Fractionation of nucleic acid on benzoylated-naphthoylated DEAE cellulose

Improved dsRNA isolation and purification method validated by viral dsRNA detection using novel primers in Saccharomyces cerevisiae

Accurate genomic sequencing demands high-quality double-stranded RNA (dsRNA). Existing methods for dsRNA extraction from yeast, fungi, and plants primarily rely on cellulose, suitable only for small volume extractions, or the time-consuming lithium chloride precipitation. To streamline the traditional phenol-chloroform-based dsRNA extraction method, the main challenge is the reduction of mitochondrial DNA (mtDNA) and Single Stranded RNA (ssRNA) to no detectable levels after gel electrophoresis. This challenge is successfully addressed through the modified approach described here, involving phenol extraction at low pH, followed by the addition of ammonium sulfate to the aqueous buffer. The dsRNA isolated using this novel method exhibits comparable quality to that obtained through cellulose purification, and it is readily amenable to RT-PCR. Moreover, a single batch of yeast cell RNA isolation requires only 2-3 h of hands-on time, thus simplifying and expediting the process significantly.•Buffers were redesigned from [32,33,35].•No DNASE, Ribonuclease A or beads were used during the purification.•Simple and inexpensive dsRNA extraction and purification method is described.

DNA recombination activity in soybean mitochondria

Mitochondrial genomes in higher plants are much larger and more complex as compared to animal mitochondrial genomes. There is growing evidence that plant mitochondrial genomes exist predominantly as a collection of linear and highly branched DNA molecules and replicate by a recombination-dependent mechanism. However, biochemical evidence of mitochondrial DNA (mtDNA) recombination activity in plants has previously been lacking. We provide the first report of strand-invasion activity in plant mitochondria. Similar to bacterial RecA, this activity from soybean is dependent on the presence of ATP and Mg(2+). Western blot analysis using an antibody against the Arabidopsis mitochondrial RecA protein shows cross-reaction with a soybean protein of about 44 kDa, indicating conservation of this protein in at least these two plant species. mtDNA structure was analyzed by electron microscopy of total soybean mtDNA and molecules recovered after field-inversion gel electrophoresis (FIGE). While most molecules were found to be linear, some molecules contained highly branched DNA structures and a small but reproducible proportion consisted of circular molecules (many with tails) similar to recombination intermediates. The presence of recombination intermediates in plant mitochondria preparations is further supported by analysis of mtDNA molecules by 2-D agarose gel electrophoresis, which indicated the presence of complex recombination structures along with a considerable amount of single-stranded DNA. These data collectively provide convincing evidence for the occurrence of homologous DNA recombination in plant mitochondria.

Linkage-disequilibrium mapping without genotyping

Genomic mismatch scanning (GMS) is a technique that enriches for regions of identity by descent (IBD) between two individuals without the need for genotyping or sequencing. Regions of IBD selected by GMS are mapped by hybridization to a microarray containing ordered clones of genomic DNA from chromosomes of interest. Here we demonstrate the feasibility and efficacy of this form of linkage-mapping, using congenital hyperinsulinism (HI), an autosomal recessive disease, whose relatively high frequency in Ashkenazi Jews suggests a founder effect. The gene responsible (SUR1) encodes the sulfonylurea receptor, which maps to chromosome 11p15.1. We show that the combination of GMS and hybridization of IBD products to a chromosome-11 microarray correctly maps the HI gene to a 2-Mb region, thereby demonstrating linkage-disequilibrium mapping without genotyping.

