Cooperative binding of Agrobacterium tumefaciens VirE2 protein to single-stranded DNA.

The VirE2 protein of Agrobacterium tumefaciens Ti plasmid pTiA6 is a single-stranded-DNA-binding protein. Density gradient centrifugation studies showed that it exists as a tetramer in solution. Monomeric VirE2 active in DNA binding could also be obtained by using a different protein isolation procedure. VirE2 was found to be thermolabile; brief incubation at 37 degrees C abolished its DNA-binding activity. It was insensitive to the sulfhydryl-specific reagent N-ethylmaleimide. Removal of the carboxy-terminal 37 residues of the 533-residue VirE2 polypeptide led to complete loss of DNA-binding activity; however, chimeric fusion proteins containing up to 125 residues of the VirE2 C terminus were inactive in DNA binding. In nuclease protection studies, VirE2 protected single-stranded DNA against degradation by DNase I. Analysis of the DNA-VirE2 complex by electron microscopy demonstrated that VirE2 coats a single-stranded DNA molecule and that the binding of VirE2 to its substrate is cooperative.     

Enhancement of gene expression by polyamidoamine dendrimer conjugates with alpha-, beta-, and gamma-cyclodextrins.

To improve the transfection efficiency of nonviral vector, we synthesized the starburst polyamidoamine dendrimer conjugates with alpha-, beta-, and gamma-cyclodextrins (CDE conjugates), expecting the synergistic effect of dendrimer and cyclodextrins (CyDs). The (1)H NMR spectroscopic data indicated that alpha-, beta-, and gamma-CyDs are covalently bound to dendrimer in a molar ratio of 1:1. The agarose gel electrophoretic studies revealed that CDE conjugates formed the complexes with plasmid DNA (pDNA) and protected the degradation of pDNA by DNase I in the same manner as dendrimer. CDE conjugates showed a potent luciferase gene expression, especially in the dendrimer conjugate with alpha-CyD (alpha-CDE conjugate) which provided the greatest transfection activity (approximately 100 times higher than those of dendrimer alone and of the physical mixture of dendrimer and alpha-CyD) in NIH3T3 and RAW264.7 cells. In addition, the gene transfer activity of alpha-CDE conjugate was superior to that of Lipofectin. The enhancing gene transfer effect of alpha-CDE conjugate may be attributable to not only increasing the cellular association, but also changing the intracellular trafficking of pDNA. These findings suggest that alpha-CDE conjugate could be a new preferable nonviral vector of pDNA.     

Potentiation of a nucleolytic activity in Bacillus subtilis

In several strains of Bacillus subtilis extensive breakdown of chromosomal DNA may be potentiated by osmotic lysis of protoplasts. At its most severe, in strains originating from Farmer & Rothman's thymine auxotroph, the rate of DNA breakdown was greater than 50% per hour at 40 degrees C. The rate of DNA breakdown in most other strains tested was approximately 5% per hour except for SP beta- strains, in which the rate of DNA breakdown was only 0.3%. DNA degradation was attributed to relaxation of control of a nuclease specified by the prophage of SP beta or a related phage. The most potent nuclease in lysates was an ATP-activated protein of Mr 280 000. Derivatives of Farmer and Rothman's strain containing integrated plasmids had the highest rate of DNA degradation. Although the chromosome was completely destroyed, covalently closed circular plasmids were generated from the integrated sequence. These showed massive deletions of the B. subtilis part of the integrated plasmid but the vector sequence remained intact. The nucleolytic activity therefore appears to recognize specific sequences in B. subtilis DNA. We suggest that activation of SP beta genes during development of competence may be a cause of deletion of cloned genes in the early stages of establishment of cloned sequences.     

