Structure of the Drosophila DNA topoisomerase II gene. Nucleotide sequence and homology among topoisomerases II

We have determined the nucleotide sequence of the Drosophila DNA topoisomerase II gene. Data from primer extension and S1 nuclease protection experiments were combined with comparisons of genomic and cDNA sequences to determine the structure of the mature messenger RNA. This message has a large open reading frame of 4341 nucleotides. The length of the predicted protein is 1447 amino acids with a molecular weight of 164,424. Topoisomerase II can be divided into three domains: (1) an N-terminal region with homology to the B (ATPase) subunit of the bacterial type II topoisomerase, DNA gyrase; (2) a central region with homology to the A (breaking and rejoining) subunit of DNA gyrase; (3) a C-terminal region characterized by alternating stretches of positively and negatively charged amino acids. DNA topoisomerase II from the fruit fly shares significant sequence homology with those from divergent sources, including bacteria, bacteriophage T4 and yeasts. The location and distribution of homologous stretches in these sequences are analyzed.     

Sequences that adopt non-B-DNA conformation in form V DNA as probed by enzymic methylation

pBR322 form V DNA is a highly torsionally strained molecule with a linking number of zero. We have used sequence-specific DNA methylases as probes for B-DNA in this molecule, exploiting the inability of methylases to methylate single-stranded DNA and Z-DNA, both of which are known to occur in form V DNA. Some sequences in form V DNA were shown to be totally in the B-form, others were totally in an altered, unmethylatable conformation, while still other sites appeared to exist partly in altered and partly in normal B-conformation. Some potential Z-forming sequences (alternating pyrimidine/purine) of less than seven base-pairs were not in the Z conformation in form V DNA, whereas others did adopt an altered structure, indicating a modulating influence of flanking sequences. Furthermore, regions of imperfect alternating pyrimidine/purine structure were sometimes capable of adopting an altered structure. In addition, some regions of altered structure had no apparent Z-forming sequences, nor were they in polypurine stretches, which have also been proposed to form left-handed DNA. These non-B-DNA conformations may represent novel left-handed helical structures or sequences that become single stranded under torsional strain. Long regions of either altered (unmethylatable) DNA or B-DNA were not always observed. In fact, one region showed three transitions between B-like DNA and altered structure within 26 base-pairs.     

Substrate specificity of HeLa endonuclease R. A G-specific mammalian endonuclease

We examined the substrate specificity of endonuclease R (endo R) a mammalian endonuclease that cleaves G.C-rich DNA sequences. The best substrates for double-stranded cleavage were homopolymeric stretches of poly(dG).poly(dC). Plasmids which contain other G-rich sequences were also cleaved but at a reduced frequency. These included the telomeric sequences, d(G4T2) and d(G2-6A), which were cleaved at approximately one-third the frequency of d(G)n.d(C)n. The alternating copolymer d(GA) and the terminal sequences of adeno-associated virus d(G1-3T/A) were also cut. Poly(dA).poly(dT) and the alternating copolymer d(GC)n were not detectably cleaved. Although endo R has a nicking activity which converts supercoiled plasmids to nicked circular DNA, the nicking activity is random with respect to plasmid sequences. Specific cleavage of G-rich sequences appears to occur by a concerted double-stranded mechanism. The cleavage pattern within the G-rich runs suggests that cleavage can occur anywhere within the G-rich region. Product ligation experiments indicate that a limited number of cleavage events (1-2) occur/molecule. Inasmuch as the best substrates for endo R are d(G)n.d(C)n and telomeric sequences, we suggest that endo R may directly recognize and cleave DNA that contains G.G base pairing.     

Detection of sequences with Z-DNA forming potential in higher plants

Sequences of alternating purine-pyrimidine residues with Z-DNA forming potential have been detected in the nuclear DNA of two higher plant species: wheat and radish. Poly (dG-dT) and poly (dG-dC) stretches have been detected by hybridization of the corresponding nick-translated probes to Southern blots. These stretches are scattered throughout the genome and some of them belong to moderately repeated sequence families interspersed with other DNA sequences.     