Genomic mismatch scanning identifies human genomic DNA shared identical by descent

Genomic mismatch scanning (GMS) is a high-throughput, high-resolution identity by descent mapping technique that enriches for genomic DNA fragments that are shared between related individuals. In GMS, DNA heteroduplexes are formed from restriction-digested genomic DNA fragments from two relatives. Mismatch-free DNA heteroduplexes, likely representing DNA shared identical by descent between the two individuals, are relatively purified by depleting the mismatch-containing heteroduplexes using the Escherichia coli mismatch repair proteins and exonuclease. Here, we demonstrate using quantitative microsatellite genotyping that, despite the complexity of the human genome, GMS can enrich the majority of restriction fragments that are identical by descent between two related humans. As the entire genome is selected in GMS, an extraordinarily dense set of markers (up to 200,000 markers) may be screened in parallel. The demonstration of the molecular enrichment of identical DNA fragments in the context of the whole human genome establishes conditions for the application of GMS to human genetics. This forms a frame-work for the further development of GMS as a hybridization-based mapping technique that utilizes DNA microarray technology to map the selected identical by descent DNA fragments.

Genomic mismatch scanning: current progress and potential applications

Genomic mismatch scanning (GMS) is a new method of genetic mapping which attempts to purify and map the regions of identity between two complex genomes in a single test. Identical DNA fragments from two genomic sources are enriched in two steps: (i) after reannealing of the two genomes, heterohybrids are purified by using a combination of a restriction methylase and methylation-sensitive endonucleases, (ii) heterohybrids that contain mismatches are nicked in vitro by the E. coli MutHLS mismatch repair system and are eliminated subsequently from the pool, leaving only mismatch-free heterohybrids. The genomic origin of this selected pool of DNA fragments is then mapped in a single hybridization step onto metaphase chromosomes or ordered DNA arrays. The principal advantages of GMS are (i) it approaches the theoretical limit of mapping power and resolution offered by an arbitrarily dense set of completely informative polymorphic markers and (ii) it results in a great increase in the effective number of informative markers without a corresponding increase in the number of individual tests. Thus, it should provide an efficient method for affected-relative-pair linkage mapping and for linkage disequilibrium mapping. In addition, a variation of GMS may allow rapid genomic scanning for regions of homozygosity-by-descent or somatic loss-of-heterozygosity. The feasibility of GMS has been validated in the 15 mb genome of Saccharomyces cerevisiae. This article discusses the principles of GMS, the application to more complex genomes, and the possible uses of GMS.

Genomic mismatch scanning: a new approach to genetic linkage mapping

Genomic mismatch scanning (GMS) is a new method of genetic linkage analysis that does not require conventional polymorphic markers or gel electrophoresis. GMS is ideally suited to affected-relative-pair mapping. DNA fragments from all regions of identity-by-descent between two relatives are isolated based on their ability to form extensive mismatch-free hybrid molecules. The genomic origin of this selected pool of DNA fragments is then mapped in a single hybridization step. Here we demonstrate the practicality of GMS in a model organism, Saccharomyces cerevisiae. GMS is likely to be applicable to other organisms, including humans, and may be of particular value in mapping complex genetic traits.

Idiotypic characteristics of immunoglobulins associated with systemic lupus erythematosus. Studies of antibodies deposited in glomeruli of humans

Indirect immunofluorescence with monoclonal antibodies to 6 different idiotypes was used to characterize immunoglobulins deposited in the glomeruli of renal biopsy samples from 32 patients with systemic lupus erythematosus (SLE) and 19 patients with nonlupus immune glomerulonephritis. IdGN2 was present in 75% of the biopsy specimens from SLE patients and in 6% of those from patients with non-lupus nephritis; IdGN1 occurred in 38% and 6%, respectively. The other idiotypes were not increased in biopsy samples from patients with SLE. Deposition of IdGN2 was associated with a subendothelial location of Ig and proliferative changes in the glomeruli. In studies of glomerular eluates from 4 immunosuppressed SLE patients, an average of 26% of total Ig and 37% of anti-DNA was composed of IdGN2. Compared with IdGN2- immunoglobulin, IdGN2+ immunoglobulin was enriched in IgG1 in all 4 eluates, and was enriched in high-avidity anti-DNA in 2 eluates. IdGN2 is a marker of antibody subsets that are characteristic of SLE and are associated with severe lupus nephritis.