Plasmid transformation in Bacillus subtilis: Fate of plasmid DNA

Summary Only multimeric, and not monomeric forms of B. subtilis plasmids can transform B. subtilis cells (Canosi et al. 1978). This finding prompted us to study the physico-chemical fate of plasmid DNA in transformation. Competent cells of B. subtilis were exposed to either unfractionated preparations or to preparations of multimeric plasmid DNA. Plasmid DNA was re-extracted from such cells and then analyzed by sedimentation and isopycnic centrifugation and also defined by its sensitivity to nuclease S1 degradation. No double-stranded plasmid DNA could be recovered from cells transformed with unfractionated plasmid preparations which contained predominantly monomeric covalently closed circular (CCC) DNA, Re-extracted plasmid DNA was single-stranded, had a molecular weight considerably smaller than monomer length DNA and had been subject to degradation to acid soluble products. However, when transformations were performed with multimeric DNA (constructed by in vitro ligation of linearized pC194 DNA), both double-stranded and partially double-stranded DNA could be recovered in addition to single-stranded DNA.We assume that plasmid DNA is converted to a single-stranded form in transformation, irrespective of its molecular structure. Double-stranded and partially double-stranded DNAs found in transformation with multimeric DNA would be the products of intramolecular annealing.Some of these results were presented at the 5th European Meeting on Bacterial Transformation and Transfection, September 1980, Florence     

Strength of conjugate binding to plasmid DNA affects degradation rate and expression level in vivo

In vitro assays have demonstrated the capability of poly-L-lysine to protect plasmid DNA from serum nucleases and cellular lysates. Our purpose was to evaluate the stability and potency of poly-L-lysine-DNA polyplexes after intravenous injection into mice. Polyplexes consisted of 32P-radiolabeled plasmid DNA complexed with poly-L-lysine at specified charge ratios. Variations in conjugate hydrophobicity and levels of modification with polyethylene glycol were investigated. Our results show that, in contrast to in vitro studies, the systemically administered polyplexes exhibited marked DNA degradation in the vascular compartment within 5 min. Substitution of poly-L-lysine epsilon-amino sites with polyethylene glycol or hydrocarbon chains resulted in faster degradation even when complexed at higher charge (+/-) ratios. Use of excess cationic charge in the polyplexes (+/- 2.5) diminished degradation rates only slightly. An analysis was made of the strength of the poly-L-lysine:DNA interaction by competition with poly-aspartic acid. Polyplexes with the strongest binding between conjugate and DNA in the competition assay were also the most stable in blood. However, tighter binding was not enough to fully protect the polyplex in vivo and polyplex DNA was substantially degraded within 10 min. Increased polyplex stability did not correlate with improved in vivo transfection efficiency.     

Nonintegrated plasmid-chromosome complexes in Escherichia coli.

A number of plasmid systems have been examined for the ability of their covalently closed circular deoxyribonucleic acid (CCC DNA) forms to cosediment in neutral sucrose gradients with the folded chromosomes of their respective hosts. Given that cosedimentation of CCC plasmid and chromosomal DNA represents a bound or complexed state between these replicons, our results can be expressed as follows. (i) All plasmid systems complex, on the average, at least one plasmid per chromosomal equivalent. (ii) Stringently controlled plasmids exist predominantly in the bound state, whereas the opposite is true for plasmids that exist in multiple copies or are under relaxed control of replication. (iii) The degree to which a plasmid population binds to host chromosomes appears to be a function of plasmid genotype and not of plasmid size. (iv) For the colicin E1 plasmid the absolute number of plasmids bound per folded chromosome equivalent does increase as the intracellular plasmid/chromosome ratio increases in cells starved for required amino acids or in cells treated with chloramphenicol; however, the ratio of bound to free plasmids remains constant during plasmid copy number amplification.     

