Heterogeneity of pumpkin ribosomal DNA

Intragenomic heterogeneity of intergenic ribosomal DNA spacers in Cucurbita moschata is determined by DNA minisatellites with variable potential to form non-canonical DNA conformations

The intergenic spacer (IGS) of rDNA is frequently built of long blocks of tandem repeats. To estimate the intragenomic variability of such knotty regions, we employed PacBio sequencing of the Cucurbita moschata genome, in which thousands of rDNA copies are distributed across a number of loci. The rRNA coding regions are highly conserved, indicating intensive interlocus homogenization and/or high selection pressure. However, the IGS exhibits high intragenomic structural diversity. Two repeated blocks, R1 (300-1250 bp) and R2 (290-643 bp), account for most of the IGS variation. They exhibit minisatellite-like features built of multiple periodically spaced short GC-rich sequence motifs with the potential to adopt non-canonical DNA conformations, G-quadruplex-folded and left-handed Z-DNA. The mutual arrangement of these motifs can be used to classify IGS variants into five structural families. Subtle polymorphisms exist within each family due to a variable number of repeats, suggesting the coexistence of an enormous number of IGS variants. The substantial length and structural heterogeneity of IGS minisatellites suggests that the tempo of their divergence exceeds the tempo of the homogenization of rDNA arrays. As frequently occurring among plants, we hypothesize that their instability may influence transcription regulation and/or destabilize rDNA units, possibly spreading them across the genome.

A MOLECULAR REEXAMINATION OF INTROGRESSION BETWEEN HELIANTHUS ANNUUS AND H. BOLANDERI (COMPOSITAE)

Heiser (1949) hypothesized that a weedy race of Helianthus bolanderi had originated by the introgression of genes from H. annum into a serpentine race of H. bolanderi. Although Heiser's investigation of these species is frequently cited as one of the best examples of introgression in plants, definitive evidence of gene exchange is lacking (Heiser, 1973). To determine whether the weedy race of H. bolanderi actually originated via introgression, we analyzed allozyme, chloroplast-DNA (cpDNA), and nuclear-ribosomal-DNA (rDNA) variation. Evidence from enzyme electrophoresis did not support the proposed introgressive origin of weedy H. bolanderi. We detected a total of 37 low-frequency alleles distinguishing the serpentine race of H. bolanderi from H. annuus. Weedy H. bolanderi possessed only four of the 37 marker alleles. Further analysis demonstrated that serpentine H. bolanderi combined seven of the 35 alleles distinguishing H. annuus from weedy H. bolanderi, indicating that serpentine H. bolanderi shares three more marker alleles with H. annuus than does weedy H. bolanderi. These results are similar to expectations for race divergence from a single common ancestor and suggest that, if introgression occurred, the majority of marker alleles were rapidly lost following the initial hybridization event. Even more compelling evidence opposing Heiser's (1949) hypothesis, however, was from restriction-fragment analysis of cpDNA and nuclear rDNA. We detected a total of 17 cpDNA and five rDNA restriction-site mutations among the 19 populations examined. No parallel or back mutations were observed in phylogenetic trees constructed using either cpDNA or rDNA mutations, and both phylogenies were completely congruent regarding the alignment of all three taxa. In addition, the weedy race of H. bolanderi possessed a unique cpDNA, which was outside the range of variation observed among populations of either of the presumed parental species. Mean sequence divergences between the cpDNAs of weedy H. bolanderi and those of serpentine H. bolanderi and H. annuus were 0.30% and 0.35%, respectively. These estimates are comparable to sequence-divergence values observed between closely related species in other plant groups. Given the lack of parallel or convergent mutations in the cpDNA and rDNA phylogenetic trees, the complete congruence of these trees with flavonoid- and allozyme-variation patterns, and the presence of a unique and divergent chloroplast genome in the weedy race of H. bolanderi, we suggest that the weedy race of H. bolanderi was not derived recently through introgression, as hypothesized, but is relatively ancient in origin.

Pattern and degree of methylation in ribosomal RNA genes of Cucurbita pepo L

Methylation with respect to its degree and distribution throughout the 18S, 5.8S and 25S rRNA gene clusters (rDNA) and within single rDNA repeats in seedlings of the higher plant Cucurbita pepo L. (zucchini) was investigated. In this plant, which is characterized by several thousand repeats, at least 70% are completely or nearly completely methylated in CpGs and to a lower degree in CpNpGs. Detailed methylation analysis revealed that a fraction of about 3-4% of all repeats is hypomethylated near the transcription initiation site (TIS) which may indicate the fraction of active repeats in C. pepo. However, a different fraction (3-4% of all repeats) which is not methylated in all sites tested (including those at the TIS) is present in C. pepo and may thus represent active but differentially methylated rDNA. The results are discussed in context of recent models on methylation and gene activity.

