RecBC, sbcB independent, (AT)n-mediated deletion of sequences flanking a Xenopus laevis beta globin gene on propagation in E. coli

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Analysis of Streptococcus pneumoniae sequences cloned into Escherichia coli: effect of promoter strength and transcription terminators

Difficulties encountered in the cloning of DNA from Streptococcus pneumoniae and other AT-rich organisms into ColE1-type Escherichia coli vectors have been proposed to be due to the presence of a large number of strong promoter-acting sequences in the donor DNA. The use of transcription terminators has been advocated as a means of reducing instability resulting from disruption of plasmid replication caused by strong promoters. However, neither the existence of promoter-acting sequences of sufficient strength and number to explain the reported cloning difficulties nor their role as a source of instability has been proven. As a direct test of the "strong promoter" hypothesis, we cloned random fragments from S. pneumoniae into an E. coli vector containing transcription terminators, identified strong promoter-acting sequences, and subsequently removed the transcription terminators. We observed that terminator removal resulted in reduced copy numbers for the strongest promoter-acting sequences but not in reduced promoter strengths or altered plasmid stabilities. Our results indicate that promoters strong enough to require transcription terminators for plasmid stability are probably rare in S. pneumoniae DNA.

Formation of (dA-dT)n cruciforms in Escherichia coli cells under different environmental conditions

We have detected cruciform formation of (dA-dT)n inserts in Escherichia coli cells by analyzing the superhelical density of isolated plasmid DNA samples and by probing intracellular DNA with chloroacetaldehyde. The plasmids we used were pUC19 containing inserts of (dA-dT)n. The cruciforms appeared after cells underwent different stresses: inhibition of protein synthesis, anaerbiosis, and osmotic shock. At the same time, all these stimuli led to an increase in superhelical density of the control pUC19 plasmid DNA. Therefore, we suggest that the increase in plasmid superhelicity in response to different environmental stimuli entails the appearance of cruciform structures. The use of the (dA-dT)n units of various lengths made it possible to estimate the superhelical density of the plasmid DNA in vivo.

Local supercoil-stabilized DNA structures

The DNA double helix exhibits local sequence-dependent polymorphism at the level of the single base pair and dinucleotide step. Curvature of the DNA molecule occurs in DNA regions with a specific type of nucleotide sequence periodicities. Negative supercoiling induces in vitro local nucleotide sequence-dependent DNA structures such as cruciforms, left-handed DNA, multistranded structures, etc. Techniques based on chemical probes have been proposed that make it possible to study DNA local structures in cells. Recent results suggest that the local DNA structures observed in vitro exist in the cell, but their occurrence and structural details are dependent on the DNA superhelical density in the cell and can be related to some cellular processes.

Superhelical torsion in cellular DNA responds directly to environmental and genetic factors

Superhelical tension of DNA in living bacteria is believed to be partially constrained by interaction with proteins. Yet DNA topology is a significant factor in a number of genetic functions and is apparently affected by both genetic and environmental influences. We have employed a technique that allows us to estimate the level of unconstrained superhelical tension inside the cell. We study the formation of cruciform structures by alternating adenine-thymine sequences in plasmid DNA by in situ chemical probing. This structural transition is driven by superhelical torsion in the DNA and thus reports directly on the level of such tension in the cellular DNA. We observe that the effect of osmotic shock is an elevation of superhelical tension; quantitative comparison with changes in plasmid linking number indicates that the alteration in DNA topology is all unconstrained. We also show that the synthesis of defective topoisomerase leads to increased superhelical tension in plasmid DNA. These experiments demonstrate that the effect of environmental and genetic influences is felt directly at the level of torsional stress in the cellular DNA.

The DNA gyrase of Escherichia coli participates in the formation of a spontaneous deletion by recA-independent recombination in vivo

A system for detecting a spontaneous deletion in Escherichia coli was developed and the role of DNA gyrase in deletion formation was studied. A derivative of lambda plac5, lambda AM36, was isolated in which whole pBR322 DNA was inserted in the lacZ gene and 227 bp of the lac gene duplicated at both sides of the pBR322 DNA. E. coli lac- strains lysogenized by lambda AM36 had a Lac- phenotype and segregated Lac+ revertants. Sequence analyses showed that the revertant was formed by a deletion that eliminated the inserted pBR322 DNA and one copy of the duplicated segments. The frequency of lac+ revertant formation was independent of recA function, was increased by oxolinic acid, an inhibitor of DNA gyrase, but was not increased in a lysogen of a nalidixic acid-resistant derivative. The reversion frequencies of temperature sensitive mutants of gyrA gene are 10 to 100 times lower than that of the wild-type strain. These results indicate that the DNA gyrase of E. coli participated in the in vivo deletion formation resulting from the direct repeats.

