Underwound loops in self-renatured DNA can be diagnostic of inverted duplications and translocated sequences

Mitochondrial DNA from Podospora anserina : IV. The large ribosomal RNA gene contains two long intervening sequences

We have examined the structure of the rRNA genes from the mitochondrial genome of Podospora anserina. Using R-loop analysis, nuclease protection experiments, and Southern blot hybridization analysis we have observed two intervening sequences (IVS) in the large rRNA gene, and none in the small rRNA gene. the IVS sequences are 1.65 kbp and 2.73 kbp long, and the larger of the two is in the position of the conserved IVS found in the mitochondrial genomes of other fungi. We have detected precursor transcripts for the large rRNA, and these data support the observation of two IVS in this gene. We also note that the large and small rRNA genes are separated by approximately 6 kbp of DNA.

Alternative structures in duplex DNA formed within the trinucleotide repeats of the myotonic dystrophy and fragile X loci

Most models proposed to explain the disease-associated expansion of (CTG)n.(CAG)n and (CGG)n.(CCG)n trinucleotide repeats include the formation of slipped strand DNA structures during replication; however, physical evidence for these alternative DNA secondary structures has not been reported. Using cloned fragments from the myotonic dystrophy (DM) and fragile X syndrome (FRAXA) loci containing normal, premutation, and full mutation lengths of repeats, we report the formation of novel alternative DNA secondary structures that map within the repeat tracts during reannealing of complementary strands, containing equal lengths of repeats, into linear duplex DNA molecules. Linear duplex DNA molecules containing these alternative DNA secondary structures are characterized by reduced electrophoretic mobilities in polyacrylamide gels. These alternative secondary structures are stable at physiological ionic strengths and to temperatures up to at least 55 degrees C. Following reduplexing, the CAG strand of the (CTG)n.(CAG)n repeats is preferentially sensitive to mung bean nuclease, suggesting the presence of single-stranded DNA in the alternative DNA structure. For (CTG)17, which is a repeat length found in normal individuals, less than 3% of the DNA molecules formed alternative DNA structures upon reduplexing. DNA molecules containing (CTG)50 or (CTG)255, which represent premutation and full mutation lengths of triplet repeats, respectively, formed a heterogeneous population of alternative DNA structures in >50% of DNA molecules. The complexity of the structures formed increased with the length of the triplet repeat. The relationship between repeat length and the propensity of formation and complexity of the novel structures correlates with the effect of repeat length on genetic instability in human diseases. These are the first results consistent with the existence of slipped strand DNA structures. The potential involvement of these structures, which we term S-DNA, in the gentic instability of triplet repeats is discussed.

Intrahelical pseudoknots and interhelical associations mediated by mispaired human minisatellite DNA sequences in vitro

The human minisatellite arrays, 33.6 and 33.15, consist of tandem reiterations of a 37-nucleotide (nt) and a 16-nt repeat unit sequence, respectively, both of which contain a majority of purine bases on one strand. Knot-like tertiary structures, which mapped to the cloned arrays, were observed by electron microscopy (EM) in homoduplex molecules produced by denaturation and reannealing in vitro. They result from a primary hybridization between misaligned repeat units of the array, forming a slipped-strand structure with staggered single-stranded DNA loops, followed by a secondary hybridization between repeat units in the two loops. Depending on the relative alignment of the loops when they hybridize, a particular form of intrahelical pseudoknot is produced. Theta-shaped, figure-of-eight, and bow-shaped structures were the most common conformational isomers observed in homoduplexes flattened into two dimensions during EM preparation. At the site of a bow-shaped structure, a conformation-dependent bend of approximately 60 degrees between the flanking DNA segments is induced; the other conformations generally do not deflect the line of the main DNA axis. Paired loops, similar to the bow-shaped structure, were apically situated in some supercoiled plasmids containing the 33.6 array. Both plasmids formed intermolecular associations, consisting of two (or more) homoduplex molecules held together at or immediately adjacent to a nexus which mapped to the minisatellite sequences. These associations might arise either by interhelical hybridization between arrays or by knot-like structures interfering with branch migration of chi-form Holliday junctions.