Structure of the intergenic spacer region from the ribosomal RNA gene family of white spruce (Picea glauca)

Five genomic clones containing ribosomal DNA repeats from the gymnosperm white spruce (Picea glauca) have been isolated and characterized by restriction enzyme analysis. No nucleotide variation or length variation was detected within the region encoding the ribosomal RNAs. Four clones which contained the intergenic spacer (IGS) region from different rDNA repeats were further characterized to reveal the sub-repeat structure within the IGS. The sub-repeats were unusually long, ranging from 540 to 990 bp but in all other respects the structure of the IGS was very similar to the organization of the IGS from wheat, Drosophila and Xenopus.

Molecular evolution of the intergenic spacer in the nuclear ribosomal RNA genes of cucurbitaceae

The intergenic spacer (IGS) of a 10-kbp repeat (clone pRZ7D) of the nuclear 18S, 5.8S, and 25S ribosomal RNA genes of Cucurbita pepo (zucchini) was sequenced and compared to the IGS sequences of two other Cucurbitaceae, Curcurbita maxima (squash), and Cucumis sativus (cucumber). The nucleotide sequence and the structural organization of the IGS of C. pepo and C. maxima are rather similar (between 75 and 100% sequence similarity depending on the region compared). The IGS are mainly composed of three different repeated elements interspersed into unique sequences: GC-rich clusters, a 422-bp AT-rich element including the transcription initiation site (TIS) for RNA polymerase I, and 260-bp repeats in the 5' external transcribed spacer (D repeats). The TIS is duplicated in the 10-kbp repeat class of C. pepo, as it is also described for the 11.5-kbp rDNA repeat of C. maxima. The IGS of Cucumis sativus is also composed of different repeated elements; however, obvious sequence identity to the Cucurbita species only occurs around the TIS and the preceding AT-rich region. GC-rich clusters with different primary sequences are present in the IGS of all three plants. Remarkably, the repeated elements in the 5'ETS accumulate TpG and TpNpG motifs, whereas CpG and CpNpG motifs less frequently occur. This accumulation might be caused by the transition of methylated cytosines (in mCpG or mCpNpG motifs) into thymidine via deamination in a previously GC-rich ancestor. The following singular region exhibits 50% G + C in C. pepo, 53% G+C in C. maxima, and 63% G + C in C. sativus.(ABSTRACT TRUNCATED AT 250 WORDS)

Predominance and tissue specificity of adenine methylation in rice

Using 'A' and 'C' methylation-specific restriction enzymes, namely, MboI, Sau3AI, DpnI, MspI, and HpaII, total rice cv Basmati 370 DNA, repetitive DNAs, and a specific repeat sequence indicated an abundance of adenine methylation. Although cytosine methylation in 5'-CCGG-3' sequences suggested more CpC methylation than CpG, the 'C' methylation in sequence 5'-GATC-3' was comparatively less than 'A' methylation. Furthermore, the presence of adenine methylation was tissue specific; it was predominant in rice shoot DNA as compared to embryo DNA. This pattern was also observed in two other cultivars of rice, i.e., R-24 and Sona, and was again confirmed using a cloned probe of a specific repeat sequence. Besides the changes in adenine methylation, there was also a qualitative change in 5mC from CpG to CpC dinucleotides in these two tissue systems.

Study of TMV assembly with heterologous RNA containing the origin-of-assembly sequence

The assembly of tobacco mosaic virus (TMV) is initiated by a specific reaction between a capsid protein oligomer and an origin-of-assembly region (OAS) located 900 nucleotides from the 3' terminus of virion RNA. Packaging is then completed by rod elongation both in the 5' and 3' directions. The temporal order of the direction of elongation and the characteristics of the reaction were studied by analysis of the in vitro assembly reaction between strain U1 protein oligomers and transcripts containing a strain U1 OAS embedded at different positions in heterologous RNA. The results confirm that elongation in the 5' direction starts very soon after the initiation reaction and is completed rapidly, within minutes. Packaging in the 3' direction is slower and does not appear to commence until 5' rod formation is complete. The reaction of strain U2 protein with the strain U1 OAS initiates rapidly, but elongation occurs only in the 5' direction; 3' packaging does not occur except when the OAS is at or near the 5' terminus, in which case elongation in the 3' direction initiates without delay with either the U1 or U2 protein. Pauses occur during elongation in the 3' direction at an average of 320 nucleotides, indicating a packaging periodicity of about six to eight helical turns.

