Immunochemical detection of multiple conformations within a 36 base pair oligonucleotide.

A 36 base pair chimeric oligonucleotide containing a central core of DNA duplex flanked by RNA/DNA hybrid at each end was synthesized. These distinct regions of the oligonucleotide adopt different conformations which were detected with antibody probes. Enzyme linked immunosorbent assays (ELISA) and a gel electrophoresis retardation assay were used to demonstrate the binding of antibodies which recognize B-DNA, Z-DNA and RNA/DNA hybrid. The DNA duplex core of this oligonucleotide adopts the B-conformation in 0.14 M NaCl. In high salt solution (4 M NaCl) the DNA core adopts the Z-conformation. The RNA/DNA hybrid at the ends of the oligomer adopt a conformation which is distinct from both B-DNA and A-RNA.     

Isolation and characterization of DNA-DNA and DNA-RNA.

A simple method for the isolation and characterization of DNA-DNA and DNA-RNA hybrid molecules formed in solution was developed. It was based on the fact that, in appropriate salt concentration, such as 5% Na2HPO4, DNA in either double-stranded (DNA-DNA or DNA-RNA) or single-stranded forms, but not free nucleotides, can bind to diethylaminoethylcellulose disc filters (DE81). Thus tested samples were treated with the single-strand-specific nuclease S1 and then applied to DE81 filters. The free nucleotides, resulting from degrading the single-stranded molecules, were removed by intensive washing with 5% Na2HPO4, leaving only the hybrid molecules on the filters. The usefulness of this method was illustrated in dissociation and reassociation studies of viral (SV40) or cellular (NIH/3T3) DNAs and DNA-RNA hybrid molecules. Using this technique the reassociation of denatured SV40 DNA was found to be a very rapid process. Dissociation studies revealed that the melting curves of tested DNAs were dependent on salt concentration. Thus the melting temperatures (tm) obtained for SV40 DNA were 76 degrees C at 1 X SSC (0.15 M NaCl-0.015 M sodium citrate) and 65 degrees C at 0.1 X SSC, and for NIH/3T3 DNA 82 degrees C at 1 X SSC and 68 degrees C at 0.1 X SSC. MuLV DNA-RNA hybrid molecules were formed by annealing in vitro synthesized MuLV DNA with 70S MuLV RNA at 68 degrees C. The melting temperature of this hybrid in the annealing solution was 87 degrees C. Another important feature of this procedure was that, after being selectively bound to the filters, the hybrid molecules could efficiently be recovered by heating the filters for 5 min at 60 degrees C in 1.5-1.7 M KCl. The recovered molecules were intact hybrids as they were found to be completely resistant to S1 nuclease.     

Characterization of the RNA synthesizing activity of isolated kidney nuclei.

The limiting factor in RNA synthesis by isolated kidney nuclei is RNA nucleotidyltransferase at high salt concentrations but at low salt concentrations template availability becomes limiting. alpha-Amanitin inhibits 85% of the activity at high salt concentrations but only 20-50% of the activity at low salt concentrations. Exogenous DNA is utilized at low salt concentrations [up to 0-1M (NH4)2SO4] but not at high salt concentrations. The effect of increasing salt concentration is mainly to cause an increase in the length of chains synthesized. Initiation rates are not increased by high salt concentrations. The apparent Km for UTP is 8-10 muM at high salt concentrations, indicating that assays performed at low UTP concentrations are likely to give inaccurate results. The activation energy for the reaction at low salt concentration is less than that for the reaction at high salt concentration. The RNA synthesizing capacity of kidney nuclei is dependent on the method of isolation, and preparation by a modification of the Chauveau method (Chauveau et al. 1956) yields the most active nuclei.     

RNase H and RNA-directed DNA polymerase: associated enzymatic activities of murine mammary tumor virus.

