Electrophoretic strand separation of long DNAs with poly (U,G) in agarose gels.

We have found that binding of poly(U,G) to single-stranded DNA decreases its mobility in 0.3% agarose gels. Differential binding to the complementary strands of denatured duplex DNA provides a simple method for strand separation. The method is shown to work with bacteriophage lambda DNA, adenovirus DNA and mtDNA for Tetrahymena pyriformis. In all cases the strand that binds more poly(U,G) in CsCl gradients also binds more in gels. The separated strands can be directly blotted from the gel onto nitrocellulose filters and used for hybridization experiments.     

Proximity of polyriboguanylic acid-reactive sites in mammalian DNA to portions of DNA preferentially hybridizing with cellular RNA

Transcribed portions of mouse nuclear DNA are adjacent to sites reacting preferentially with polyriboguanylic acid [poly(G)]. This spatial relationship was suggested by hybridization of radioactively labeled Ehrlich ascites RNA with denatured mouse DNA, the latter fractionated by centrifugation in CsCl equilibrium density gradients both in the presence and in the absence of various synthetic polyribonucleotides. The fractions of DNA which preferentially reacted with guanylic acid-rich polyribonucleotides hybridized with radioactive RNA to a higher degree than did the bulk of cellular DNA. This ability to react with polyriboguanylic acid-containing polymers was further enhanced by breaking DNA by sonication. No increased tendency for such hybridization was seen with the DNA that preferentially reacted with polyribouridylic acid.     

DNA strand specificity of temporal RNA classes produced during infection of Bacillus subtilis by SP82.

The DNA of the Bacillus subtilis bacteriophage SP82 has been separated into heavy (H) and light (L) fractions by centrifugation in buoyant density gradients in the presence of polyguanylic acid. Competition-hybridization experiments were performed with these separated fractions using RNAs isolated from cells labeled at intervals which account for 80% of the lytic cycle and unlabeled competitor RNAs isolated from phage-infected cells at 2-min intervals throughout infection. The analysis of temporal RNA classes were facilitated by use of a double reciprocal plot of the data. Five temporal classes binding to the H fraction and three binding to the L fraction were detected; the possible existence of an additional class transcribed from the H fraction is discussed. RNA synthesized in the presence of chloramphenicol contains two of the three classes produced from L-DNA and two of the five classes transcribed from H-DNA.     

Fractionated Strands of Bacterial Deoxyribonucleic Acid III. Transformation Efficiencies and Rates of Phenotypic Expression

Preferential binding of guanine-rich ribopolymers to one of the complementary strands of denatured deoxyribonucleic acid (DNA) of Diplococcus pneumoniae permitted the fractionation of the complements in CsCl density gradients. Phenotypic expression of the newly acquired genes for four drug resistances was more rapid in cells transformed by the heavy fractions than in those transformed either by light fractions or by unfractionated DNA. The efficiencies of transformation with the two complements were nearly equal for the four markers tested. Both efficiency and expression results were the same whether we assayed the residual activity or the activity obtained by annealing the fractions with excess recipient DNA.     

Asymmetric Transcription of Bacteriophage Mu-1

The deoxyribonucleic acid (DNA) of bacteriophage Mu-1 can be separated into its complementary strands by poly(U,G) binding and equilibrium centrifugation. DNA-ribonucleic acid (RNA) hybridizations in liquid show that more than 98% of "early" phage-specific RNA and over 96% of "late" messenger species bind to the heavy [poly(U,G)-binding] strand of Mu-1 DNA. A small (1.45%) but significant amount of late RNA binds to the light strand. The significance of this RNA fraction is discussed in connection with the peculiar structure of denatured and reannealed Mu-1 DNA.     

Evidence for a Single-Stranded Adenovirus-Associated Virus Genome: Isolation and Separation of Complementary Single Strands

Single-stranded adenovirus-associated virus type 2 deoxyribonucleic acid (AAV-2 DNA) has been isolated from the virion after enzymatic pretreatment of the particles by heating at 53 C for 1 hr in 0.015 m NaCl plus 0.0015 m sodium citrate in the presence of 1% sodium dodecyl sulfate. Double-stranded AAV-2 DNA present as a marker is not denatured by this treatment. AAV-2 single-stranded DNA is composed of two complementary species which can be separated in neutral CsCl when 5-bromodeoxyuridine has been substituted for thymidine in the DNA. The present report is the first documented instance of the separation of complementary strands of an animal virus DNA.     