Sequence analysis of the upstream regions of Xenopus laevis beta-globin genes and arrangement of repetitive elements within the globin gene clusters

The globin gene clusters of Xenopus laevis are interspersed by various different repetitive DNA elements. A specific repeat, the JH12 element, has been mapped by Southern analysis and some of its locations have been subsequently confirmed by nucleotide sequencing. JH12 family members seem to represent mobile genetic elements and display a high degree of divergence. The nucleotide sequences upstream to the adult beta I-globin gene and to the two coordinately expressed larval beta I- and beta II-globin genes have been determined and compared to those of the adult alpha-genes. Besides some repetitive DNA elements and a short sequence of rather weak homology we have found no characteristic sequence motifs to be common to the adult alpha- and beta-genes. The two larval beta-genes share one short sequence element being absent from the adult genes. This might reflect completely different sequence requirements for protein interactions and for the regulation of adult and larval globin gene expression.

FOSP-1 (frog oviduct-specific protein-1) gene: cloning of cDNA and induction by estrogen in primary cultures of Xenopus oviduct cells

We describe the isolation of a cloned cDNA from a cDNA library of oviduct of estrogen-treated adult Xenopus. Although the protein encoded by this cDNA is not known, it is designated as FOSP-1 (frog oviduct-specific protein-1). A partial restriction map of FOSP-1 cDNA, which is 1.5 kb in size, is presented. Northern hybridization analysis showed that FOSP-1 cDNA codes for a single species of mRNA of 2.6 kb which is exclusively expressed in Xenopus oviduct. Southern blot analysis showed that the gene was present in only one or two copies. Sequencing of partial FOSP-1 cDNA did not reveal homology with any protein in the sequence data bank. Measurement of steady-state levels of FOSP-1 mRNA in primary cultures of Xenopus oviduct cells by a technique of quantitative slot-blot analysis showed that both 17 beta and 17 alpha stereoisomers of estradiol caused a rapid 5-fold enhancement of accumulation of the mRNA with maximum values obtained at 5 X 10(-8) M estrogen. Progesterone caused only a small increase in FOSP-1 mRNA concentration. This hormone-specific induction of mRNA makes FOSP-1 a valuable candidate for exploring tissue specificity of regulation by estrogen of gene expression.

Formation of deletion in Escherichia coli between direct repeats located in the long inverted repeats of a cellular slime mold plasmid: participation of DNA gyrase

We constructed a recombinant plasmid containing the 2.1 kb HindIII fragment of plasmid pDG1, isolated from the cellular slime mold (Dictyostelium sp. strain GA11), and using pAG60 as cloning vector. We found that deletions of the recombinant plasmid took place frequently in Escherichia coli wild-type cells. However, the deletion was not observed when the plasmid was introduced into a strain that was an isogenic temperature-sensitive mutant of the gyrA gene. These results suggest that E. coli DNA gyrase is involved in the mechanisms of the deletion formation. It was shown that the 1.0 kb deletant derived from the 2.1 kb HindIII insert was produced by elimination of a 1.1 kb region. Sequence analysis of the deletants showed that cutting and rejoining took place between two out of the six nearly perfect direct repeats [21 bp palindromic sequences; AAAAAA(T/C)GGC(G/C)GCC(A/G)TTTTTT], located near the distal ends of the inverted repeats, preserving one copy of the repeats. These sequences consist of local short inverted repeats, where cutting and rejoining occur at one of the two regions.

5' structural motifs and Xenopus beta globin gene activation

We have analysed the structure of the Xenopus beta globin gene 5' flanking region in erythroid and non-erythroid chromatin, in supercoiled plasmids and in minichromosomes assembled in HeLa cell transfections. We have identified two erythroid chromatin-specific, nuclease-hypersensitive sites (HSs), one centred on the cap site, the other located 1000 base-pairs further upstream. An (AT)n tract is located 200 base-pairs upstream from each of these sites. In supercoiled plasmids, the (AT)n tracts, and not the chromatin HSs, are preferentially cleaved by single strand and double strand-specific nucleases. Using restriction enzymes, we have looked at the structure of the cap site HS in minichromosomes assembled in HeLa cell transfections. We find that the structure is indistinguishable from that found in erythroid chromatin, thus reinforcing our previous suggestion, based only on DNase I studies, that the formation of this HS is not dependent on erythroid-specific factors. In view of this close structural mimicry of the situation in vivo, we have used the HeLa cell model system to study the sequences required for cap site HS formation. We find that deletion of the (AT)n tract immediately upstream influenced neither the formation of the HS nor transcription of the globin gene. Indeed, these features remained unaffected by further deletion of upstream sequences, including 50 base-pairs of the HS itself. In this construct, the dimensions of the HS remained the same as in the undeleted construct, with the plasmid sequences that replaced the deleted Xenopus sequences becoming hypersensitive. Thus, HS formation is directed by sequences downstream from --116 acting over a distance of at least 50 base-pairs.