The Cucurbita maxima ribosomal DNA intergenic spacer has a complex structure

The nucleotide (nt) sequence of the 5508-nt intergenic spacer (IGS), between the 25S- and the 18S-coding regions of Cucurbita maxima rDNA, was determined. The fragment sequenced is 6142 nt long and includes 472 nt of 25S- and 162 nt of 18S-coding regions. The IGS has a complex primary structure, composed of five repetitive families (A-E) and three unique domains. It is dominated by the presence of nine, tandemly-repeating units of approximately 250 nt (repeat D), each unit containing four copies of an internal subrepeat (repeat E). The repetitive units show sequence variability consisting of nt changes, insertions and deletions. Upstream of the nine D repeats and between two copies of the B repeat is a 575-nt region, highly G + C rich (83%) and heavily biased toward C (58%) in the sense strand. Within this region are six repetitive units, averaging 42 nt (repeat C) each, containing but a single A nt. Downstream from the terminus of the 25S-coding sequence, are two tandem copies of the 103-nt A repeat. The IGS of C. maxima is longer and more complex than that of other plant IGSs described to date. The 600 nt at the 5' portion of cucurbit IGS is more conserved in evolution than the remainder, as revealed by comparison of C. maxima and C. pepo IGS restriction maps and by nucleotide sequence comparison of C. maxima and Cucumis sativa IGSs.

DNase I sensitivity of ribosomal RNA genes in chromatin and nucleolar dominance in wheat

Ribosomal RNA genes at different nucleolar organizer (NOR) loci in hexaploid wheat are expressed at different levels. The degree of expression of a particular organizer depends on the genetic background, especially on the presence of other NOR loci. For example, when chromosome 1U of Aegilops umbellulata is introduced into the hexaploid wheat cultivar "Chinese Spring" the A. umbellulata NOR accounts for most of the nucleolar activity and seems to suppress the activity of the wheat NOR loci. Even in wild-type "Chinese Spring", the NOR on chromosome 1B is partially dominant to that on chromosome 6B, since the 1B locus is more active in spite of having fewer genes. We have previously shown that these and other examples of nucleolar dominance in wheat are associated with undermethylation of cytosine residues in certain regions of the dominant rDNA. Here, we show that rRNA genes at dominant loci are organized in a chromatin conformation that renders them more sensitive to DNase I digestion than other rRNA genes. In addition, we have mapped several DNase I-hypersensitive sites in the intergenic spacer region of the rDNA repeating unit. Some of these sites are located near the initiation region for the 45 S rRNA precursor, while others are associated with a series of short direct repeats 5' to the 45 S rRNA initiation site. The results are discussed in terms of a model in which repeated sequences in the wheat intergenic DNA are presumed to function as upstream promoters and transcriptional enhancers similar to those in Xenopus.

Structure of melon rDNA and nucleotide sequence of the 17-25S spacer region

Restriction enzyme and hybridization analysis of melon nuclear DNA suggests a homogenous rDNA population with a repeat unit of 10.2 kb. Several full length Hind III rDNA repeat units were cloned and one of these is described in detail. The regions coding for 25S, 17S and 5.8S rRNAs were located by crossed-contact hybridization and R-loop mapping. Introns were not observed. The nucleotide sequence of the internal transcribed spacer and flanking regions was determined and compared with the corresponding region from rice rDNA by dot matrix analysis. In addition, the extent of gross sequence homology between cloned melon and pea rDNA units was determined by heteroduplex mapping.

Characterization of the TMV encapsidation initiation site on 18S rRNA

Tobacco Mosaic Virus capsid protein oligomers react with and encapsidate 18S rRNA from both plant and mammalian sources in vitro. The site (ei) in 18S rRNA which reacts with capsid protein to initiate the packaging reaction has been localized and partially characterized by testing the ability of transcripts from different regions of a cloned Cucurbita pepo rDNA repeat unit to become encapsidated. The 18S rRNA ei is found to react more slowly with capsid protein than does the functional virion ei and to lie within a 43 nucleotide region which starts at position 157 from the 5' terminus of 18S rRNA. When 6 nucleotides are removed from the 5' end, the remaining 37 nucleotide segment is still reactive, but with reduced efficiency. The primary structure of the reactive segment has limited similarity to the virion ei and can be folded into a stem-loop. The first 18 nucleotides of the ei region is highly conserved from an evolutionary standpoint and this may account for the ability of 18S rRNAs from both plant and mammalian sources to be encapsidated.