A native cruciform DNA structure probed in bacteria by recombinant T7 endonuclease

T7 endonuclease preferentially cleaves purified supercoiled pBR322 and colE1 plasmids at the single-stranded regions exposed when palindromic sequences assume cruciform structures (Panayotatos, N., and Wells, R.D. (1981) Nature 289, 466-470). In vivo, however, induction of nuclease synthesis off a cloned gene caused complete degradation of the bacterial DNA but not of the plasmid vector; presumably, single-stranded regions (cruciforms?) on the genome effectively complete for the nuclease with similar sites on the plasmid (Panayotatos, N., and Fontaine, A. (1985) J. Biol. Chem. 260, 3173-3177). To overcome this competition, we introduced on the plasmid the naturally occurring colE1 palindrome which forms a more stable cruciform in vitro. In addition, we increased the target size (and the T7 endonuclease gene dosage) by raising the copy number of the plasmid 5-fold. Induction of the endonuclease encoded by this new plasmid (pLAT75) resulted not only in degradation of genomic DNA but also in intracellular nicking and linearization of the plasmid. The cleavage site in vivo was mapped at the colE1 palindrome and coincided with the site cleaved specifically in vitro by either T7 or S1 endonuclease only when this palindrome assumes the cruciform structure. These results indicate that cruciform structures exist intracellularly and demonstrate the usefulness of endonucleases as probes of DNA topology in vivo.     

Induction of a cytotoxic T lymphocyte (CTL) response to plasmid DNA delivered via Lipodine liposomes

We have previously shown that liposome-mediated plasmid DNA immunisation may be a preferred alternative to the use of naked DNA. Lipodine DNA formulations consist of liposomes containing entrapped DNA plasmid by the dehydration-rehydration (DRV) method. Such liposome formulations are distinct from liposomes with externally complexed DNA in that the majority of the DNA is "internal" to the liposome structure and hence protected from DNAase degradation. Previous studies on the immune response induced by DNA vaccines entrapped in Lipodine have focused on the humoural response. In the present study, we have expanded the analysis profile in order to include the cytotoxic T lymphocyte (CTL) component of the immune response. We have analysed the immune response induced by DNA entrapped in Lipodine compared to that induced by DNA alone when delivered subcutaneously, a route of administration not normally inducing significant plasmid DNA mediated immune activation. Our results indicate that delivery of a small dose of plasmid DNA in Lipodine results in an improved antibody response to the plasmid encoded antigen and a strong antigen specific CTL response compared to that induced by DNA delivered alone.     

Interaction of a folded chromosome-associated protein with single-stranded DNA-binding protein of Escherichia coli, identified by affinity chromatography

A single-stranded DNA-binding protein (SSB) affinity column was prepared by optimizing the coupling of Escherichia coli single-stranded DNA-binding protein to Affi-Gel 10. The bound SSB retained its ability to specifically bind single-stranded DNA. When nuclease-treated cell extracts were incubated with the SSB beads overnight at 4 degrees C, a major protein of Mr = 25,000 was bound. At shorter incubation times, two additional proteins of Mr = 32,000 and 36,000 were also detected. In the absence of nuclease treatment, eight additional proteins ranging from Mr = 14,000 to 160,000 also bound to the affinity column. The major Mr = 25,000 protein has been shown to be a folded chromosome-associated protein. Its binding to SSB is strongly enhanced by the addition of DNA polymerase III or DNA polymerase III holoenzyme.     

Characterization of the phage phi 29 protein p5 as a single-stranded DNA binding protein. Function in phi 29 DNA-protein p3 replication.

The phage phi 29 protein p5, required in vivo in the elongation step of phi 29 DNA replication, was highly purified from Escherichia coli cells harbouring a gene 5-containing plasmid and from phi 29-infected Bacillus subtilis. The protein was characterized as the gene 5 product by amino acid analysis and NH2-terminal sequence determination. The purified protein p5 was shown to bind to single-stranded DNA and to protect it against nuclease degradation. No effect of protein p5 was observed either on the formation of the p3-dAMP initiation complex or on the rate of elongation. However, protein p5 greatly stimulated phi 29 DNA-protein p3 replication at incubation times where the replication in the absence of p5 leveled off.     

