A study of foldback DNA

A novel family of repeat sequences in the mouse genome responsive to retinoic acid

Repetitive DNA sequences form a substantial portion of eukaryotic genomes and exist as members of families that differ in copy number, length, and sequence. Various functions, including chromosomal integrity, gene regulation, and gene rearrangement have been ascribed to repetitive DNA. Although there is evidence that some repetitive sequences may participate in gene regulation, little is known about how their own expression may be regulated. During the course of gene trapping experiments with embryonic stem (ES) cells, we identified a novel class of expressed repetitive sequences in the mouse, using 5' rapid amplification of cDNA ends-polymerase chain reaction (5' RACE-PCR) to clone fusion transcripts from these lines. The expression of these repeats was induced by retinoic acid (RA) in cultured ES cells examined by Northern blot analyses. In vivo, their expression was spatially restricted in embryos and in the adult brain as determined by RNA in situ hybridization. We designated this family of sequences as Dr (developmentally regulated) repeats. The members of the Dr family, identified by cDNA cloning and through database search, are highly similar in sequence and show peculiar structural features. Our results suggest the expression of Dr-containing transcripts may be part of an ES cell differentiation program triggered by RA.

Structure and evolution of a family of interspersed repetitive DNA sequences in Caenorhabditis elegans

The structure of three members of a repetitive DNA family from the genome of the nematode Caenorhabditis elegans has been studied. The three repetitive elements have a similar unitary structure consisting of two 451-bp sequences in inverted orientation separated by 491 bp, 1.5 kb, and 2.5 kb, respectively. The 491-bp sequence separating the inverted 451-bp sequences of the shortest element is found adjacent to one of the repeats in the other two elements as well. The combination of the three sequences we define as the basic repetitive unit. Comparison of the nucleotide sequences of the three elements has allowed the identification of the one most closely resembling the primordial repetitive element. Additionally, a process of co-evolution is evident that results in the introduction of identical sequence changes into both copies of the inverted sequence within a single unit. Possible mechanisms are discussed for the homogenization of these sequences. A direct test of one possible homogenization mechanism, namely homologous recombination between the inverted sequences accompanied by gene conversion, shows that recombination between the inverted repeats does not occur at high frequency.

Characterization of inverted repeated sequences in Ascaris nuclear DNA

The inverted repeated sequences of the chromatin-eliminating nematode Ascaris lumbricoides var. suum have been examined by electron microscopy and by hydroxyapatite chromatography, both in the germ-line and in the somatic DNA. 38% of the inverted repeats of the germ-line DNA analysed in the electron microscope have a single-stranded loop, in comparison to about 50% of looped structures in the somatic DNA. The loops are on average 2.3 X 10(3) base pairs (bp) long. The rest of the foldback DNA consists of simple hairpins. The average length of looped and unlooped inverted repeats is of the order of 300-400 bp in the germ-line and in the somatic DNA. The content of S1-resistant foldback duplexes isolated by hydroxyapatite chromatography amounts to 1.3% in spermatids, with an average length of 350 bp, and to 1.1% in intestinal or larval cell nuclei, with a length of about 320 bp. We estimate by two different methods that there exist approximately 12500 inverted repeats per haploid germ-line genome and approximately 8000 in the haploid somatic genome. A statistical analysis of the data indicates that the great majority of the foldback sequences are randomly distributed in the Ascaris genome, with a spacing of about (40-80) X 10(3) bp, both in the germ-line and in the somatic DNA.

Characterization of highly and moderately repetitive 500 bp Eco RI fragments from Xenopus laevis DNA

Three different types of repetitive Eco RI fragments, which comigrate within a visible band of approximately 500 bp at gel electrophoresis of Xenopus laevis DNA Eco RI digests have been cloned and sequenced. These sequences are designated as Repetitive Eco RI Monomers: REM 1, REM 2 and REM 3. The sequences contain direct repeats, inverted repeats and palindromic elements. Genomic organization of the most abundant sequence (REM 1; 0.4% of total DNA) is that of an interspersed sequence. REM 2 (0.08%) is partly organized as an interspersed element and partly found in tandem arrangement, whereas REM 3 (0.02%) represents the tandemly repeated monomeric unit of a satellite DNA. In situ hybridization has shown that REM 1 and REM 2 sequences are found on most chromosomes, REM 1 being preferentially located on specific chromosomal loci. REM 3 is located near the centromere region of only one chromosome pair (presumably number 1). Hybridization of Northern blots from RNAs of different developmental stages revealed that REM 1, REM 2 and REM 3 sequences are transcribed and that transcription is under developmental control.