RAD4 gene of Saccharomyces cerevisiae: molecular cloning and partial characterization of a gene that is inactivated in Escherichia coli

In contrast to other Saccharomyces cerevisiae RAD genes involved in nucleotide excision repair of DNA, the RAD4 gene could not be isolated by screening a yeast genomic library for recombinant plasmids which complement the UV sensitivity of rad4 mutants (Pure et al., J. Mol. Biol. 183:31-42, 1985). We therefore attempted to walk to RAD4 from the neighboring SPT2 gene and obtained an integrating derivative of a plasmid isolated by Roeder et al. (Mol. Cell. Biol. 5:1543-1553, 1985) which contains a 4-kilobase fragment of yeast DNA including a mutant allele of SPT2. When integrated into several different rad4 mutant strains, this plasmid (pR169) complements UV sensitivity at a frequency of approximately 10%. However, a centromeric plasmid containing rescued sequences which include flanking yeast DNA no longer complements the phenotype of rad4 mutants. Complementing activity was restored by in vivo repair of a defined gap in the centromeric plasmid. The repaired plasmid fully complements the UV sensitivity of all rad4 mutants tested when isolated directly from yeast cells, but when this plasmid is propagated in Escherichia coli complementing activity is lost. We have mapped the physical location of the RAD4 gene by insertional mutagenesis and by transcript mapping. The gene is approximately 2.3 kilobases in size and is located immediately upstream of the SPT2 gene. Both genes are transcribed in the same direction. RAD4 is not an essential gene, and no increased transcription of this gene is observed in cells exposed to the DNA-damaging agent 4-nitroquinoline-1-oxide. The site of inactivation of RAD4 in a particular plasmid propagated in E. coli was localized to a 100-base-pair region by gene disruption and gap repair experiments. In addition, we have identified the approximate locations of the chromosomal rad4-2, rad4-3, and rad4-4 mutations.

RAD4 gene of Saccharomyces cerevisiae: molecular cloning and partial characterization of a gene that is inactivated in Escherichia coli

In contrast to other Saccharomyces cerevisiae RAD genes involved in nucleotide excision repair of DNA, the RAD4 gene could not be isolated by screening a yeast genomic library for recombinant plasmids which complement the UV sensitivity of rad4 mutants (Pure et al., J. Mol. Biol. 183:31-42, 1985). We therefore attempted to walk to RAD4 from the neighboring SPT2 gene and obtained an integrating derivative of a plasmid isolated by Roeder et al. (Mol. Cell. Biol. 5:1543-1553, 1985) which contains a 4-kilobase fragment of yeast DNA including a mutant allele of SPT2. When integrated into several different rad4 mutant strains, this plasmid (pR169) complements UV sensitivity at a frequency of approximately 10%. However, a centromeric plasmid containing rescued sequences which include flanking yeast DNA no longer complements the phenotype of rad4 mutants. Complementing activity was restored by in vivo repair of a defined gap in the centromeric plasmid. The repaired plasmid fully complements the UV sensitivity of all rad4 mutants tested when isolated directly from yeast cells, but when this plasmid is propagated in Escherichia coli complementing activity is lost. We have mapped the physical location of the RAD4 gene by insertional mutagenesis and by transcript mapping. The gene is approximately 2.3 kilobases in size and is located immediately upstream of the SPT2 gene. Both genes are transcribed in the same direction. RAD4 is not an essential gene, and no increased transcription of this gene is observed in cells exposed to the DNA-damaging agent 4-nitroquinoline-1-oxide. The site of inactivation of RAD4 in a particular plasmid propagated in E. coli was localized to a 100-base-pair region by gene disruption and gap repair experiments. In addition, we have identified the approximate locations of the chromosomal rad4-2, rad4-3, and rad4-4 mutations.