In Vitro Reconstitution of an Escherichia coli RNA-guided Immune System Reveals Unidirectional,ATP-dependent Degradation of DNA Target

Many prokaryotes utilize small RNA transcribed from clustered, regularly interspaced, short palindromic repeats (CRISPRs) to protect themselves from foreign genetic elements, such as phage and plasmids. In Escherichia coli, this small RNA is packaged into a surveillance complex (Cascade) that uses the RNA sequence to direct binding to invasive DNA. Once bound, Cascade recruits the Cas3 nuclease-helicase, which then proceeds to progressively degrade the invading DNA. Here, using individually purified Cascade and Cas3 from E. coli, we reconstitute CRISPR-mediated plasmid degradation in vitro. Analysis of this reconstituted assay suggests that Cascade recruits Cas3 to a single-stranded region of the DNA target exposed by Cascade binding. Cas3 then nicks the exposed DNA. Recruitment and nicking is stimulated by the presence, but not hydrolysis, of ATP. Following nicking and powered by ATP hydrolysis, the concerted actions of the helicase and nuclease domains of Cas3 proceed to unwind and degrade the entire DNA target in a unidirectional manner.     

Single-stranded DNA from viruses, prokaryotes and eukaryotes]

The review presents the results of investigations of single-stranded DNAs of viruses, bacteria and cells of higher organisms. Methods of revealing, isolating and analysis of these DNAs are presented. A large variety of single-stranded DNA containing genomes of plant and animal viruses was revealed. Attention is drawn to the integration and replication of viral genomes. Results of SV40 integration during the first two days after infection of Chinese hamster cells are shown. Results of studying multi-copy single-stranded DNA in bacterial cells were analysed. In separate sections, the replication of plasmid single-stranded DNA was studied as well as the problem of plasmid stability in cells. Advances in bacteria transformation studies are stated. Data of single-stranded DNA investigation in cells of higher organisms are mainly presented on the example of early embryos. Data on the analysis of gene hypersensitivity to nuclease S1 are given. A table of proteins destabilizing and unweaving single-stranded DNA and a classification table of proteins bound with single-stranded DNA according to their functional significance are presented. It is stated that the problem of single-stranded DNA significance in cells remains open, although some results have been achieved.     

Mass spectrometric investigation of the DNA-binding properties of an anthracycline with two trisaccharide chains

Cosmomycin D (CosD) is an anthracycline that has two trisaccharide chains linked to its ring system. Gel electrophoresis showed that CosD formed stable complexes with plasmid DNA under conditions where daunorubicin (Dn) and doxorubicin (Dx) dissociated to some extent during the experiments. The footprint and stability of CosD complexed with 10- and 16 mer DNA was investigated using several applications of electrospray ionisation mass spectrometry (ESI-MS). ESI-MS binding profiles showed that fewer CosD molecules bound to the sequences than Dn or Dx. In agreement with this, ESI-MS analysis of nuclease digestion products of the complexes showed that CosD protected the DNA to a greater extent than Dn or Dx. In tandem MS experiments, all CosD–DNA complexes were more stable than Dn- and Dx-DNA complexes. These results support that CosD binds more tightly to DNA and exerts a larger footprint than Dn or Dx. ESI-MS investigations of the binding properties of CosD could be carried out rapidly and using only small amounts of sample.     

Compact structure of ribosomal chromatin in Xenopus laevis.

Micrococcal nuclease digestion was used as a tool to study the organization of the ribosomal chromatin in liver, blood and embryo cells of X. laevis. It was found that in liver and blood cells, ribosomal DNA is efficiently protected from nuclease attack in comparison to bulk chromatin. Although ribosomal chromatin is fragmented in a typical nucleosomal pattern, a considerable portion of ribosomal DNA retains a high molecular weight even after extensive digestion. A greater accessibility of the coding region in comparison to the non-coding spacer was found. In embryos, when ribosomal DNA is fully transcribed, these genes are even more highly protected than in adult tissues: in fact, the nucleosomal ladder can hardly be detected and rDNA is preserved in high molecular weight. Treatment of chromatin with 0.8 M NaCl abolishes the specific resistance of the ribosomal chromatin to digestion. The ribosomal chromatin, particularly in its active state, seems to be therefore tightly complexed with chromosomal proteins which protect its DNA from nuclease degradation.     