Detection of replication initiation by a replicon family in DNA of synchronized pea (Pisum sativum) root cells using benzoylated naphthoylated DEAE-cellulose chromatography

Fractionated replicating DNA from pea was obtained from both synchronized cells just starting replication and from carbohydrate-starved cells ending replication. Benzoylated naphthoylated DEAE-cellulose chromatography of pulse-labeled DNA digested with EcoR I gave evidence that a family of replicons initiated replication 45 to 60 min after synchronized cells were released from the G1/S phase boundary. DNA from cells labeled in late S phase, on the other hand, showed no signs of additional replication initiations before entering G2 phase. Results with DNA from both early and late S phase cells comply with a model based on the premise that with short pulses of [(3)H]-thymidine the isotope is localized at replication forks and that longer pulses label both replication forks and recently replicated segments of double-stranded DNA. The model applies only to DNA subjected to fragmentation before chromatography.The results also suggest that benzoylated naphthoylated DEAE-cellulose chromatography is a useful means to isolate origins and replication forks from synchronized plant cells.

Purification of circular DNA using benzoylated naphthoylated DEAE-cellulose

Un-nicked circular DNA can be separated from protein, RNA, and other DNA in a simple three-step protocol consisting of exonuclease III digestion, extraction with benzoylated naphthoylated DEAE-cellulose (BND cellulose) in 1 M NaCl, and alcohol precipitation of the remaining supercoiled DNA. Exonuclease III treatment introduces single-stranded regions into contaminating linear and nicked circular DNA. This DNA, together with most RNA and protein, is adsorbed onto BND cellulose leaving form I DNA in solution. The protocol can be used to purify analytical as well as preparative amounts of supercoiled DNA. This procedure is a substitute for cesium chloride-ethidium bromide gradient ultracentrifugation and gives a comparable yield of pure form I DNA. Other classes of DNA can be isolated by changing the pretreatment step. Selective digestion of linear DNA with lambda exonuclease permits the isolation of both nicked circular and supercoiled DNA while brief heat-induced or alkali-induced denaturation leads to the recovery of rapidly reannealing DNA. In large-scale purifications, the basic protocol is usually preceded by one or more BND cellulose extractions in 1 M NaCl to remove contaminants absorbing UV or inhibiting exonuclease III.

P1 plasmid replication: replicon structure

Bacteriophage P1 lysogenizes Escherichia coli as a unit-copy plasmid. We have undertaken to define the plasmid-encoded elements implicated in P1 plasmid maintenance. We show that a 2081 base-pair fragment of the 90,000 base P1 plasmid confers the capacity for controlled plasmid replication. DNA sequence analysis reveals several open reading frames in this fragment. The largest is shown to encode a 32,000 Mr protein required for plasmid replication. The corresponding gene, repA, has been identified genetically. A set of five 19 base-pair repeats is located upstream from repA; a set of nine similar repeats is located immediately downstream from repA. Each set of repeats, when cloned into pBR322, exerts incompatibility towards a P1 replicon. The upstream set, designated incC, consists of direct repeats that are spaced about two turns of the DNA helix apart; the downstream set, designated incA, consists of nine repeats arranged three in one orientation and six in the other. Spacing between incA repeats were three or four turns of the helix apart. The organization of the plasmid maintenance regions of P1 and the unit-copy sex factor plasmid, F, is strikingly similar. Although the DNA sequences of this region in the two plasmids exhibit little homology, a 9 base-pair sequence that appears four times in the origin region of members of the Enterobacteriaceae also occurs twice as direct repeats in similar positions in P1 and F. This sequence, where it occurs in E. coli, has been postulated to be the binding site for the essential replication protein determined by dnaA. The dnaA protein appears not to be essential for the replication of either plasmid; therefore, the function of the sequence in P1 and F may be regulatory.

