol) as substrates and the nick translation activity of Escherichia coli DNA polymerase I. The reaction product yields single-stranded fragments about 400 nucleotides long following denaturation. Because restriction fragments derived from different regions of the nick-translated DNA have nearly the same specific radioactivity (cts/min per 10[su3] bases), we infer that nicks are introduced, and nick translation is initiated, with equal probability within all internal regions of the DNA. Such labeled DNAs (and restriction endonuclease fragments derived from them) are useful probes for detecting rare homologous sequences by in situ hybridization and reassociation kinetic analysis.     

New endogenous herpesvirus of guinea pigs: biological and molecular characterization.

Two known guinea pig herpesviruses, guinea pig cytomegalovirus (GPCMV) and guinea pig herpes-like virus (GPHLV), and well characterized. A third herpesvirus (GPXV) was originally isolated from leukocytes of healthy strain 2 guinea pigs. Growth of GPXV in guinea pig embryo fibroblastic cells produced a characteristic cytopathic effect. Electron microscopy of guinea pig cells infected with GPXV revealed the morphological development of a herpesvirus. Cross-neutralization tests and immunoferritin electron microscopy demonstrated that GPXV, GPCMV, and GPHLV were serologically distinct herpeviruses of guinea pigs. To confirm the distinction between these three herpesviruses, DNA genomes were compared by CsCl equilibrium buoyant density measurements and restriction endonuclease cleavage analysis. 32P-labeled viral DNA ws obtained from nucleocapsids isolated from virus-infected cells, and the buoyant density of GPXV DNA differed from that of GPCMV and GPHLV. Cleavage of viral DNAs with restriction endonucleases followed by gel electrophoresis revealed distinct patterns for each virus.     

Subunit structure of chromatin and the organization of eukaryotic highly repetitive DNA: indications of a phase relation between restriction sites and chromatin subunits in African green monkey and calf nuclei.

The periodicities of the restriction enzyme cleavage sites in highly repetitive DNAs of six mammalian species (monkey, mouse, sheep, human, calf and rat) appear related to the length of DNA contained in the nucleosome subunit of chromatin. We suggest that the nucleosome structure is an essential element in the generation and evolution of repeated DNA sequences in mammals (Brown et al., 1978; Maio et al., 1977). The possibility of a phase relation between DNA repeat sequences and associated nucleosome proteins is consistent with this hypothesis and has been tested by restriction enzyme and micrococcal nuclease digestions of repetitive DNA sequences in isolated, intact nuclei.Sites for four different restriction enzyme activities, EcoRI, EcoRI¹, HindIII and HaeIII have been mapped within the repeat unit of component α DNA, a highly repetitive DNA fraction of the African green monkey. The periodicity of cleavage sites for each of the enzymes (176 ± 4 nucleotide base-pairs) corresponds closely to the periodicity (about 185 nucleotide base-pairs) of the sites attacked in the initial stages of micrococcal nuclease digestion of nuclear chromatin. In intact monkey nuclei, EcoRI-RI¹ sites are accessible to restriction enzyme cleavage; the HindIII and HaeIII sites are not. The results suggest (1) that, in component α chromatin, the EcoRI-RI¹ sites are found at the interstices of adjacent nucleosomes and (2) the HindIII and HaeIII sites are protected from cleavage by their location on the protein core of the nucleosome. This interpretation was confirmed by experiments in which DNA segments of mononucleosomes and nucleosome cores released from CV-1 nuclei by micrococcal nuclease were subsequently treated with EcoRI, EcoRI¹ and HindIII. A major secondary segment of component α, about 140 nucleotide base-pairs in length, was released only by treatment with HindIII, in keeping with the location of the HindIII sites in the restriction map and their resistance to cleavage in intact nuclei.EcoRI reduces calf satellite I DNA to a segment of about 1408 nucleotide basepairs. In contrast, restriction of calf satellite I DNA with EcoRI¹ produces six prominent segments ranging in size from 176 to 1408 nucleotide base-pairs. Treatment of isolated calf nuclei with either EcoRI or EcoRI¹ did not produce segments shorter than 1408 base-pairs, indicating that while canonical EcoRI sites are accessible to attack, the irregularly spaced EcoRI¹ sites are specifically blocked. The results are consistent with a phase relation between the repeat sequence of calf satellite I DNA and an octameric array of nucleosomes.     

A study of the evolution of repeated DNA sequences in primates and the existence of a new class of repetitive sequences in primates.