Fractionation of microbial DNA strands on poly I-coated kieselguhr

The column chromatographic method employing poly I-coated kieselguhr (IHCK) for partitioning of microbial DNA strands into complementary fractions has been modified for use with AT-type DNAs. Both the original and the modified procedures are given in this paper. DNA sample size may vary from nanograms to milligrams. Partially degraded, denatured DNA specimens (including coliphage T2 DNA) have invariably been separated into two distinct fractions. Comparisons have been made as to the relative length of the separated strands, their base composition and their relative affinity for poly C, in several DNAs with GC contents ranging from 23% (Clostridium perfringens) to 73% (Micrococcus lysodeikticus).     

Redundant DNA of Neurospora crassa

Approximately 20% of the DNA of Neurospora crassa consists of redundant sequences. This is calculated from the reassociation rate of fragmented, denatured DNA as measured by hydroxyapatite column chromatography. The redundant DNA has a complexity of 10⁵ base pairs and a repetition frequency of up to 60 copies per genome. Its buoyant density in CsCl is 1.720 g/ml and its hypochromicity 20–24%. Base composition determination shows 54% GC content like Neurospora nuclear DNA. DNA-RNA hybridization studies indicate that rRNA and tRNA cistrons make up 2.3 and 1.2%, respectively, of the redundant fraction. Pulse-labeled RNA is shown to hybridize with both redundant and unique DNA fractions, suggesting that both fractions are transcribed.This work is supported by a grant from National Science Foundation (GB 8058) and National Institute of Health Research Career Development Award (K3GM31-238).     

Interaction of polyribonucleotides with plant mitochondrial DNA

DNA is extracted from purified mitochondria of potato tubers. This DNA cannot be resolved into two strands by alkaline CsCl gradients in our experiments. Poly (G), poly (U) and poly (I,G) interact with the plant mitochondrial DNA as shown by the marked shift in buoyant density that they produce on denatured DNA. Poly (A) and poly (C) do not lead to detectable interactions in standard conditions whereas a slight fixation of poly (C) occurs at acidic pH. These results suggest that the plant mitochondrial DNA contains d-A and d-C rich clusters and, in a lesser extent, d-G rich clusters.     

Relationship of mRNA from Productively Infected Cells to the Complementary Strands of Adenovirus Type 2 DNA

The complementary strands of adenovirus type 2 (Ad2) DNA were separated by buoyant density gradient centrifugation with poly (U, G). The complementary strand DNA was shown to remain intact through the course of strand separation. The l-strand of Ad2 DNA, appearing in the less dense complex with poly (U, G) in neutral CsCl density gradients, was shown to have a buoyant density in alkaline (pH 12.5) CsCl density gradients which is 2 to 3 mg per ml greater than that of its complement (h-strand). Renaturation of purified complementary strand DNA was observed only in mixtures of h- and l-strand DNA, and then with the second-order reaction rate expected for Ad2 DNA. Hybridization of the complementary strands of Ad2 DNA with cytoplasmic mRNA isolated from infected HeLa cells was performed in liquid phase and analyzed by hydroxylapatite chromatography. Before viral DNA synthesis (6 h after infection), 13 to 18% of the h-strand and 30 to 35% of the l-strand were represented in viral mRNA. Late (18 h) after infection the mRNA represented 20 to 25% and 63 to 68% of the h- and l-strands, respectively. Most, if not all sequences present in viral mRNA before viral DNA synthesis were also present in the cytoplasm late in infection.     

The chromosome of bacteriophage T5 : II. Arrangement of the single-stranded DNA fragments in the T5 and T5st(O) chromosomes

Denatured bacteriophage T5 DNA contains a large number of single-stranded DNA fragments which have been separated by agarose gel electrophoresis and classified as “major” or “minor” species on the basis of their relative abundances (Hayward & Smith, 1972). For further study of these fragments we have centrifuged denatured T5 DNA in CsCl density-gradients in the presence of poly(G). Gel electrophoretic analysis of fractions from these gradients shows that the 37.0 and 13.9 million major fragments of T5⁺ DNA and the 35.3 and 17.2 million of T5st(O) DNA are found in the high buoyant density regions. The other fragments vary in the extent of their interactions with poly(G) and a minor fragment, which has anomalous electrophoretic properties, exhibits the strongest poly(G) interaction.     