DNA tertiary structures formed in vitro by misaligned hybridization of multiple tandem repeat sequences

DNA tertiary structures are shown to be formed by denaturation and reannealing in vitro of molecularly-cloned DNA containing multiple tandem repeat sequences. Electron microscopy of homoduplex DNA molecules containing the human c-Harvey-ras gene revealed knot-like structures which mapped to the position of the 812 bp variable tandem repeat (VTR) sequence. We propose that the structures result from slipped-strand mispairing within the VTR and hybridisation of homologous repetitive sequences in the single-stranded loops so produced. Similar structures were also found in freshly-linearized supercoiled plasmids. More complex knot-like structures were found in homoduplexes of a 4 kb tandem array from the hypervariable region 3' to the human alpha-globin locus. Formation of such DNA tertiary structures in vitro also provides a practical method for identifying and mapping direct tandem repeat arrays that are at least 800 bp long.

Linear adenovirus DNA is organized into supercoiled domains in virus particles

Electron microscopic analysis of bis-psoralen crosslinked adenovirus type 5 virion DNA revealed supercoiled domains in an otherwise linear DNA. The existence of supercoiled arrangement in all the virion DNA was demonstrated by the sensitivity of Ad5 DNA in pentonless virus particles to the supercoiling-dependent endonucleolytic activity of Bal31 and S1 nucleases. These nucleases were found to cleave Ad5 virion DNA at specific sites. The observation of stable cleavage sites in the limit digestion of virion DNA by Bal31 suggests that cleavage sites represent boundaries of core proteins which impede the exonuclease activity of Bal31. These data suggest that specific arrangement of core proteins on Ad5 virion DNA. Based on this analysis we determined positions of core proteins in viral genome using indirect end labeling technique. The size of supercoiled domains of virion DNA was estimated by electron microscopy and also by boundaries of mutually exclusive Bal31 cleavage sites at limit digestion condition. Our data suggest each supercoiled domain is equal to about 12% of Ad5 genome length and about 8 loops can be accommodated in Ad5 virion. However sequences at two extreme ends of the viral genome were found to be outside of supercoiled domains. An interesting correlation between supercoiled domains and gene domains of Ad5 genome was noticed.

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.

The role of insertions, deletions, and substitutions in the evolution of R6 related plasmids encoding aminoglycoside transferase ANT-(2")

In 7% of gram-negative bacteria resistance to gentamicin is mainly mediated by plasmid-encoded aminoglycoside transferase ANT-(2"). The genome organization of 15 aadB plasmids (42-110 kb) was analyzed by restriction and hybridization techniques. They appeared to be IncFII-like replicons but were distinct from R6 by virtue of small substitutions in the transfer region. Aminoglycoside resistance genes aadB and aadA were located on Tn21 related elements. Only one of them was able to transpose its resistance genes mer sul aadA and aadB ( Tn4000 ), the other elements were naturally occurring defective transposons. In some of these structures deletions were identified at the termini, at sul, aadA , mer or transposition function--insertions adjacent to aadA or mer. The mode of these rearrangements and their site-specificity were considered with respect to the evolution of the Tn21 transposon family.

Aspects of the secondary and tertiary structure of DNA

DNA is the primary genetic material of most organisms. A wide variety of naturally occurring duplex DNA's are known to exist as covalently closed circles. This covalent continuity introduces a topological constraint, and consequently these molecules possess aspects of tertiary and even higher-order structure. Virtually every physical, chemical and biological property of DNA - its transcription, hydrodynamic behaviour, energetics, enzymology and so on - are related to these structural features. We describe the parameters describing the topology and conformation of covalently-closed, duplex DNA's (form I DNA's), the conservation relationship between them and its implications.