Characterization of repetitive elements in several Cucurbita species

About 1.3×10(5) copies of a tandemly arranged, 351 base pair element constitute from 4 to 8% of the Cucurbita pepo genome. A homologous, high copy number repetitive element is present in the genomes of C. moschata and C. foetidissima, but not in C. maxima or Cucumis sativus. Array lengths of at least 65 members have been detected for C. pepo, and 140 for C. moschata. The nucleotide sequence of six C. pepo repeat units were determined and each was found to be unique, differing from the others at from 7 to 23 positions. The element was composed of highly modified DNA as evidenced by the fact that only one of its two Hpa I restriction sites is subject to digestion and by the observation that all internal Cs and about half of the external Cs of its single Hpa II site are methylated. At least 5 cellular RNA species contain sequences complementary to one of the DNA strands of the element. These have discrete sizes of 3.0, 2.3, 1.8, 1.3 and 0.5 kb. Such transcripts are detected in C. pepo, C. moschata and C. foetidissima stem and/or leaf RNA, but not root RNA and are probably not polyadenylated. No transcripts were found which contain sequences complementary to the other DNA strand of the element.

Ribosomal RNA genes in plants: variability in copy number and in the intergenic spacer

Ribosomal RNA genes in plants are highly variable both in copy number and in intergenic spacer (IGS) length. This variability exists not only between distantly related species, but among members of the same genus and also among members of the same population of a single species. Analysis of inheritance indicates that copy number change is rapid, occurring even among somatic cells of individual plants, and that up to 90% or more of the gene copies are superfluous. Subrepetitive sequences within the IGS appear to be changing rapidly as well. They are not only variable in sequence from one species to the next, but can vary in number between neighboring gene repeats on the chromosome. In all species examined in detail they are located in the same region of the IGS and contain sequences that can be folded into stem-loop structures flanked by a pyrimidine-rich region. It has been suggested that these subrepeats function in transcriptional enhancement, termination or processing, or in recombination events generating the high multiplicity of ribosomal genes.

Gametoclonal variation detected in the nuclear ribosomal DNA from doubled haploid lines of a spring wheat (Triticum aestivum L., cv. 'César')

The organization of the nuclear ribosomal DNA from a parental line of wheat (Triticum aestivum L., cv. 'César') and its anther-derived first cycle and second cycle doubled haploid lines has been analyzed by DNA-DNA molecular hybridization. Restricted DNA has been probed by three subclones of wheat nuclear ribosomal DNA covering the entire repeat unit. No significant difference was detected in the extent of methylation of ribosomal DNA of the doubled haploid lines with respect to the parental line. On the other hand, a variation has been found in the organization of the nontranscribed spacer region of ribosomal DNA of the first cycle doubled haploid line. This variation remains stable after a second cycle of in vitro androgenesis. However, one out of five second cycle doubled haploid lines so far tested showed an additional hybridization band present in the parental line but lacking in the first cycle doubled haploid line.

Developmental regulation of cytosine methylation in the nuclear ribosomal RNA genes of Pisum sativum

Prominent features of the cytosine methylation pattern of the Pisum sativum nuclear ribosomal RNA genes have been defined. Cytosine methylation within the C-C-G-G sequence was studied using the restriction enzymes HpaII and MspI and gel blot hybridizations of the restriction digests. The extent to which particular features of the methylation pattern change during seedling development has also been determined. Total cellular DNA, purified from defined sections of pea seedlings grown under different lighting conditions, was analyzed with DNA hybridization probes derived from different portions of a cloned member of the nuclear rRNA gene family. By use of an indirect end-labeling technique, a map of 23 cleavable HpaII and/or MspI sites in genomic rDNA was constructed. The map covers about 90% of the rDNA repeat including the entire non-transcribed spacer region and most of the rRNA coding sequences. One notable feature of the map is that the most prominent HpaII site, located about 800 base-pairs upstream from the 5' end of the mature 18 S rRNA, is cleaved only in one of the two most abundant rDNA length variants (the short variant). With a gel blot assay specific for cleavage at this site, we estimated the HpaII sensitivity of DNA preparations from several stages of pea seedling development. We find that, while methylation is generally low in young seedlings, DNA obtained from the apical buds of pea seedlings is highly methylated. Further, the methylation level of rDNA within the pea bud decreases as the buds are allowed to develop under continuous white light. Our data, taken together with published studies on pea seedling development, indicate that cytosine methylation levels may be related to the regulated expression of the nuclear rRNA genes in pea.