The RNA-directed DNA polymerase of murine mammary tumor virus, a type B RNA tumor virus, was purified sequentially through DEAE-cellulose, phosphocellulose (step gradient), and phosphocellulose (linear salt gradient) chromatography followed by glycerol sedimentation centrifugation. During all stages of purification, coincident peaks of RNA-directed DNA polymerase activity, templated by polyribocytidylate-oligodeoxyguanidylate, and RNase H digestion of [3H]polyriboadenylate-polydeoxythymidylate were observed, and both enzymatic activities displayed a cation preference for magnesium. Under conditions that removed adventitiously associated nucleases, RNase H activity was found to co-purify with polymerase. The specificity of this nuclease was assayed with various prepared substrates, which indicated that the polymerase-associated RNase H activity was directed only against the RNA strand of an RNA-DNA hybrid. It is highly probable that RNase H (RNA-DNA hybrid: ribonucleotide-hydrolase, EC 3.1.4..34) and RNA-directed DNA polymerase of type B viruses are associated enzymatic activities analogous to those observed for avian and mammalian type C RNA tumor viruses.     

Hydroxyapatite-mediated transfer of DNA on nitrocellulose filters in dot-hybridization experiments

The method of hydroxylapatite-mediated rapid and effective transfer of DNA onto nitrocellulose filters for following dot-hybridization was elaborated. The analysed DNA occurred initially in diluted and large volume solutions (from 1 to 10 ml) with various composition (2 M NaCl; 4 M LiCl--8 M urea; 4 M CsCl; 5 and 20% sucrose) was adsorbed on hydroxylapatite and quantitatively transferred onto nitrocellulose after hydroxylapatite solubilization in a small volume of acid (usually, 200 microliters of 10% TCA). As exemplified by the hybridization of total rat liver DNA with the plasmid ph22 DNA containing a cluster of sea urchin histone genes, the method presented appears to be not only simple and useful for handling multiple probes of diluted DNA solutions with high concentrations of salts, sucrose and urea but also more sensitive than some convenient DNA dot-hybridization methods.     

Purification of specific adenovirus 2 RNAs by preparative hybridization and selective thermal elution.

A method is described for the preparation isolation of highly purified adenovirus RNA species. Cytoplasmic RNAs from cells infected with adenovirus 2 were selected by hybridization to viral DNA fragments bound to nitrocellulose membranes. A series of washes at elevated temperatures (50-70 degrees) determined conditions at which the true hybrids were stable but non-specific RNA was removed. This temperature has been found to correlate with the base composition of the DNA fragment. After washing at this predetermined temperature, the specific RNA was eluted at 85 degrees. The purity of the eluted RNA was greater than 95% as determined by size, sequence specificity, and template activity in an in vitro protein synthesizing system. The method described should be generally useful for purification of specific RNAs.     

Screening of isolated DNA for sequences released from anchorage sites in nuclear matrix

Isolated chromosomal DNA is associated with polypeptides that are not released from DNA by several methods designed to purify DNA, e.g. treatment with sodium dodecyl sulphate. DNA fragments associated with these very tight DNA/protein complexes show high affinity to nitrocellulose filters in the presence of salt concentrations of 500 mM or greater. Consequently, a fraction of AluI-fragmented native DNA comprising the complexes and 0.2 to 0.3 micron of vicinal DNA can be isolated by one filtration step. This fraction of DNA shows characteristics of residual DNA sequences retained in nuclei after extraction with nucleases and high salt (nuclear matrix). The DNA fragments retained on filters are highly enriched in replicative DNA; and their degree of hybridization with poly(A)+ RNA points to enrichment in actively transcribed sequences. The results support previous work indicating that the very tight DNA/polypeptide complexes co-isolating with DNA under conditions that release other peptide materials from DNA may be anchorage sites of DNA in the nuclear matrix. Moreover, the method described here allows isolation of replicating and actively transcribed DNA sequences directly from isolated total genomic DNA by skipping artefact-prone isolations of the nuclear matrix.     

Polyelectrolyte complexes as a tool for purification of plasmid DNA. Background and development

The demand for highly purified plasmids in gene therapy and plasmid-based vaccines requires large-scale production of pharmaceutical-grade plasmid. Plasmid DNA was selectively precipitated from a clarified alkaline lysate using the polycation poly(N,N'-dimethyldiallylammonium) chloride which formed insoluble polyelectrolyte complex (PEC) with the plasmid DNA. Soluble PECs of DNA with polycations have earlier been used for cell transformation, but now the focus has been on insoluble PECs. Both DNA and RNA form stable PECs with synthetic polycations. However, it was possible to find a range of salt concentration where plasmid DNA was quantitatively precipitated whereas RNA remained in solution. The precipitated plasmid DNA was resolubilised at high salt concentration and the polycation was removed by gel-filtration.     