Isolation and complete nucleotide sequence of the gene for bovine parathyroid hormone

The structure of the bovine parathyroid hormone (PTH) gene has been analyzed by Southern blot hybridization of genomic DNA and by nucleotide sequence analysis of a cloned PTH gene. In the Southern analysis, several restriction enzymes produced single fragments that hybridized to PTH cDNA suggesting that there is a single bovine PTH gene. The restriction map of the cloned gene is the same as that determined by Southern blot analysis of bovine DNA. The sequence of 3154 bp of the cloned gene has been determined including 510 bp and 139 bp in the 5' and 3' flanking regions, respectively. The gene contains two introns which separate three exons that code primarily for: (i) the 5' untranslated region, (ii) the pre-sequence of preProPTH, and (iii) PTH and the 3' untranslated region. The gene contains 68% A + T and unusually long stretches of 100- to 150-bp sequences containing alternating A and T nucleotides in the 5' flanking region and intron A. The 5' flanking region contains two TATA sequences, both of which appear to be functional as determined by S1 nuclease mapping. Compared to the rat and human genes, the locations of the introns are identical but the sizes differ. Comparable human and bovine sequences in the flanking regions and introns are about 80% homologous.     

DNA duplex with the potential to change handedness after every half a turn.

Polymorphic forms of the DNA duplex with long stretches of structural monotony are known. Several alternating purine-pyrimidine sequences have been shown to adopt left-handed Z-conformation. We report a DNA sequence d(CGCGCGATCGAT)n exhibiting alternating right-handed B and left-handed Z helical conformation after every half a turn. Further, this unusual conformation with change in handedness after every six base pairs was induced at physiological superhelical density.     

Scoring functions for computational algorithms applicable to the design of spiked oligonucleotides.

Protein engineering by inserting stretches of random DNA sequences into target genes in combination with adequate screening or selection methods is a versatile technique to elucidate and improve protein functions. Established compounds for generating semi-random DNA sequences are spiked oligonucleotides which are synthesised by interspersing wild type (wt) nucleotides of the target sequence with certain amounts of other nucleotides. Directed spiking strategies reduce the complexity of a library to a manageable format compared with completely random libraries. Computational algorithms render feasible the calculation of appropriate nucleotide mixtures to encode specified amino acid subpopulations. The crucial element in the ranking of spiked codons generated during an iterative algorithm is the scoring function. In this report three scoring functions are analysed: the sum-of-square-differences function s, a modified cubic function c, and a scoring function m derived from maximum likelihood considerations. The impact of these scoring functions on calculated amino acid distributions is demonstrated by an example of mutagenising a domain surrounding the active site serine of subtilisin-like proteases. At default weight settings of one for each amino acid, the new scoring function m is superior to functions s and c in finding matches to a given amino acid population.     

Wrinkled DNA.

The B form of poly d(GC):poly d(GC) in orthorhombic microcrystallites in oriented fibers has a secondary structure in which a dinucleotide is the repeated motif rather than a mononucleotide as in standard, smooth B DNA. One set of nucleotides (probably GpC) has the same conformations as the smooth form but the alternate (CpG) nucleotides have a different conformation at C3'-O3'. This leads to a distinctive change in the orientation of the phosphate groups. Similar perturbations can be detected in other poly d(PuPy):poly d(PuPy) DNAs such as poly d(IC):poly d(IC) and poly d(AT):poly d(AT) in their D forms which have tetragonal crystal environments. This suggests that such perturbations are intrinsic to all stretches of duplex DNA where purines and pyrimidines alternate and may play a role in the detection and exploitation of such sequences by regulatory proteins.     