Analysis of four tobacco mitochondrial DNA size classes

Supercoiled mtDNAs were isolated from tobacco suspension culture cells and three of the smallest size classes (10.1, 20.2 and 30.3 kb) were characterized through denaturation, heteroduplex and restriction mapping. The 20.2 molecule was found to be a head-to-tail dimer of the 10.1 or X size class, while the 30.3 kb size class was found to contain two kinds of molecules, a head-to-tail trimer of X (X3) and a second molecule, ABC. X and ABC had a 118 +/- 35 bp region of homology, and both size classes shared a degree of homology with at least one other size class. Restriction maps of both the X and ABC molecules are presented and the possible origin and role of the many plant mtDNA size classes are discussed.

Characterization of plasmids in aminocyclitol-resistant Staphylococcus aureus: electron microscopic and restriction endonuclease analysis

Plasmid species isolated from aminocyclitol-resistant Staphylococcus aureus have been analyzed by restriction endonuclease digestion and electron microscopy. These plasmids can be divided into two interrelated groups; intergroup variability is due to the gain or loss of defined DNA sequences. Plasmids pSJ1 and pSJ24 are related to staphylococcal penicillinase plasmid pI524 which was first described over 20 years ago. Both pSJ1 and pSJ24 differ from pI524 by the acquisition of 8 and 4 kbp, respectively, and encode additional resistance to the antibiotics erythromycin and kanamycin. The gain of these resistance determinants suggests that the evolution of staphylococcal resistance plasmids parallels that observed for plasmids of gram-negative bacteria and has serious implications for the spread of antibiotic resistance among the staphylococci.

Molecular analysis of the human interferon-alpha gene family

Fifteen DNA clones containing sequences related to human interferon-alpha cDNA were isolated from a human chromosomal gene bank (Nagata et al., Nature 287 (1980) 401-408) and characterized by restriction mapping, R-loop and heteroduplex analysis. Nine distinct DNA segments hybridized strongly with interferon-alpha 1 cDNA and formed R-loops with poly(A) RNA from interferon-producing human leukocytes; most if not all of these segments represent functional interferon genes. Five segments hybridized weakly with the probe and did not form R-loops with the poly(A) RNA; one of these was characterized as an interferon-alpha pseudogene. Several DNA segments overlap and define a region of 36 kilobase pairs (kb) that contains three strongly and three weakly hybridizing sequences. From our data and those of Goeddel et al. (Nature 290 (1981) 20-25) we conclude that there exist at least 11 distinct genes of gene-like sequences of the interferon-alpha type in the human genome, of which most likely represents an allelic variant, and at least five pseudogenes distantly related to the interferon-alpha genes.

DNA electron microscopy

In recent years DNA electron microscopy has become a tool of increasing interest in the fields of molecular genetics and molecular and cell biology. Together with the development of in vitro recombination and DNA cloning, new electron microscope techniques have been developed with the aim of studying the structural and functional organization of genetic material. The most important methods are based on nucleic acid hybridizations: DNA-DNA hybridization (heteroduplex, D-loop), RNA-DNA hybridization (R-loop), or combinations of both (R-hybrid). They allow both qualitative and quantitative analysis of gene organization, position and extension of homology regions, and characterization of transcription. The reproducibility and resolution of these methods make it possible to map a specific DNA region within 50 to 100 nucleotides. Therefore they have become a prerequisite for determining regions of interest for subsequent nucleotide sequencing. Special methods have been developed also for the analysis of protein-DNA interaction: e.g., direct visualization of specific protein-DNA complexes (enzymes, regulatory proteins), and analysis of structures with higher complexity (chromatin, transcription complexes).

Unwinding and rewinding of DNA by the RecBC enzyme

Under physiological conditions the initial action of the RecBC enzyme (exonuclease V) on duplex DNA is unwinding of the DNA strands. We have examined by electron microscopy the initial products of this unwinding reaction. When such reactions are carried out in the presence of DNA binding protein, unwinding structures are seen both at the terminus of the duplex DNA and at locations remote from the ends of the DNA molecule. Both terminal and internal unwinding structures proceed along DNA at about 300 nucleotides per second, and the single-stranded loops in both types of structure enlarge at about 100 nucleotides per second. In the internal unwindings DNA must be rewound behind the enzyme at about 200 nucleotides per second. The structures do not occur on supercoiled or nicked circular DNA, indicating that free ends are needed for their formation. In the absence of DNA binding protein only internal unwinding structures are seen, suggesting that the internal structures are formed from the terminal unwindings by base-pairing of their unwound single-strand tails. We present a model which incorporates these structures and is consistent with previous observations on the unwinding and degradative actions of the enzyme. In this model the enzyme travels through duplex DNA by unwinding the DNA ahead of itself and rewinding it behind itself. The internal unwindings produced by the RecBC enzyme could be active in initial synapsis step in genetic recombination.