Structure and variation in ribosomal RNA genes of pea : Characterization of a cloned rDNA repeat and chromosomal rDNA variants

A complete ribosomal DNA (rDNA) repeat unit has been cloned from the genome of Pisum sativum (garden pea) and used to construct a map containing a total of 58 cleavage sites for 23 different restriction enzymes. Regions encoding 18s and 25s ribosomal RNA (rRNA) were identified by R-loop analysis. A 180 bp sequence element is repeated eight times in the intergenic 'nontranscribed spacer' (NTS) region, as defined by eight evenly spaced RsaI cleavage sites. Sequence heterogeneity among these elements (subrepeats) is indicated by the presence of an NcoI site within the five RsaI subrepeats distal to the 25s rRNA gene but not in the three subrepeats proximal to this gene, and also by the presence of an additional RsaI cleavage site in one subrepeat.The approximately 4000 copies of the rDNA repeat in the pea nuclear genome show considerable heterogeneity with respect to the length of the NTS region, and differences are also frequently observed between different genotypes. In both cases the length variation appears to be due primarily to differences in the number of subrepeat elements.Comparison of rDNA restriction maps for two pea genotypes separated for hundreds or perhaps thousands of generations reveals that they contain many rDNA identical repeat units. This data is consistent with the view that new rDNA variants are fixed only infrequently in the evolution of a species.Differences also exist between the rDNA repeats of a single genotype with respect to the degree of base modification at certain restriction sites. A large number of sites known to exist in the pea rDNA clone are not cleaved at all in genomic rDNA, or are cleaved in only some copies of the rDNA repeat. We believe these examples of incomplete cleavage results mostly from methylation, although it is difficult to rule out the possibility of sequence variation in all cases. Most putative modifications are best interpreted in terms of cytosine methylation in CG and CXG sequences, but at least one example is more consistent with adenine methylation.We also have constructed a more detailed restriction map of the wheat rDNA clone pTA71 and present a comparison of this map to our map of pea, pumpkin, and wheat in order to assess the amount of useful evolutionary information that can be obtained by comparison of such maps.

Variation in the ribosomal RNA genes among individuals of Vicia faba

Length heterogeneity in the ribosomal repeat of Vicia faba is due to the presence of variable numbers of a 325 bp subrepetitive element within the nontranscribed spacer region. The distribution of size classes among 88 individuals within a population was investigated by blot-hybridization. We find that individual plants can exhibit more than 20 size classes and that hybridization patterns are highly diverse from individual to individual, more so than for any species so far investigated. In contrast, no such differences are observed in patterns for different tissues from a single plant or from parental to F1 generation. Some changes were observed in the F2 generation. We conclude that unequal recombination can give rise to the diversity that we observe for the V. faba rDNA repeats.

The structure of the maize ribosomal DNA spacer region

A combination of a single stranded plasmid vector and ordered deletions were used to determine the complete nucleotide sequence of a rDNA spacer region isolated from the DNA of maize Black Mexican Sweet suspension cells. The sequence reveals the presence of ten "200 base" subrepeats within the maize rDNA spacer region. By S1 protection experiments we have tentatively determined that the start of maize rRNA transcription is 144 bases 3' of the end of the last spacer subrepeat. We propose that the spacer subrepeats may have an important role in regulating maize rRNA transcription.

Heterogeneity in cucumber ribosomal DNA

Restriction and hybridization analysis of cucumber native ribosomal (r) DNA purified from actinomycin-D/CsCl gradients suggested that the repeat units were heterogeneous in both length and sequence. Several full length rDNA repeat units were cloned and five are described which account for all the EcoR I and Xba I fragments present in native DNA. One of a number of BamH I sites found in the clones is not found in a proportion of native rDNA because of base modification. Restriction maps are described for the representative clones and aligned with R-loop maps obtained from electron microscope analysis of each type of repeat unit hybridized under R-loop conditions to pure 18S and 25S rRNAs. The major heterogeneity is explained by differences in length of the external spacer region and by a proportion of the repeat units showing a restriction fragment length polymorphism on EcoR I digestion. The regions coding for 18S and 25S rRNA are uninterrupted and highly conserved.