Characterization of rat ribosomal DNA. The highly repetitive sequences that flank the ribosomal RNA transcription unit are homologous and contain RNA polymerase III transcription initiation sites

The non-transcribed spacers (NTS) of the ribosomal genes of a number of organisms have been studied and were found to contain repetitive sequences. In these studies with plasmid subclones of NTS, designated p3.4, p2.6 and p1.7, which come from both 5' and 3' flanking regions of the rat ribosomal genes, respectively, it has been determined that these sequences are found elsewhere within the genome. Southern hybridization analysis has demonstrated that the 5' and 3' NTS subclones cross-hybridize, and that the cross-hybridizing regions are synonymous with the highly repetitive regions. Sequences homologous to the rat NTS were specifically localized to both 5' and 3' flanking regions as well as to a number of the introns of cloned genes including rat serum albumin, rat alpha-fetoprotein, rat casein and human serum albumin. No hybridization was detected of the 5' NTS subclone to the human Alu sequence clone, Blur 8, or to the rodent equivalent, a clone containing Chinese hamster ovary type I and II Alu sequences. However, as reported for type II Alu sequences, the subcloned rat NTS sequences contain RNA polymerase III initiation sites and also hybridize to a number of small RNAs, but not 4.5 S or 7 S RNA. Sequence analysis of two distinct repetitive regions in p1.7 has revealed a region of alternating purine-pyrimidine nucleotides, potentially of Z DNA, and stretches of repetitive sequences. The possible roles for these repetitive sequences in recombination and in maintaining a hierarchical structure for the ribosomal genes are discussed.     

Synthetic oligonucleotide probes deduced from amino acid sequence data. Theoretical and practical considerations

Synthetic probes deduced from amino acid sequence data are widely used to detect cognate coding sequences in libraries of cloned DNA segments. The redundancy of the genetic code dictates that a choice must be made between (1) a mixture of probes reflecting all codon combinations, and (2) a single longer "optimal" probe. The second strategy is examined in detail. The frequency of sequences matching a given probe by chance alone can be determined and also the frequency of sequences closely resembling the probe and contributing to the hybridization background. Gene banks cannot be treated as random associations of the four nucleotides, and probe sequences deduced from amino acid sequence data occur more often than predicted by chance alone. Probe lengths must be increased to confer the necessary specificity. Examination of hybrids formed between unique homologous probes and their cognate targets reveals that short stretches of perfect homology occurring by chance make a significant contribution to the hybridization background. Statistical methods for improving homology are examined, taking human coding sequences as an example, and considerations of codon utilization and dinucleotide frequencies yield an overall homology of greater than 82%. Recommendations for probe design and hybridization are presented, and the choice between using multiple probes reflecting all codon possibilities and a unique optimal probe is discussed.     

(A-T)n tracts embedded in random sequence DNA--formation of a structure which is chemically reactive and torsionally deformable.

Alternating d(A-T)n sequences which are contiguous with DNA of effectively random sequence have an abnormal conformation in linear DNA molecules. These regions are strongly reactive towards chemical modification by osmium tetroxide, and are preferentially cleaved by micrococcal nuclease. Both the chemical modification and the enzymic cutting occur uniformly through the alternating tract, and there is no evidence for enzyme or chemical sensitivity in the interfaces between the tract and DNA of normal conformation. These reactivities have a requirement for an alternating sequence. In addition to chemical reactivity, alternating (A-T)n sequences exhibit anomalously small twist changes on cruciform formation, suggesting that the pre-extruded DNA is underwound. We propose that the alternating sequences adopt an altered conformation which is subject to easy torsional deformation.     