A new class of lowly repetitive DNA sequences has been detected in the primate genome. The renaturation rate of this sequence class is practically indistinguishable from the renaturation rate of single-copy sequences. Consequently, this lowly repetitive sequence class has not been previously observed in DNA renaturation rate studies. This new sequence class is significant in that it might occupy a major fraction of the primate genome.Based on a study of the thermal stabilities of DNA heteroduplexes constructed from human DNA and either bonnet monkey or galago DNAs, we are able to compare the relative mutation rates of repetitive and single-copy sequences in the primate genome. We find that the mutation rate of short, interspersed repetitive sequences is either less than or approximately equal to the mutation rate of single-copy sequences. This implies that the base sequence of these repetitive sequences is important to their biological function.We also find that numerous mutations have accumulated in interspersed repeated sequences since the divergence of galago and human. These mutations are only recognizable because they occur at specific sites in the repeated sequence rather than at random sites in the sequence. Although interspersed repetitive sequences from human and galago can readily cross-hybridize, these site-specific mutations identify them as being two distinct classes. In contrast, far fewer site-specific mutations have occurred since the divergence of human and monkey.     

Characterization of guinea pig cytomegalovirus DNA.

The genome of guinea pig cytomegalovirus (GPCMV) was analyzed and compared with that of human cytomegalovirus (HCMV). GPCMV and HCMV DNAs were isolated from virions and further purified by CsCl centrifugation. Purified GPCMV DNA sedimented as a single peak in a neutral sucrose gradient and was infectious when transfected into guinea pig embryo fibroblast cells. The cytopathology was characteristic of that seen after infection with GPCMV. Virus DNA purified from virions isolated from infected GPEF or 104C1 cells had a CsCl buoyant density of 1.713 g/cm3, which corresponds to a guanine plus cytosine content of 54.1%. The CsCl buoyant density of GPCMV DNA was slightly less than that of HCMV DNA (1.716 g/cm3), but sufficiently different so that the two virus DNA peaks did not coincide. GPCMV DNA cosedimented with T4 DNA in a neutral sucrose gradient. Restriction endonuclease cleavage of GPCMV or HCMV DNAs with HindIII, XbaI, or EcoRI yielded fragments easily separable by agarose gel electrophoresis and ranging from 1.0 X 10(6) to 25.8 X 10(6) daltons. The number, size, and molarity of GPCMV DNA fragments generated by restriction enzymes were determined. Hybridization of restriction endonuclease-cleaved GPCMV DNA with radioactively labeled HCMV DNA and, conversely, hybridization of restriction endonuclease-cleaved HCMV DNA with radioactively labeled GPCMV DNA indicated sequence homology between the two virus DNAs.     

Variations in induction of drug-metabolizing enzymes by trans-Stilbene oxide in rodent species

trans-Stilbene oxide (400 mg/kg) produced a 500% increase in the microsomal in the microsomal epoxide hydratase activity in rat and mouse with little change in the soluble enzyme activity. However, in guinea pig, the soluble epoxide hydratase activity increased by about 33% with only a small increase (47.6%) in the microsomal enzyme activity. The soluble glutathione S-transferase activities were also induced in both rat and mouse, with little change in that of the guinea pig. Increasing dosage of trans-stilbene oxide from 400 mg/kg to 1000 mg/kg had little effect on the above enzyme activities. That the guinea pig was not relatively refractory to all inducing agents was shown by the fact phenobarbital (100 mg/kg) and 3-methylcholanthrene (25 mg/kg) produced relatively similar increases in the activities of aniline hydroxylase and P-aminopyrineP-demethylase in rat, mouse and guinea pig. However, these inducers produced only a 15–20% stimulation in the soluble glutathione S-transferase and microsomal epoxide hydratase activities in guinea pig, when compared to a 50–80% increase in rat and mouse, suggesting a general resistance to induction by the phase II enzymes in guinea liver. In all animal models, the inducer markedly increased th emicrosomal total phospholipid content, although the sphingomyelin content itself was decreased. In both rat and mouse, the microsomal cholesterol content was significantly decreased while that in guinea pig was unaffected. Possible factors responsible for the observed species differences are discussed.     

Structural organization of interspersed repetitive elements present in the DNA of Mus musculus

Two-dimensional displays of the restriction fragments from the DNA of Mus musculus revealed a complex species-specific pattern produced from nonsatellite repetitive sequences. The patterns have been used as a guide in the direct purification of a group of broadly interspersed repeated DNA sequences (characterized by a 1350-bp Eco-Bam fragment) that have been studied by molecular cloning, restriction mapping and genomic Southern blotting. These studies show that the cloned representatives originate from an abundant group of sequences that share homology with about 2% of the mouse genome. The sequences do not appear to share homology with mouse-interspersed-family-1 (MIF-1) nor with the major AT-rich satellite sequences of mouse. They appear to be part of a group of larger repetitive elements that is both broadly interspersed and heavily methylated in normal mouse tissue.     