Organization and evolution of repeated DNA sequences in closely related plant genomes

In common with many other eukaryotic species, the genomes of species in the genus Allium contain a high proportion of repeated DNA sequences, which may be implicated in the considerable differences in genome size that are seen between even very closely related species. The gross organization of repetitive sequences within the genome of Allium sativum and of some other related species has been investigated using DNA/DNA hybridization studies. Such studies show that there has been much modulation in the amounts of different repeated DNA families during the evolution of the genus Allium; these repetitive elements are interspersed in all species with sequences of low repetition. The organization and distribution of one particular repetitive family within the genus has been examined using a cloned hybridization probe. Hybridization of this probe to DNA from related genomes reveals that this element is present in all Allium species examined, but with large-scale modulation of its abundance, and some considerable changes in its sequence environment. The evolution of such genome-specific arrangements of common repetitive elements and the possible mechanisms by which they might be maintained are discussed.

Tandemly repeated DNA sequences from Xenopus laevis. II. Dispersed clusters of a 388 base-pair repeating unit

A repetitive DNA sequence family from Xenopus laevis that has an unusual genomic organization has been identified. It has been shown by blot-hybridization that this sequence occurs in clusters containing variable numbers of the 388 base-pair repeating unit. There are approximately 500 such clusters in the genome, and each cluster has common flanking sequences. The number of tandem 388 base-pair repeats per cluster ranges from one to at least 15, with a mean of seven. Homologous sequences were found in two related species, Xenopus borealis and Xenopus mulleri, where the size of the repeating units and their genomic arrangement are very similar to those in X. laevis. The complete nucleotide sequence of a cloned representative 388 base-pair repeating unit showed no short internal repeats and no long reading frames. By blot-hybridization, no evidence of transcripts of this sequence was found in total RNA from X. laevis liver, embryos or oocytes.

Structure and distribution of inverted repeats (Palindromes). I. Analysis of DNA of Drosophila melanogaster

The size and distribution of renatured inverted repeats (palindromes) in D. melanogaster DNA were studied by electron microscopy (EM). The results of these studies differ from the previously published observations regarding the number, distribution and the size of inverted repeats (ir) present in DNA. -1. In contrast to the previous published observation almost all (96%) of the ir were found in crowded clusters. The DNA strands with clustered palindromes contained 2-21 palindromes (4-42 ir), with an average of 7.25 palindromes (14.5 ir) per strand. No correlation could be found between the length of the DNA strands and the number of ir per strand. -2, Also contrary to some previously published results, most (80%) of the ir formed on renaturation unlooped palindromes and these were always clustered. Looped palindromes (hairpins, formed by renaturation of ir separated by a non-homologous sequence long enough to be seen in EM as single-stranded loop) were found 1-2 per DNA strand, as part of clusters or as solitary palindromes in a DNA strand. The average spacing length (inside clusters) between centers of all palindromes was 2.349 kb, and between centers of looped palindromes 7.6 kb. - 3. The length of the ir was found to be smaller than documented in most of the previously published results. The majority, 80-90%, of the ir found in the unlooped and looped palindromes, respectively, belonged to one main-size class with a range of 30-210 bp and an average length of 100 bp, but longer ir were also observed. The average length of the ir in unlooped palindromes was 124 bp, in looped 244 bp, and the total average was 148 bp - 4. It was calculated that there are about 30,000 palindromes (60,000 ir) in the D, melanogaster genome, of which about 24,000 are unlooped and 6,000 looped, with the spacing between centers of all palindromes averaging about 4.4 kb in length.