Degradation of Escherichia coli chromosomal and plasmid DNA in serum

Incubation of serum-sensitive [3H]thymidine labelled Escherichia coli PC2166 (RSF1030) and E. coli AM1281 (pBR322) harbouring small plasmids (mol. wt 5.5 X 10(6) and 2.6 X 10(6] in serum resulted in killing of 99.9% of the bacteria within 15 min and in the release of 85% of the radioactivity into the medium after 1 h incubation. The fate of chromosomal and plasmid DNA during incubation of the bacteria in serum was analysed by measurement of the amount of DNA-associated radioactivity, by TCA precipitation, by agarose gel electrophoresis and by the capacity of DNA to transform competent acceptor bacteria. Chromosomal DNA and high molecular weight plasmid DNA were rapidly degraded after 1 h incubation of bacteria in serum. However, low molecular weight plasmid DNA was virtually unaffected and remained physicochemically as well as biologically intact during up to 4 h of incubation of bacteria in serum.     

Characterization of a periplasmic S1-like nuclease coded by the Mesorhizobium loti symbiosis island

DNA sequences encoding hypothetical proteins homologous to S1 nuclease from Aspergillus oryzae are found in many organisms including fungi, plants, pathogenic bacteria, and eukaryotic parasites. One of these is the M1 nuclease of Mesorhizobium loti which we demonstrate herein to be an enzymatically active, soluble, and stable S1 homolog that lacks the extensive mannosyl-glycosylation found in eukaryotic S1 nuclease homologs. We have expressed the cloned M1 protein in M. loti and purified recombinant native M1 to near homogeneity and have also isolated a homogeneous M1 carboxy-terminal hexahistidine tag fusion protein. Mass spectrometry and N-terminal Edman degradation sequencing confirmed the protein identity. The enzymatic properties of the purified M1 nuclease are similar to those of S1. At acidic pH M1 is 25 times more active on single-stranded DNA than on double-stranded DNA and 3 times more active on single-stranded DNA than on single-stranded RNA. At neutral pH the RNase activity of M1 exceeds the DNase activity. M1 nicks supercoiled RF-I plasmid DNA and rapidly cuts the phosphodiester bond across from the nick in the resultant relaxed RF-II plasmid DNA. Therefore, M1 represents an active bacterial S1 homolog in spite of great sequence divergence. The biochemical characterization of M1 nuclease supports our sequence alignment that reveals the minimal 21 amino acid residues that are necessarily conserved for the structure and functions of this enzyme family. The ability of M1 to degrade RNA at neutral pH implies previously unappreciated roles of these nucleases in biological systems.     

The major apoptotic endonuclease DFF40/CAD is a deoxyribose-specific and double-strand-specific enzyme

DFF40/CAD endonuclease is primarily responsible for internucleosomal DNA cleavage during the terminal stages of apoptosis. The nuclease specifically introduces DNA double strand breaks into chromatin substrates. Here we performed a detailed study on the specificity of the nuclease using synthetic single-stranded and double-stranded ribo- and deoxyribo-oligonucleotides as substrates. We have found that neither single-stranded DNA, single-stranded RNA, double-stranded RNA nor RNA–DNA heteroduplexes are cleaved by the DFF40/CAD nuclease. Noteworthy, all types of oligonucleotides that are not cleaved by the nuclease inhibit cleavage of double-stranded DNA. We have also observed that in cells undergoing apoptosis in vivo neither the activation of DFF40/CAD nor oligonucleosomal chromatin fragmentation was temporally correlated with either total cellular or nuclear RNA degradation. We conclude that DFF40/CAD is exclusively specific for double-stranded DNA. Jakub Hanus and Magdalena Kalinowska-Herok contributed equally to the work.