The simian-virus-40 large-tumor antigen in replicating viral chromatin. A salt-resistant protein-DNA interaction

The large tumor antigen (T antigen) is a genome regulation protein, coded by simian virus 40, that binds with high affinity to specific binding sites on viral DNA. The specifically bound T antigen is released from these sites in 0.2-0.3 M NaCl. Immunoprecipitation techniques were used to show that T antigen also dissociates in 0.2-0.3 M NaCl from mature viral chromatin but not from replicating viral chromatin. In fact, a considerable fraction of T antigen remains associated with replicating chromatin at NaCl concentrations as high as 1.2 M NaCl when most chromatin proteins, including histones, dissociate. However, T antigen binding to both replicating DNA and mature DNA is sensitive to intercalating drugs such as caffeine and ethidium bromide. We consider the possibility that the unexpectedly tight binding of T antigen to replicating DNA is related to the function that T antigen performs during viral DNA replication.

Structure of E. coli 16S RNA elucidated by psoralen crosslinking

E. coli 16S RNA in solution was photoreacted with hydroxymethyltrimethylpsoralen and long wave ultraviolet light. Positions of crosslinks were determined to high resolution by partially digesting the RNA with T1 RNase, separating the crosslinked fragments by two-dimensional gel electrophoresis, reversing the crosslink, and sequencing the separated fragments. This method yielded the locations of crosslinks to +/- 15 nucleotides. Even finer placement has been made on the basis of our knowledge of psoralen reactivity. Thirteen unique crosslinks were mapped. Seven crosslinks confirmed regions of secondary structure which had been predicted in published phylogenetic models, three crosslinks discriminated between phylogenetic models, and three proved the existence of new structures. The new structures were all long range interactions which appear to be in dynamic equilibrium with local secondary structure. Because this technique yields direct information about the secondary structure of large RNAs, it should prove invaluable in studying the structure of other RNAs of all sizes.

Protein covalently bound to minus-strand DNA intermediates of duck hepatitis B virus

Analysis of duck hepatitis B viral DNA by gel electrophoresis, Southern blotting, and binding to benzoylated naphthoylated DEAE-cellulose showed that a protein is bound to the minus-strand virion DNA as well as to the full-length single strand, minus-strand species, and minus-strand DNA intermediates isolated from replicating complexes present in infected duck liver. By utilizing a modified dideoxynucleotidyl sequencing method, it was shown that the protein is covalently bound to the smallest detectable growing strands (ca. 30 bases) and that minus-strand synthesis begins at a unique site. These results support the notion that the protein may function as a primer for synthesis of the minus-strand DNA.

Genetic analysis of temperature-sensitive mutants which define the gene for the major herpes simplex virus type 1 DNA-binding protein

We have assigned eight temperature-sensitive mutants of herpes simplex virus type 1 to complementation group 1-1. Members of this group fail to complement mutants in herpes simplex virus type 2 complementation group 2-2. The mutation of one member of group 1-1, tsHA1 of strain mP, has been shown to map in or near the sequence which encodes the major herpes simplex virus type 1 DNA-binding protein (Conley et al., J. Virol. 37:191-206, 1981). The mutations of five other members of group 1-1 map in or near the sequence in which the tsHA1 mutation maps, a sequence which lies near the center of UL between the genes for the viral DNA polymerase and viral glycoprotein gAgB. These mutants can be divided into two groups; the mutations of one group map between coordinates 0.385 and 0.398, and the mutations of the other group map between coordinates 0.398 and 0.413. At the nonpermissive temperature mutants in group 1-1 are viral DNA negative, and mutant-infected cells fail to react with monoclonal antibody to the 130,000-dalton DNA-binding protein. Taken together, these data indicate that mutants in complementation groups 1-1 and 2-2 define the gene for the major herpes simplex virus DNA-binding protein, an early gene product required for viral DNA synthesis.