Unusual structure of the FB family of transposable elements in Drosophila

We have analyzed the construction of the members of the foldback (FB) family of transposable elements in Drosophila by detailed restriction analysis, cross hybridization, electron microscopy, in situ hybridization and nucleotide sequence determination. The members are heterogeneous, with both the inverted terminal repeats and the total element sizes extremely variable. Nevertheless, the ends of the inverted repeats represent closely conserved sequences, similar for all members. Sequence analysis of one of the FB elements revealed an unusual constriction. There are scattered multiple copies of a 10 bp sequence near the inverted repeat termini; 300 bp from the end this sequence is expanded to a 20 bp repeat, and 500 bp from the end it is again expanded to a 31 bp repeat. A large part of the inverted repeats consists of contiguous tandem repeats of this 31 bp sequence. We also find two differences between the two copies of the inverted repeat, one of which involves an intact copy of the 10 bp sequence mentioned above. Sequence analysis of a corresponding DNA segment without this transposable element shows that insertion generates a 9 bp duplication at the target site. In situ hybridizations to polytene chromosomes show about 30 widely scattered positions with homology. Comparison of the hybridization patterns for three strains shows significant interstrain and intrastrain differences in chromosomal locations.

General occurrence and transcription of intervening sequences in mouse genes expressed via polyadenylated mRNA

cDNA of modal size approximately 1600 nucleotides, transcribed from mouse brain polyadenylated mRNA, was annealed with excess of high molecular weight (approximately kb) genomic DNA. The S1 nuclease method was then applied to determine possible sequence discontinuity between the cDNA and genomic DNA. A substantial reduction in the average size of the annealed cDNA was observed following S1 nuclease treatment. Large single copy genomic DNA, annealed with excess high molecular weight DNA, and cDNA, hybridized with its template mRNA, were resistant to cleavage by S1 nuclease. We interpret these results to indicate a high frequency of discontinuous coding sequences in the genomic DNA that annealed with the cDNA. The same result was obtained using fractionated cDNA, enriched in transcripts of relatively infrequent or abundant mRNA species. The result obtained with the infrequent sequence class cDNA indicates that tens of thousands of split genes exist in the mouse genome. Extensive cleavage of the cDNA by S1 nuclease was also observed after hybridization with greater than 30S nuclear RNA, indicating that intervening sequences are generally transcribed.

A detailed comparison of the 5'-end of the ovalbumin gene cloned from chicken oviduct and erythrocyte DNA

We have examined homologous fragments of DNA cloned from two different tissues for changes in the dNA sequence which might be related to tissue specific gene expression. The 5' end of the chicken ovalbumin gene was cloned from oviduct or erythrocyte DNA DNA using cosmids as vectors. We have compared the two clones obtained by restriction enzyme digestions, analysis of heteroduplexes by electron microscopy or S1 nuclease digestion and by DNA sequencing. Our results show that whereas no alteration occured in the region of the gene assumed to be of importance for the control of transcription, a 4 nucleotide deletion/insertion was detected in the first intron of the ovalbumin gene.

Plasmid cloning vectors that can be nicked at a unique site

We describe ColEl-type plasmids, with relaxed DNA replication, based on pMB9, and carrying the CmR determinant of R1, in addition to the TcR determinant of pMB9. One of the plasmids, pPH207, has unique sites for EcoRI, HindIII, BamI, SalI and HpaI. Insertion of foreign DNA into all but the last of these inactivates either the CmR or the TcR determinant. The original CmR TcR plasmid (pCM2) contains a copy of IS1 which produces deletions to left and to right. Most of these inactivate either the CmR or the TcR determinant. An internal 280 bp deletion of IS1 DNA in pPH207 greatly reduces the frequency at which deletions are observed. The main feature of these plasmids is a site that is cleaved by some preparations of EcoRI in only one strand of the DNA duplex (the EcoRIn site). This site facilitates strand separation of sequences inserted at the HindIII, BamI and SalI sites of the TcR gene, and also of any inserted at the true EcoRI site by a method that destroys that site. Since the orientation of the EcoRIn site is known, the orientation of sequences inserted at the neighbouring sites can be easily determined. Plasmid pPH207 is not mobilised by a Hfr, but its mobilisation is promoted by ColEl. It is therefore Mob- bom+. Experiments with minicells show that it directs the copious synthesis of chloramphenicol transacetylase.