Ribonuclease H: a Ubiquitous Activity in Virions of Ribonucleic Acid Tumor Viruses

Ten ribonucleic acid (RNA) tumor viruses grown in five different host cell species and three non-oncogenic viruses from three different virus groups have been examined for ribonuclease H content. Three different substrates were used to assay ribonuclease H: calf thymus [(3)H]RNA-deoxyribonucleic acid (DNA) hybrid prepared with denatured calf thymus DNA and Escherichia coli DNA-directed RNA polymerase, (3)H-polydenylic acid [(3)H-poly(A)] complexed to polydeoxythymidylic acid [poly(dT)], and (3)H-polyuridylic acid [(3)H-poly(U)] complexed to polydeoxyadenylic acid [poly(dA)]. All ten RNA tumor viruses contained ribonuclease H activity which degraded the RNA of both the calf thymus hybrid and poly(A)-poly(dT), whereas only the ribonuclease H in the Moloney strain of murine sarcoma-leukemia virus and in RD-feline leukemia virus hydrolyzed the RNA strand of poly(U)-poly(dA). No appreciable ribonuclease H activity was detected in influenza, Sendai, or vesicular stomatitis virus. The ribonuclease H and RNA-directed DNA polymerase activities in Moloney murine sarcoma-leukemia virus were inseparable by phosphocellulose chromatography or glycerol gradient centrifugation, but appeared to be partially separated by diethylaminoethyl-cellulose chromatography.     

Hybridization maps of early and late messenger RNA sequences on the adenovirus type 2 genome.

Specific fragments of adenovirus type 2 DNA, generated by cleavage with restriction endonucleases endoR.EcoRI, endoR.HpaI and endoR.HindIII were used in hybridization-mapping experiments. The complementary strands of individual cleavage fragments were separated by the method of Tibbetts &; Pettersson (1974). Liquid hybridizations were performed with ³²P-labeled separated strands of cleavage fragments and messenger RNA extracted from cells early and late after adenovirus infection. The fraction of each fragment strand which was represented in “early” and “late” messenger RNA was determined by chromatography on hydroxylapatite. Early messenger RNA was found to be derived from four widely separated regions, two on the 1- and two on the h-strand (h- and l- refer to the strand with heavy and light buoyant density in CsCl when complexed with poly(U, G)). Messenger RNA, present exclusively late after infection, is derived from several locations, predominantly from the l-strand with a major block of continuous sequences extending between positions 0.25 and 0.65 on the unit map of the adenovirus type 2 genome.     

Transcription of the genome of adenovirus type 12. III. Maps of stable RNA from productively infected human cells and abortively infected and transformed hamster cells.

The adenovirus type 12-specific mRNA and the stable nuclear RNA from productively infected KB cells, early postinfection, from abortively infected BHK-21 cells, and from the adenovirus type 12-transformed hamster lines T637 and HA12/7 have been mapped on the genome of adenovirus type 12. The intact separated heavy (H) and light (L) strands of adenovirus type 12 DNA have been used to determine the extent of complementarity of the mRNA or nuclear RNA from different cell lines to each of the strands. More precise map positions have been obtained by the use of the H and L complements of the fragments of adenovirus type 12 DNA which were produced with the EcoRI and BamHI restriction endonucleases. The results of the mapping experiments demonstrate that the mRNA's isolated early from productively and abortively infected and from two lines of transformed cells are derived from the same or similar regions of the adenovirus type 12 genome. The map positions on the adenovirus type 12 genome for the mRNA from the cell lines as indicated correspond to regions located approximately between 0 and 0.1 and 0.74 and 0.88 fractional length units on the L strand and to regions between 0.63 and 0.74 and 0.89 and 1.0 fractional length units on the H strand. The HA12/7 line lacks mRNA complementary to the region between 0.74 and 0.88 fractional length units on the L strand. Similar data are found for the nuclear RNA, except that the regions transcribed are more extensive than those observed in mRNA. The polarity of the H strand has its 3'-end on the right terminus in the EcoRI A fragment, and the L strand has its 3'-end on the left terminus in the EcoRI C fragment. Thus, the H strand is transcribed from right to left (1 = leftward strand); and the L strand is transcribed from left to right (r = rightward strand). The designations H and L refer to the relative heavy and light densities of the two strands in polyuridylic-polyguanylic acid-CsCl density gradients. The EcoRI C-H and D-H complements have been shown to be part of the intact L strand; thus, there is a "reversal in heaviness" on the left terminus of the viral DNA.     