The structure of unstable constitutive revertants of mutant galOP-308::IS2-I

The isolation and characterization of three unstable and constitutive revertants of mutant galOP-308 of E. coli is described. In this mutant an IS2 element is integrated between the promoter and the first structural gene of the galactose operon, and exerts a strong polar effect on the expression of the three galactose genes. In the three revertants under investigation it was observed that relief of polarity and constitutive expression of the gal-operon were accompanied by the deletion of 90% of the IS2 sequence and of various lengths of the adjacent sequences including the gal-promoter. We conclude from this result that the transcription termination signals causing strong polarity were located on the deleted part of IS2, and that in our revertants the galactose genes are now under the control of a new promoter which is apparently unstable.

Electron microscopic observation of new transposable elements inserted into P22 phage genome from R plasmids

By using phage P22spl, a deletion mutant of phage P22, the structures of two new transposons on P22 genomes were studied by the electron microscopic heteroduplex method. One of these was the Cm (chloramphenicol) transposon derived from an R plasmid, NR1, and the other the Km (kanamycin) transposon frin obr502. the heteroduplex between P22 phage DNAs with and without the Cm transposon revealed that the Cm transposon was similar in structure to the Tn9 element, a well-known Cm transposon derived from the R plasmid pMS14. On the other hand, the Km transposon of pNR502 was quite different in structure from other Km transposons reported previously. This transposon consists of a 6.8 kilobase (kb) segment of DNA, in which a short inverted repeat is contained. The heteroduplex experiments showed that a 4.5 kb segment of DNA was deleted from the P22 genome in the P22spl genome. Because of a shorter unit length of the genome, phage P22spl is considered to be useful of assaying various kinds of transposable elements.

Tandem pentuplication of a DNA segment in a derivative of bacteriophage P2: its use in the study of the mechanism of DNA annealing

From a tandem duplication mutant of phage P2, triplication, quadruplication and pentuplication forms were derived. They were recognized by decreased virion heat stability resulting from the increase in DNA content, and were confirmed by electron microscope heteroduplex mapping. These forms of partially repeated DNA are quite stable in P2 because of the low level of recombination typical of this phage. Under conditions normally employed for full DNA renaturation, these high order repeat chromosomes gave often incomplete renaturation over the repeated segments. Based on current models for DNA renaturation, several predictions were made and tested. The results, although not quantitatively exhaustive, indicated that base pairing proceeding from a nucleation site was sufficiently slow to allow a second nucleation to occur with a fair probability over a length of a few thousand base pairs.

The structure and transcription of four linked rabbit beta-like globin genes

Rabbit chromosomal DNA contains a cluster of four linked beta-like globin genes arranged in the orientation 5'-beta 4-(8kb)-beta 3-(5 kb)-beta 2-(7-kb)-beta 1-3'. Determination of the nucleotide sequence of gene beta 1 confirms that this gene corresponds to the second type of two common co-dominant alleles encoding the adult beta-globin chain. With the exception of two nucleotide substitutions in the large intervening sequence (intron), the intron and flanking sequences are identical with the nucleotide sequence of the first type determined by Weissmann et al. (1979). A 14S polyadenylated transcript containing large intron sequences (possibly a mRNA precursor) is detected in the bone marrow cells of anemic rabbits. Gene beta 2 has limited sequence homology to adult and embryonic beta-globin probes and lacks a detectable mRNA transcript in the erythropoietic tissues examined. It contains at least one intervening sequence analogous to the large intron in gene beta 1. Genes beta 3 and beta 4 both contain an intron of 0.8 kb. Partial DNA sequence analysis indicates that the large intron in beta 4 is located between codons for amino acids lysine and leucine in an analogous position to that of the large intron in beta 1. In addition, a second smaller intron interrupts the 5' coding sequences of gene beta 4. Both genes beta 3 and beta 4 are transcribed in embryonic globin-producing cells. Their DNA sequence homology is limited, however, to a segment of approximately 0.2 kb located on the 5' side of the large intron.