Repetitive DNA sequences near three human beta-type globin genes

Five repetitive DNA sequences, of average length 259 bp, have been identified in the intergenic regions which flank three human beta-tupe globin genes. A pair of inverted repeat sequences, separated by 919 bp, was found 1.0 kb to the 5' side of the epsiln-globin gene. Each contains a homologous Alu I site. Another repetitive sequence, with the same orientation as the inverted repeat sequence closest to the epsilon-globin gene, lies about 2.2 kb to the 5' side of the delta-globin gene. A pair of inverted repeat sequences, with the same relative orientations as the other pair and separated by about 800 bp, was found about 1.5 kb to the 3' side of the beta-globin gene.

Deoxyribonucleic acid sequence organization in the genome of the dinoflagellate Crypthecodinium cohnii

Details of the general DNA sequence organization in the dinoflagellate Crypthecodinium cohnii have been obtained by using hydroxylapatite binding experiments, S1 nuclease digestion .and electron microscopy of reassociated DNA. It has been found that roughly half of the genome is made up of unique sequences interspersed with repeated sequence elements with a period of approximately 600 nucleotides. This class represents roughly 95% of the total number of interspersed unique elements in the genome. The remaining 5% are uninterrupted by repeated sequences for at least 4000 nucleotide pairs. The interspersed repeated elements are narrowly distributed in length with 80% under 300 nucleotide pairs in length. About half of the repeated DNA (20-30% of the genome) is not interspersed among unique sequences. The close spacing of the short repeats interspersed throughout much of the genome is consistent with the occurrence of the huge network structures observed in the electron microscope for low Cot reassociation of moderately long fragments. An unusual class of heteroduplexes was detected in the electron microscope which is believed to derive from the reassociation of repeated sequences from different families which are frequently found adjacent to one another in different locations in the genome. The occurrence of this novel arrangement of repeated sequences may reflect the unusual organization of the dinoflagellate nucleus. However, in most respects the sequence arrangement in this unicellular alga is very typical of higher plants and animals.

The organization of repetitive sequences in a cluster of rabbit beta-like globin genes

Several complementary procedures were used to identify and characterize DNA sequences which are repeated within a 44 kilobase (kb) segment of rabbit chromosomal DNA containing four different rabbit beta-like globin genes (beta 1-beta 4). Cross-hybridization between cloned DNAs from different regions of the gene cluster indicates the presence of a complex array of repeat sequences interspersed with the globin genes. We classified 20 different repeat sequences into five families whose members cross-hybridize. Electron microscopy was used to determine the location, size and relative orientations of many of the repeat sequences. Both direct and inverted repeats were identified, with sizes ranging from 140 to 1400 base pairs (bp). Each of the four closely linked globin genes is flanked by at least one pair of inverted repeats of 140-400 bp, and the entire set of four genes is flanked by an inverted repeat of 1400 bp. Two of the five repeat families contain repeat sequences of different sizes. We found that the smaller sequence elements can occur individually or in association with the larger repeat sequences, suggesting that the larger repeats may be composed of more than one smaller repeat sequence. The restriction fragments containing the intracluster repeats also contain sequences which are repeated many times in total rabbit genomic DNA, but it is not known whether the genomic and intracluster repeats are the same sequences. The results provide the first demonstration of the relationship between single-copy and repetitive DNA sequences in a large segment of chromosomal DNA containing a well characterized set of developmentally regulated genes.

The sequence organization of bovine DNA

The organization of repetitive DNA sequences has been investigated in bovine DNA. Repetitive sequences of all kinds constitute 25% to 30% of the total. Five density satellites constitute about 20% of the genome, and most of the remainder consists of alternating repeating and nonrepeating sequences. The nonrepeating sequences have a very broad size distribution averaging 4,000 nucleotide paris in length with the longest exceeding 10,000 nucleotide pairs. The interspersed repetitive sequences are much more nearly homogeneous in size, averaging 350 nucleotide pairs in length, and are divided into 8 to 14 sequence families.