A method for gene enrichment based on the avidin-biotin interaction. Application to the Drosophila ribosomal RNA genes.

A method of enriching, from the total DNA of an organism, for long DNA strands carrying a particular gene is described. The purified RNA corresponding to the gene is covalently attached to biotin via a cytochrome c bridge. This modified RNA is hybridized to the total DNA. Those DNA strands which hybridize are separated from all the other DNA, using the avidin-biotin interaction, by one of two methods. Avidin is covalently attached to submicroscopic polymer spheres; the complexes of avidin spheres with the DNA: RNA-biotin hybrids band in CsCl at a much lower buoyant density than does free DNA. Alternatively, the DNA:RNA-biotin hybrids are isolated by affinity chromatography on an avidin-solid support column. These methods have been used to prepare long single strands of Drosophila ribosomal DNA (rDNA) in high yield and 42 to 80% pure.     

Purification of RNA-DNA hybrids by exclusion chromatography.

A simple method for selection of RNA-DNA hybrids has been developed and applied to the purification of adenovirus-specific messenger RNA. Cytoplasmic RNA prepared from adenovirus type 2 (ad2)-infected HeLa cells or from an ad2-transformed rat cell line was hybridized in solution to the complementary strands of ad2 DNA. The hybridization mixture was subsequently fractionated by chromatography on a Sepharose 2B column. The intact probe DNA as well as the RNA-DNA hybrids are excluded from the gel matrix and elute with the void volume. Nonhybridized RNA, in contrast, is included into the gel matrix and elutes as a broad peak well separated from the excluded fractions. Fractions corresponding to the void volume, were collected and the RNA-DNA hybrids were denatured in 90% formamide. The selected RNA was separated from the DNA by affinity chromatography on poly(U)-Sepharose. Restriction endonuclease fragments of DNA with a large enough size to make them excluded from the agarose column were also used for hybridization. In these experiments hybridizations were carried out under conditions which would allow R-loop formation (Thomas, M., White, R.L., and Davis, R.W. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 2294-2298) and the hybridized RNA was separated from unhybridized RNA by Sepharose chromatography. The validity of the method was demonstrated by programming an in vitro protein-synthesizing system with selected RNA.     

Replication of the DNA of chick embryo lethal orphan virus

Replication of the DNA of chick embryo lethal orphan virus was semi-conservative. In CsCl density gradients a portion of pulse-labelled intracellular viral DNA was more dense than mature DNA and sometimes approached the density of denatured DNA. Chromatography on benzoylated naphthoylated DEAE-cellulose also suggested that replicating viral DNA had extensive single-stranded regions. In neutral sucrose, some pulse-labelled viral DNA sedimented faster than mature DNA. Short pulses of [³H]thymidine were incorporated into fragments that sedimented at about 12 s in alkaline sucrose. As the pulse length was increased, label was found in material that sedimented faster than 12 s fragments but more slowly than the strands of mature viral DNA, and finally in full length viral DNA strands. During a “chase” in unlabelled medium, pulse-labelled intracellular viral DNA was converted to a form with properties like those of mature DNA. No closed circular structures could be detected when pulse-labelled DNA was centrifuged in CsCl in the presence of ethidium bromide. Thus the replication of this DNA, which is linear and lacks terminal repetitions detectable by exonuclease digestion and annealing, does not involve circles or concatemers in which one or both strands are continuous. However, the 5′ ends of the daughter strands cannot be completed unless the nascent DNA forms a maturation intermediate, the most likely form of which is a concatemer with staggered nicks in both strands at one genome intervals. This implies an unusual structure of the ends of the DNA, or the existence of a protein that interacts with the ends.