The structure of the vimentin gene

The structure of the chromosomal gene encoding the intermediate filament protein vimentin is described. This gene, which is present as a single copy in the hamster genome, comprises about 10 kb of DNA and contains more than 80% of intron sequences. S1 mapping and sequence analysis reveal nine exons with a total length of 1848 nucleotides. For the complete primary structure of hamster vimentin, 464 amino acids are predicted, giving a molecular weight of 53,500 daltons. The intron positions are at codons 186, 206/207, 238/239, 292/293, 334/335, 408, 423, and 451/452. The overall homology with chicken desmin is 60% and is even higher in the central (alpha-helical) regions of both molecules. Cross-hybridization at the DNA level, however, is low. Comparison of the amino acid sequence of vimentin with prekeratin sequences shows that there is lesser homology of primary structure, but both the position and size of alpha-helical regions are strongly conserved. At the 5' end of the gene there is a consensus promoter sequence. The first AUG start codon is found 132 nucleotides downstream of the estimated cap site. The 3' nontranslated sequence shows homologies with the chicken vimentin gene. An interesting feature of the vimentin gene is a stretch of 44 nucleotides of alternating dC and dA within intron 2 that may form left-handed Z-DNA.     

A 7.1 kb linear DNA molecule of Theileria parva has scrambled rDNA sequences and open reading frames for mitochondrially encoded proteins.

Theileria parva, an intralymphocytic protozoan parasite of cattle, contains a linear 7.1 kb DNA element with terminal inverted repeat sequences. The molecule is transcribed into low molecular weight RNA, and both DNA strands encode short stretches of unique sequences, usually < 100 nucleotides, which are similar to large (LSU) or small (SSU) ribosomal subunit RNA. Phylogenetically conserved conformational rRNA domains were assembled from the discontinuous rDNA sequences using comparative secondary structure modelling. For example, a minimum of four predicted sequences, two derived from each DNA strand, is required to assemble domain V of LSU rRNA which participates in peptidyl transferase activity. The discontinuities in the identified rRNA domains fall within regions of no known functional significance. Hence, it is likely that the element encodes fragmented rDNA genes and the mature rRNA is unconventional, consisting of several fragments of RNA, primarily held together by intermolecular and intramolecular base pairing. The element also has ORFs for components of the last two mitochondrial electron transport enzyme complexes. The structure of the parasite DNA element, its protein coding capacity and scrambled rDNA gene sequences, are reminiscent of the mitochondrial genome of Chlamydomonas reinhardtii. We propose that the 7.1 kb element is equivalent to the mitochondrial DNA of T. parva, although a number of its features are unusual for this family of extrachromosomal DNA molecules.     

Loss of DNA: a plausible molecular level explanation for crustacean neuropeptide gene evolution

Alignment of nucleotides of APGWamide, RPCH and AKH genes gives region stretches (common regions) present in all family member variants. Common regions were separated by gap sections in the larger variants of family members. Consensus sequences for single polynucleotides from virtual hybrid molecules of DNA were obtained by joining the common regions of DNA and deleting the extra DNA nucleotides. Conceptual translation of these virtual hybrids resulted in polypeptides similar to APGWamide, RPCH and the AKH pre-pro-peptide. Virtual polypeptides were also similar to LWamide and RFamide along hydras to mammals. DNA loss probably explains the origin of neuropeptides.     

Hypersensitive mung bean nuclease cleavage sites in Plasmodium knowlesi DNA

Nucleotide sequences of Plasmodium knowlesi DNA that are cleaved by mung bean nuclease (Mbn) at low enzyme concentration (0.2 units enzyme per micrograms DNA) are listed. They are tandemly repeated purine/pyrimidine (RpY) stretches of DNA with (ApT) dimers predominating. Most cut sites are within almost 100% RpY tracts. The enzyme cleaves at many points within the RpY stretch and usually hydrolyzes the 5'-ApT-3' linkage. These alternating RpY target sites are flanked by homopurine and homopyrimidine stretches. At least one Mbn target site lies next to an in vivo transcribed region.     