Organisation of inverted repeat sequences in hamster cell nuclear DNA

Hamster cell nuclear DNA is shown to contain inverted repeat (foldback) sequences, in some respects similar to the foldback fraction in DNA from other animal cell types. Using electron microscopy the majority of foldback duplexes are shown to be located in simple hairpin-like DNA structures, formed from individual pairs of complementary inverted repeated sequences 50--1000 nucleotides in length, in some cases arranged in tandem, and in other cases separated by intervening sequences, up to 16000 nucleotide residues long. In addition, a novel class of foldback structure, referred to as 'bubbled hairpins' is reported, which appear to be formed from clusters of inverted repeat sequences that are separated from adjacent clusters of complementary inverted repeats by large intervening sequences which vary in length from 5000 to over 20000 nucleotide residues. Due to the special pattern of distribution of these latter inverted repeat sequences, 'bubbled hairpins' are observed only in long foldback DNA. Evidence is presented that the distribution of foldback sequences in hamster cell DNA is highly ordered. The lengths of the intervening single chains in foldback structures appear to vary non-randomly. This gives rise to a localised periodic pattern of organisation that is believed to be a consequence of regular alternating arrangements of foldback and non-foldback sequences in the segments of DNA from which foldback structures are derived.

Distribution of polypyrimidine . polypurine segments in DNA from diverse organisms

Polypyrimidine . polypurine segments are regions of duplex DNA which contain a highly asymmetric distribution of pyrimidine and purine nucleotides. A polypyrimidine in single-stranded DNA can be detected by its ability to form a complex and poly(A, G) which will bind to hydroxyapatite. We tested DNA from a variety of organisms and found that most contained polypyrimidines. From the shape of the curve relating DNA size to percentage bound to hydroxyapatite, we conclude that polypyrimidine . polypurine segments occur widely in DNA from higher organisms, at intervals of 6000--8000 base pairs throughout the majority of the genome. Lower levels occur in DNA from yeast and Drosophila.

Distribution pattern and enzymic hypermethylation of inverted repetitive DNA sequences in P815 mastocytoma cells

A specific class of DNA sequences, the inverted repetitive sequences, forms a double-stranded structure within a single linear polynucleotide chain in denatured DNA. The reassociation process is unimolecular and occurs very fast. Quantitative analyses have shown that in mouse P815 cells these sequences comprise about 4% of the nuclear DNA and are interspersed within sequences of other degrees of repetitiveness. After labeling the cells with L-[Me-3H]methionine and [14C]deoxycytidine, relative rates of enzymic DNA methylation were computed on the basis of radioactivities found in pyrimidine residues of the nuclear DNA. The results indicate that in P815 cells, DNA of inverted repetitive sequences is methylated to a level about 50% higher than the normal repetitive DNA sequences and to about 300% higher than the unique and intermediary intermediatry sequences. The biological function of the inverted repetitive sequences, as well as of the role of enzymic methylation of DNA remains unknown.

An analysis of cytoplasmic RNA populations in Drosophila melanogaster, Oregon R

Nucleic acid reassociation methods were used to estimate the number of different polyadenylated RNA [poly (A) + RNA] sequences in the cytoplasm of whole Drosophila melanogaster at different stages of development and in the cytoplasm of cells of the L3 cell line. The number-average length (LN) of poly (A) + RNA from L3 cells is 1.4 kb, and the steady-state LN of the poly (A) tracts is 70 nucleotides. Analysis of RNA-driven reassociation with copy DNA shows that the poly (A) + RNA from L3 cells contains 5200 different sequences distributed in three abundance classes. The RNA forms hybrid duplexes with about 4.5% of single-copy Drosophila DNA, corresponding to 6500 sequences of 1.4 kb. The LN of poly (A) tracts present in whole embryos, larvae, pupae, and imagos is in each case close to 70 nucleotides. RNA-driven reassociation experiments show that poly (A) + RNA from these sources contains, respectively, 3500, greater than or equal to 4900, 6900, and greater than or equal to 4900 sequences. Cross-hybridization reactions show extensive homology between these RNA populations. All five poly (A) + RNA preparations contain a prominent component with a sedimentation coefficient of 13 and a size of 1.78 kb, which is shown to be the larger species of mitochondrial rRNA. This rRNA binds to oligo (dT) cellulose and serves as an efficient template for cDNA synthesis by reverse transcriptase. In RNA-driven reassociation experiments it behaves like an abundant mRNA.