Transfer of African green monkey highly repetitive DNA into mouse L cells

In DNA transfer experiments, using the cloned thymidine kinase (tk) gene from HSV I as selective marker, highly repetitive DNA from African green monkey cells (α-satellite) was introduced into mouse cells by the calcium technique. The tk⁺ transformants (transformation is defined as a change in the genotype by introduction of foreign DNA) contained exogenous DNA in amounts that can be visualized in most cases directly in ethidium bromide (EB)-stained gels. In two transformants it represented approx. 0.1% of the host genome. After transfer into the recipient cells the organization of the α-satellite has been changed as deduced by analysis with restriction nucleases. According to in situ hybridization experiments, most (if not all) of the α-satellite is present at one chromosomal location of the host genome.     

Plasmids containing mouse rDNA do not recombine with cellular ribosomal genes when introduced into cultured mouse cells.

We have examined the fate of plasmids containing a segment of a mouse rDNA repeat after they were introduced by transfection into cultured mouse cells. In addition to the rDNA segment, the plasmids contained the thymidine kinase gene from herpes simplex virus 1 to allow for selection of the plasmid after transfection into thymidine kinase-deficient mouse cells. Thus far, no cases of homologous recombination between transfected plasmid DNAs and host cell sequences have been documented. We reasoned that the high repetition frequency of the rRNA genes in the mouse genome (200 copies per diploid cell) might create a favorable situation for obtaining homologous recombination events between the plasmids containing rDNA and host cell rDNA sequences. The plasmids were introduced into cells in both the presence and the absence of carrier DNA and both as covalently closed circles and linear molecules. The sites of plasmid integration in the genomes of various cell lines were examined by DNA restriction digests and hybridization, molecular cloning, and nuclear fractionation. In the seven cell lines examined, there was no evidence that the plasmids had integrated into the rRNA gene clusters of the cell. Thus, the apparent absence of site-specific integration of cloned DNAs introduced into mammalian cells does not appear to be due simply to the small target presented by most host cell sequences.     

Tissue specific methylation of human Y chromosomal DNA sequences

This report describes two moderately repetitive human Y chromosomal DNA sequences isolated from a flow sorted Y chromosonal library. These sequences are present in XY male and XY female DNAs but absent in XX male and XX female DNAs. Genomic Southern blot analysis against DNAs isolated from different tissues showed tissue specific DNA methylation patterns. In contrast to the 2.1 kb Hae III repeats which are hypomethylated in sperm DNA, the moderately repetitive sequences used in this study are highly methylated in sperm, less methylated in blood and brain and least methylated in placental DNA.     

Genomic Subtraction Recovers Rye-Specific DNA Elements Enriched in the Rye Genome

Repetitive DNA sequence families have been identified in methylated relic DNAs of rye. This study sought to isolate rye genome-specific repetitive elements regardless of the level of methylation, using a genomic subtraction method. The total genomic DNAs of rye-chromosome-addition-wheat lines were cleaved to short fragments with a methylation-insensitive 4-bp cutter, MboI, and then common DNA sequences between rye and wheat were subtracted by annealing with excess wheat genomic DNA. Four classes of rye-specific repetitive elements were successfully isolated from both the methylated and non-methylated regions of the genome. Annealing of the DNA mixture at a ratio of the enzyme-restricted fragments:the sonicated fragments (1:3–1:5) was key to this success. Two classes of repetitive elements identified here belong to representative repetitive families: the tandem 350-family and the dispersed R173 family. Southern blot hybridization patterns of the two repetitive elements showed distinct fragments in methylation-insensitive EcoO109I digests, but continuous smear signals in the methylation-sensitive PstI and SalI digests, indicating that both of the known families are contained in the methylated regions. The subtelomeric tandem 350-family is organized by multimers of a 380-bp-core unit defined by the restriction enzyme EcoO109I. The other two repetitive element classes had new DNA sequences (444, 89 bp) and different core-unit sizes, as defined by methylation-sensitive enzymes. The EcoO109I recognition sites consisting of PyCCNGGPu-multi sequences existed with high frequency in the four types of rye repetitive families and might be a useful tool for studying the genomic organization and differentiation of this species.