Isolation of yeast histone genes H2A and H2B

Analysis of cloned sequences for yeast histone genes H2A and H2B reveals that there are only two copies of this pair of genes within the haploid yeast genome. Within each copy, the genes for H2A and H2B are separated by approximately 700 bp of spacer DNA. The two copies are separated from one another in the yeast genome by a minimum distance of 35-60 kb. Sequence homology between the two copies is restricted to the genes for H2A and H2B; the spacer DNA between the genes is nonhomologous. In both copies, the genes for H2A and H2B are divergently transcribed. In addition, both plasmids code for other nonhistone proteins. Sequences coding for histones H3 and H4 have not been detected in the immediate vicinity of the genes for H2A and H2B.

Physical mapping of Staphylococcus aureus penicillinase plasmid pI524: characterization of an invertible region

The staphylococcal penicillinase plasmid pI524 and a series of derivatives have been extensively mapped by restriction endonuclease digestion and by heteroduplex analysis. We report here the identification of a 2.2 kb region that undergoes a reversible, rec-independent inversion. This sequence is bounded by a pair of inverted repeats 650 base pairs in length, and has asymmetrically located recognition sites for at least three restriction endonucleases. A series of deleted derivatives and one naturally occurring, closely related plasmid, were studied. Two of these retain the inversion; the remainder are incapable of inverting and were all found to be locked in the same orientation of the inversion. The invertible sequence is adjacent to the region of the plasmid encoding beta-lactamase (bla); this entire region appears to be transposable and the inversion may be involved in the regulation of beta-lactamase expression or in translocation.

Heteroduplex electron microscopy of phage Mu mutants containing IS1 insertions and chloramphenicol resistance transposons

We have examined by electron microscopy the DNA heteroduplexes of six bacteriophage Mu mutants, Mu X cam, generated by the insertion of the Tn9 transposon for chloramphenicol resistance. Tn9 was found to be 2.8 +/- 0.2 kilobases (kb) in length and to consist of a cam determinant flanked by two IS1 sequences arranged in a direct order. In two of the six Mu X cam mutants, the Tn9 insertion was at a fixed location, 3.9 kb from the left, or c, end. In the other four mutants, the position of the insertion varied, even though the lysogenic cultures induced were grown from single colonies. The insertion was located at either 3.3 kb, 3.9 kb, or, less frequently, at 4.4 kb from the left end of the DNA. Furthermore, at low frequencies, the insertions were found to be in an orientation opposite to what predominated in the preparation. Thus, Tn9 in the Mu X cam mutants examined could appear to undergo rapid rearrangements during Mu growth or over a few generations of cell growth. One of the Tn9 insertion sites was apparently the same as that for a 0.8 kb insertion found in a Mu X mutant. This latter insertion was identified as an IS1 sequence. The DNA molecules from all the Mu X cam mutant phage particles were found to be missing the bacterial DNA at the S (right) end, along with a variable amount of the adjoining Mu DNA in the beta region. This observation supports the headful packaging model for Mu DNA.

Adjacent insertion sequences IS2 and IS5 in bacteriophage Mu mutants and an IS5 in a lambda darg bacteriophage

Using electron microscopic heteroduplex analysis, we have demonstrated that an insertion found in a Mu prophage and in some infectious. Mu deletion-substitution mutants derived from it consists of bacterial insertion sequence IS2 linked directly to IS5. Other infectious Mu mutants derived from the same lysogen have only IS5 or a portion of IS2. In addition, we have found that an independent insertion in a transducing phage, lambda 13 dargB2, is IS5. The ends of IS5 are short, inverted duplications of each other. These observations support the notion that the DNA insertion previously designated IS5 on the basis of a single example in lambda KH100 is a bona fide bacterial insertion sequence.