Yeast chromosomal DNA molecules have strands which are cross-linked at their termini

The microbial eukaryote Saccharomyces cerevisiae has 18 chromosomes, each consisting of a DNA molecule of 1 x 15 x 10(8) daltons (150 to 2,300 kilobase pairs). Interstand cross-links have now been found in molecules of all sizes by examining the ability of high molecular weight DNA to snap back, i.e., to rapidly renature after denaturation. Experiments in which snap back was assessed for molecules broken by shearing indicate that there are probably two cross-links in each chromosome. Evidence that the cross-links occur at specific sites in the genome was obtained by treating total chromosomal DNA with the endonuclease EcoRI which cleaves the yeast genome into approximately 2,000 discrete fragments. Cross-link containing fragments were separated from fragments without cross-links. This purification resulted in enrichment for about 18 specific fragments. To determine whether the cross-links are terminal or at internal sites in chromosomal DNA, large shear-produced fragments were examined by electron microsopy. With complete denaturation few fragments exhibit the X-shaped single strand configuration expected for internal cross-links. When partially denatured fragments were examined some ends had single strand loops as expected for (AT-rich) cross-linked termini. We propose that a duplex chromosomal DNA molecules have cross-linked termini. We propose that a duplex chromosomal DNA molecule in this eukaryote consists of a continuous, single, self-complementary strand of DNA. This structure has implications for the mechanism of chromosome replication and may be the basis of telomere behavior.

Genome structure of Tetrahymena pyriformis

Reassociation kinetics of DNA from the macronucleus of the ciliate, Tetrahymena pyriformis GL, has been studied. The genome size determined by the kinetic complexity of DNA was found to be 2.0 X 10(8) base pairs (or 1.2 X 10(11) daltons). About 90% of the macronuclear DNA fragments 200-300 nucleotides in length reassociate at a rate corresponding to single-copy nucleotide sequences, and 7-9% at a rate corresponding to moderate repetitive sequences; 3-4% of such DNA fragments reassociate at C0t practically equal to zero. To investigate the linear distribution of repetitive sequences, DNA fragments of high molecular weight were reassociated and reassociation products were treated with S1-nuclease. DNA double-stranded fragments were then fractionated by size. It has been established that in the Tetrahymena genome long regions containing more than 2000 nucleotides make up about half of the DNA repetitive sequences. Another half of the DNA repetitive sequences (short DNA regions about 200-300 nucleotides long) intersperse with single-copy sequences about 1,000 nucleotides long. Thus, no more than 15% of the Tetrahymena genome is patterned on the principle of interspersing single-copy and short repetitive sequences. Most of the so called "zero time binding" or "foldback" DNA seem to be represented by inverted self-complementary (palindromic) nucleotide sequences. The conclusion has been drawn from the analysis of this fraction isolated preparatively by chromatography. About 75% of the foldback DNA is resistant to S1-nuclease treatment. The S1-nuclease resistance is independent of the original DNA concentration. Heat denaturation and renaturation are reversible and show both hyper- and hypochromic effects. The majority of the inverted sequences are unique and about 20% are repeated tens of times. According to the equilibrium distribution in CsCl density gradients the average nucleotide content of the palindromic fraction does not differ significantly from that of total macronuclear DNA. It was shown that the largest part of this fraction of the Tetrahymena genome are not fragments of ribosomal genes.

Prevention of G:C pairing in mouse DNA by complete blocking of guanine residues with glyoxal. Availability of cytosine, adenine and thymine for hydrogen bonding with added unmodified polynucleotides

We have developed conditions for the reaction of single-stranded DNA with glyoxal which permit blocking of essentially all guanine residues. This procedure effectively prevents base pairing involving these guanine residues, yet permits cytosine, thymine and adenine residues in the DNA to pair with added polynucleotides. Modification of DNA with glyoxal greatly reduces intrastrand helical regions, resulting in a very low binding to hydroxyapatite, as compared to unmodified DNA. Annealing of modified DNA with some synthetic polynucleotides of restricted composition (but not others) leads to a significant increase in binding, presumably because mouse DNA has sequences not containing guanine which are capable of hydrogen bonding to the added polynucleotides. This relatively simple procedure may allow isolation and further study of these guanine-free sequences in DNA.