Genome of reticuloendotheliosis virus: characterization by use of cloned proviral DNA

Reticuloendotheliosis virus is an avian type C retrovirus that is capable of transforming fibroblasts and hematopoietic cells both in vivo and in vitro. This virus is highly related to the three other members of the reticuloendotheliosis virus group, including spleen necrosis virus, but it is apparently unrelated to the avian leukosis-sarcoma virus family. Previous studies have shown that it consists of a replication-competent helper virus (designated REV-A) and a defective component (designated REV) that is responsible for transformation. In this study we used restriction endonuclease mapping and heteroduplex analysis to characterize the proviral DNAs of REV-A and REV. Both producer and nonproducer transformed chicken spleen cells were used as sources of REV proviral DNA; this genome was mapped in detail, and fragments of it were cloned in lambdagtWES.lambdaB. The infected canine thymus line Cf2Th(REV-A) was used as a source of REV-A proviral DNA. The restriction maps and heteroduplexes of the REV and REV-A genomes showed that (proceeding from 5' to 3') (i) REV contains a large fraction of the REV-A gag gene (assuming a gene order of gag-pol-env and gene sizes similar to those of other type C viruses), for the two genomes are very similar over a distance of 2.1 kilobases beginning at their 5' termini; (ii) most or all of REV-A pol is deleted in REV; (iii) REV contains a 1.1 kilobase segment derived from the 3' end of REV-A pol or the 5' end of env or both; (iv) this env region in REV is followed by a 1.9-kilobase segment which is unrelated to REV-A; and (v) the helper-unrelated segment of REV extends essentially all of the way to the beginning of the 3' long terminal repeat. Therefore, like avian myeloblastosis virus but unlike the other avian acute leukemia viruses and most mammalian and avian sarcoma viruses, REV appears to be an env gene recombinant. We also found that the REV-specific segment is derived from avian DNA, for a cloned REV fragment was able to hybridize with the DNA from an uninfected chicken. Therefore, like the other acute transforming viruses, REV appears to be the product of recombination between a replication-competent virus and host DNA. Two other defective genomes in virus-producing chicken cells were also cloned and characterized. One was very similar to REV in its presumptive gag and env segments, but instead of a host-derived insertion it contained additional env sequences. The second was similar (but not identical) to the first in its gag and env regions and appeared to contain an additional 1-kilobase inversion of REV-A sequences.

Replication of SV40 chromatin in extracts from eggs of Xenopus laevis

Simian virus 40 (SV40) nucleoprotein complexes were prepared from lytically infected cells and used as primer-templates for DNA replication in protein extracts from Xenopus eggs. We found that nucleoprotein containing replicating SV40 DNA served as primer-template while nucleoprotein with nonreplicating SV40 DNA was ineffective. In vitro DNA synthesis begins with short DNA fragments ("Okazaki fragments") which are, in later steps, joined to give unit length SV40 DNA strands, suggesting that in vivo initiated rounds of replication are completed in vitro in the Xenopus system. This conclusion is supported by a restriction enzyme analysis showing that in vitro DNA synthesis occurs in fragments distal to the SV40 origin of replication. Our studies indicate that SV40 DNA replication in Xenopus extracts can be used an an experimental system to study the biochemistry of replicative DNA chain elongation in vitro.

Restricted subpopulations of DNA antibodies in kidneys of mice with systemic lupus. Comparison of antibodies in serum and renal eluates

Sera from MRL/1, BXSB, and NZB/NZW mice, which develop IgG antibodies to DNA and glomerular deposits of DNA-antiDNA immune complexes, were studied by isoelectric focusing. A large array of IgG antibodies with isoelectric points ranging from pH 5.5--9.0 were found to bind double-stranded DNA. Antibodies with isoelectric points from 8.0--8.5 were significantly more frequent than antibodies focusing in all other pH ranges. In contrast, glomerular eluates from MRL/1 and NZB/NZW mice contained a restricted number of DNA-binding bands, all of which focused at pH 8.0--9.0. Anti-DNA with isoelectric points from pH 8.0--9.0 may be more pathogenic for the kidney than other subpopulations.