Selective isolation of mercurated DNA by affinity chromatography on thiol matrices

A method for isolating picomole quantities of nascent mercurated DNA from a mixture of cellular nucleic acids using affinity chromatography on thiol-agarose is described. Analysis of mercurated DNA (HgDNA) isolated in the presence of in vivo-labeled cellular RNA or in vitro-synthesized RNA showed a low level of RNA contamination, about 0.04-0.16%, in the HgDNA. Comparative binding studies on different thiol matrices showed that the efficiency of binding of HgDNA was related to the nature but not to the SH content of the matrix used. Another important parameter for binding was the structure of HgDNA. The recovery was 98% with large nascent HgDNA sedimenting at about 30 S, whereas for short pulse-labeled single-stranded HgDNA (20-50 nucleotides long), the maximum recovery was 60%. The effect of the structure of HgDNA on the binding to the thiol matrix was probed using a variety of well-defined mercurated structures obtained from phage DNA and their restriction fragments. For DNA containing one 5-mercuricytidine 5'-triphosphate (HgdCMP) residue at each 3'-end, short fragments (size range, 230-510 bp) were bound quantitatively. With larger fragments (size range, 490-1100 bp), the binding decreased progressively with increasing size. DNA fragments larger than 1060 bp did not bind to the matrix. Single-stranded DNA containing only one HgdCMP at one end did not bind to the matrix even in the size range 200-1100 nucleotides. In contrast, continuous stretches of HgdCMP residues in one strand or short stretches of HgdCMP residues at random in both strands permit quantitative binding irrespective of size.     

Concordance of experimentally mapped or predicted Z-DNA sites with positions of selected alternating purine-pyrimidine tracts.

The recent electronmicroscopic and biochemical mapping of Z-DNA sites in phi X174, SV40, pBR322 and PM2 DNAs has been used to determine two sets of criteria for identification of potential Z-DNA sequences in natural DNA genomes. The prediction of potential Z-DNA tracts and corresponding statistical analysis of their occurrence have been made on a sample of 14 DNA genomes. Alternating purine and pyrimidine tracts longer than 5 base pairs in length and their clusters (quasi alternating fragments) in the 14 genomes studied are under-represented compared to the expectation from corresponding random sequences. The fragments [d(G X C)]n and [d(C X G)]n (n greater than or equal to 3) in general do not occur in circular DNA genomes and are under-represented in the linear DNAs of phages lambda and T7, whereas in linear genomes of adenoviruses they are strongly over-represented. With minor exceptions, potential Z-DNA sites are also under-represented compared to random sequences. In the 14 genomes studied, predicted Z-DNA tracts occur in non-coding as well as in protein coding regions. The predicted Z-DNA sites in phi X174, SV40, pBR322 and PM2 correspond well with those mapped experimentally. A complete listing together with a compact graphical representation of alternating purine-pyrimidine fragments and their Z-forming potential are presented.     

Torsional stress induces left-handed helical stretches in DNA of natural base sequence: circular dichroism and antibody binding

Above a threshold of torsional stress, the c.d. spectrum of covalently closed circular DNA of natural base sequence acquires a Z-like contribution and antibodies raised against Z-DNA are bound. Mapping of the antibody binding sites by electron microscopy reveals sites which correlate with stretches enriched in alternating purine-pyrimidine sequences and GC base pairs.     

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.     

The flexibility of alternating dA-dT sequences

The flexibility of alternating poly (dA-dT) has been investigated by the technique of transient electric dichroism. Rotational relaxation times, which are very sensitive to changes in the end-to-end length of flexible polymers, are determined from the field free dichroism decay curves of four, well defined fragments of poly (dA-dT) ranging in size from 136 to 270 base pairs. Persistence lengths, calculated from the results of Hagerman and Zimm (Biopolymers (1981) 29, 1481-1502), are in the range 200-250 A. This makes alternating dA-dT sequences about twice as flexible as naturally occurring, "random" sequence DNA. Considering a bend around a nucleosome, for example, this difference in persistence length translates to an energy difference between poly (dA-dT) and random sequence DNA of 0.17 kT/base pair or 1 kcal per 10 base pair stretch. This energy difference is sufficiently large to suggest that dA-dT sequences could serve as markers in DNA packaging, for example, at sites where DNA must tightly bend to accommodate structures.