Some aspects of the basic mechanisms of chemical carcinogenesis

An extended summary is presented of current progress in research on the basic mechanism of chemical carcinogenesis conducted in the Division of Biophysics, School of Hygiene and Public Health, at the Johns Hopkins University. The first section concerns the involvement of free radicals in benzo[a]pyrene metabolism and carcinogenesis, the second the relationship between neoplastic transformation and somatic mutation, and the third the changes in DNA sequence organization and gene expression in neoplastic transformation.

Characterization of foldback sequences in Physarum polycephalum nuclear DNA using the electron microscope

An examination of the foldback fraction of nuclear DNA from Physarum polycephalum has been carried out using the electron microscope. Results show that the inverted repeat sequences responsible for the formation of foldback DNA range from 150-3000 bases in length, with a number-average size of 340 bases. About one-half of the inverted sequences form looped structures with loop sizes averaging 1200 bases in length. The distance between adjacent foldback sequences is estimated to be in the range 100-1500 bases.

Sequence arrangement of the rDNA of Drosophila melanogaster

The sequence arrangement of genes coding for stable rRNA species and of the interspersed spacers on long single strands of rDNA purified from total chromosomal DNA of Drosophila melanogaster has been determined by a study of the structure of rRNA:DNA hybrids which were mounted for electron microscope observation by the gene 32-ethidium bromide technique. One repeat unit contains the following sequences in the order given. First, an 18 S gene of length 2.13 +/- 0.17 kb. Second, an internal transcribed spacer (Spl) of length 1.58 +/- 0.15 kb. A short sequence coding for the 5.8S and perhaps the 2S rRNA species is located within this spacer. Third, the 28S gene with a length of 4.36 +/- 0.23 kb. About 55% of the 28S genes are unbroken or continuous (C genes). However, about 45% of the 28S genes contain an insertion of an additional segment of DNA that is not complementary to rRNA (l genes). The insertion occurs at a reproducible point 2.99 +/- 0.26 kb from the junction with Spl. The insertions are heterogeneous in length and occur in three broad size classes: 1.42 +/- 0.47, 3.97 +/- 0.55, and 6.59 +/- 0.62 kb. Fourth, an external spacer between the 28S gene and the next 18S gene which is presumably mainly nontranscribed and which has a heterogeneous length distribution with a mean length and standard deviation of 5.67 +/- 1.92 kb. Short inverted repeat stems (100-400 nucleotide pairs) occur at the base of the insertion. It is known from other studies that I genes occur only on the X chromosome. The present study shows that the I and C genes on the X chromosomes are approximately randomly assorted. The sequence arrangement on the plasmid pDm103 containing one repeat of rDNA (Glover et al., 1975) has been determined by similar methods. The I gene on this plasmid contains an inverted repeat stem. The occurrence of inverted repeat sequences flanking the insertion supports the speculation that these sequences are translocatable elements similar to procaryotic translocons.

Characterization of foldback sequences in hamster DNA using electron microsocpy

Foldback sequences in nuclear DNA from cultured Hamster fibroblasts (BHK-21/C13 cells) have been characterized by electron microscopy. One half of the structures observed when denatured hamster DNA is allowed to anneal in the range O less than Cot1 less than 1 x 10(-4) M sec result from the annealing of inverted sequences forming foldback DNA. The remainder have a probable bimolecular origin. arising from rapidly-annealing sequences of satellite-like complexity. The average length of the inverted sequences in the foldback molecules is about 0.9 kilobases. There is estimated to be about 42,000 such sequences (21,000 pairs) in the hamster genome, approximately 45% of which form looped structures with a mean loop length of 1.74 kilobases. Contrary to previous reports, binding of the renatured duplex molecules to hydroxyapatite results in a poor recovery of structures containing identifiable foldback sequences, due to preferential enrichment of the bound fraction with duplexes formed by intermolecular annealing.