Reaction of T7 DNA with a polycyclic aromatic hydrocarbon. Lack of structural perturbation

Bacteriophage T7 DNA reacts uniformly with trans-7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydrobenzo(a)pyrene(anti-BPDE). The reaction product retains the native configuration so that only one site sensitive to S1 nuclease is produced for every 70 anti-BPDE adducts. DNA treated with anti-BPDE is retained on benzoylated naphthoylated DEAE-cellulose even after washing with 1.0 M salt solutions. About 100 adducts per T7 molecule are required for adherence which is not due to breaks or single-stranded regions since adherence is not affected by S1 nuclease treatment. The binding of anti-BPDE reacted DNA to benzoylated naphthoylated DEAE-cellulose is cooperative and requires many residues per bound fragment. Treatment of T7 DNA treated with anti-BPDE with restriction endonuclease yields smaller molecules, still containing adducts, which do not adhere. We interpret these results to mean that reaction with BPDE does not involve deformation of the DNA structure and that the adducts lie in a position which they are readily accessible for interaction with aromatic groups on the column resin.

Resolution of ribonucleic acids by Sepharose 4B column chromatography

Ribonucleic acids were resolved by molecular sieve chromatography on columns of Sepharose 4B. The elution positions of messenger ribonucleic acids were determined by detection of polyadenosine tracts and by support of protein synthesis in a messenger-dependent cell-free system. The elution position of other ribonucleic acid species from the Sepharose 4B was determined by formamide-sucrose density gradient centrifugation. Resolution of ribonucleic acids by this column was not dependent on molecular weight but rather on other properties such as secondary structure or the presence of poly(adenylic acid). The elution profiles of ribonucleic acids on cross-linked Sepharose 4B differed markely from those on conventional Sepharose and appeared to depend on molecular size alone. There was diminished resolution of high molecular weight ribonucleic acids on such columns.

Concatemers of alternating plus and minus strands are intermediates in adenovirus-associated virus DNA synthesis

Replicating DNA molecules of adenovirus-associated virus (AAV) were selectively extracted from KB cells coinfected at 39.5 detrees with a DNA minus, temperature-sensitive mutant of adenovirus 5 (ts125) as helper. Under these conditions AAV DNA replication proceeds normally, but there is little, if any, adenovirus DNA synthesis. An analysis of the replicating molecules in sucrose density gradients reveals that there are AAV DNA intermediates which consist of covalently linked plus and minus DNA strands. Under denaturing conditions, these concatemers are linear single strands whose lengths can reach at least four times the size of the AAV genome. The most abundant concatemeric species is a dimer which presumably exists in vivo as a unit length hairpin. Unit length linear duplexes appear to be immediate precursors of plus and minus progeny strands. These findings are compatible with a self-priming mechanism for the synthesis of AAV DNA.

Fractionation of mammalian DNA on deae-cellulose

Chromatography on a DEAE-cellulose (DE-52) column of native and denatured DNA from P388F cells has been studied. The main bulk of native DNA is eluted at 0.8M NaC1 and a minor fraction is eluted with 0.5N NaOH. The proportion of the DNA components obtained depends on the type of isotopic labelling used and the method of storing of the DNA preparation following isolation. Heat-denatured DNA elutes in 2 M NaC1 mainly within the pH gradient form 0.1 M NH4OH. When native DNA is chromatographed on DEAE-cellulose, a small fraction of the DNA elutes at 0.5 N NaOH. This fraction is double-stranded, as determined by hydroxyapatite chromatography. A similar component predominates, however, when "newly synthesised" DNA is fracionated. The profiles obtained with "newly synthesised" and "template" labelled DNA differ in their undenatured and heat-denatured configurations. The presence of formaldehyde during the chromatography of undenatured DNA leads to an increased homogeneity of the profile and during heat denaturation considerable modifications to the profile are observed. Some of the changes can be explained in terms of a decrease in the heterogeneity of the charge distribution on the DNA. The technique appears to combine a high degree of reproducibility with sensitivity to charge clustering along the DNA.