Extraction of proteins from Saccharomyces cerevisiae ribosomes under nondenaturing conditions

The differential sensitivity of ribosomal proteins to removal by salts has been studied. Proteins were extracted from the large and small subunits of cytoplasmic ribosomes from Saccharomyces cerevisiae by washing the individual subunits with a series of solutions containing increasing concentrations of NH4Cl (0.74-3.56 M) for a defined time (20 min) at 0 degrees C. The molar ratio of magnesium to ammonium ions of 1:40 was maintained to protect the ribosomal subparticles from complete disassembly. Proteins extracted under each salt condition were analyzed for composition by two-dimensional polyacrylamide gel electrophoresis. The relative quantity of each protein was determined. Most proteins were not removed from the ribosomal particle completely by any one condition, but were preferentially enriched in a single fraction. Whereas most proteins could be solubilized, several proteins remained predominantly or exclusively with the final core particle. The kinetics of protein release from both subunits at a single NH4Cl concentration (0.74 M) were also studied. Release of protein was time dependent, i.e., longer extraction generally removed more of the same proteins. However, prolonged treatment (240 min) of subunits, even at the same salt concentration, resulted in removal of additional species of proteins in varying amounts. Among the ribosomal RNA species, only the 5 S RNA species was released from the ribosomal particles upon treatment.     

Hydroxyapatite-mediated transfer of DNA from diluted solutions to nitrocellulose or nylon membranes

Transfer of DNA (from 0.1 to 10 micrograms) from diluted solutions of variable volumes (1-10 ml) and various composition (2 M NaCl; 4 M LiCl, 8 M urea; 4 M CsCl; 20% sucrose) to nitrocellulose or nylon membranes was achieved with the use of hydroxyapatite. This absorbent that binds nucleic acids effectively and independently of ionic strength and composition of solution (except for chelators and phosphate ions) easily dissolves in small volumes of acids (for example, in 10% TCA). This phenomenon provides the opportunity to deliver the acid-insoluble precipitates to membrane filters. After alkaline denaturation on the filter followed by a fixation step (baking or UV irradiation for nitrocellulose or nylon filters, respectively), DNA hybridizes effectively with nick-translated DNA probes. The method is simple, reproducible, sensitive, and useful for working with diluted DNA solutions containing interfering substances.     

DNA-dependent protein kinase catalytic subunit. Structural requirements for kinase activation by DNA ends.

DNA-dependent protein kinase (DNA-PK) is a DNA end-activated protein kinase composed of a catalytic subunit, DNA-PKcs, and a DNA binding subunit, Ku, that is involved in repair of DNA double-stranded breaks (DSBs). We have previously shown that DNA-PKcs interacts with single-stranded DNA (ssDNA) ends with a separate ssDNA binding site to be activated for its kinase activity. Here, the properties of the ssDNA binding site were examined by using DNA fragments with modified ssDNA extensions. DNA fragments with a wide range of ssDNA modifictations activated DNA-PKcs, indicating a relaxed specificity for the chemical structure of terminal nucleotides of a DSB. Methyl substitution of the phosphate backbone impaired kinase activation but not binding, indicating that interaction with the DNA backbone was involved in kinase activation. Experiments with RNA and RNA/DNA hybrid fragments suggested that the discrimination between RNA and DNA ends resides in the double-stranded DNA binding function of DNA-PKcs. DNA fragments exposing only one ssDNA end activated DNA-PKcs poorly, suggesting that DNA-PKcs distinguishes between DSBs and ssDNA breaks by simultaneous interaction with two ssDNA ends. These properties potentially explain how DNA-PKcs can be specifically activated by DSBs but still recognize the diverse chemical structures exposed when DSBs are introduced by ionizing radiation.     

A new method of DNA and RNA transfer onto nitrocellulose filters during blot hybridization

A quick (1-2 hour) method of DNA and RNA transfer onto nitrocellulose filters for subsequent blot-hybridization was elaborated. The main features of the method proposed are, firstly, almost complete exclusion of the mechanical impact on the gel and, secondly, addition to the transfer medium (20 X SSC) of a chaotropic agent, 0.5 M NaClO4. The latter results in a slight dissolution of the gel matrix and, on the other hand, somewhat increases the binding of the nucleic acid to the nitrocellulose. The method shortens significantly the time of DNA or RNA transfer at equal, or even higher, quality of hybridization.