Encapsidation of 18 S rRNA by tobacco mosaic virus coat protein

It has been reported that tobacco mosaic virus capsid protein encapsidates discretesized truncated portions of host 18 S rRNA in vitro. This paper presents further information concerning the nature and specificity of this reaction. We have found that it is only the 5' portions of 18 S rRNA that are encapsidated. The structure recognized by capsid protein is highly conserved; bovine as well as plant 18 S rRNA becomes encapsidated. It is further demonstrated that assembly of 18 S rRNA is slow in comparison to assembly of TMV RNA and that this is due to a slow rate of initiation. Synthetic 18 S rRNA, prepared by in vitro transcription of an 18 S rRNA coding sequence, differs from native 18 S rRNA in that full length, rather than a truncated portion, is encapsidated. The possible reasons for this are discussed.

Characterization of the genome of Arabidopsis thaliana

The small crucifer Arabidopsis thaliana has many useful features as an experimental organism for the study of plant molecular biology. It has a four-week life-cycle, only five chromosomes and a genome size less than half that of Drosophila. To characterize the DNA sequence organization of this plant, we have randomly selected 50 recombinant lambda clones containing inserts with an average length of 12,800 base-pairs and analyzed their content of repetitive and unique DNA by various genome blot, restriction digestion and RNA blot procedures. The following conclusions can be drawn. The DNA represented in this random sample is composed predominantly of single-copy sequences. This presumably reflects the organization of the Arabidopsis genome as a whole and supports prior conclusions reached on the basis of kinetics of DNA reassociation. The DNA that encodes the ribosomal RNAs constitutes the only major class of cloned nuclear repetitive DNA. It consists of approximately 570 tandem copies of a heterogeneous 9900-base-pair repeat unit. There is an average of approximately 660 copies of the chloroplast genome per cell. Therefore, the chloroplast genome constitutes the major component of the repetitive sequences found in A. thaliana DNA made from whole plants. The inner cytosine residue in the sequence C-C-G-G is methylated more often than the outer in the tandem ribosomal DNA units, whereas very few differences in the methylation state of these two cytosine residues are detected in unique sequences.

An under-methylated region in the spacer of ribosomal RNA genes of Lilium henryi

Ribosomal RNA genes of Lilium henryi are almost completely methylated at CG and CNG sequences. A short under-methylated region was detected between 2.05 and 2.4 kbp upstream of the 18S sequences. It included the only sites of digestion by four methylation-sensitive restriction endonucleases - PstI, Hae II, Eco RII and Hpa II. Only about 15%-20% of rDNA repeats from shoot meristem are susceptible to each of the enzymes. The same repeats are apparently cut by all enzymes and occur in contiguous blocks. Because the region involved is likely to include regulatory sequences it may be that under-methylation occurs specifically in active rDNA repeats. To test this, rDNA was examined from pollen mother cells at pachytene where transcription has fallen to near zero. Under-methylation levels here were similar to those in shoot meristem tissue. Thus methylation of this region is not the agent responsible for rDNA gene inactivation in pachytene cells and it does not occur immediately genes become inactive. Even so, sequences in this region might be prevented from becoming methylated in transcribing repeats.

Methylation Pattern of Radish (Raphanus sativus) Nuclear Ribosomal RNA Genes

The methylation pattern of radish Raphanus sativus nuclear rDNA has been investigated using the Hpa II, Msp I, and Hha I restriction enzymes. The presence of numerous target sites for these enzymes has been shown using cloned rDNA fragments. A large fraction of the numerous rDNA units are heavily methylated, being completely resistant to Hpa II and Hpa I. However, specific sites are constantly available in another fraction of the units and are therefore unmethylated. The use of different probes allowed us to demonstrate that hypomethylated sites are present in different regions. Major hypomethylated Hha I sites have been mapped in the 5' portion of 25S rRNA coding sequence. Among the hypomethylated fraction, different methylation patterns coexist. It has been possible to demonstrate that methylation patterns are specific for particular units. The Hha I pattern of rDNA in tissues of different developmental stages was analyzed. Evidence for possible tissue specific differences in the methylation pattern is reported.