Separation of complementary strands of plasmid DNA using the biotin-avidin system and its application to heteroduplex formation and RNA/DNA hybridizations in electron microscopy.

A method for the separation of complementary strands with the help of the biotin-avidin system is described. Restriction fragments were terminally labeled at both ends with biotinylated nucleotides. The DNA was cut by a second restriction enzyme, and the fragments were bound to an avidin agarose column. The non-biotinylated strands were eluted with 0.1 M NaOH, and the biotin-labeled strands were subsequently released from the column by elution with 50% guanidine isothiocyanate/formamide. Contamination of the separated strands by complementary single strands was less than 4%.-Separated linear single strands of the vector pEMBL were prepared. On annealing with recombinant circular DNA a substitution loop is formed which provides position and orientation markers for the unambiguous electron microscopic analysis of heteroduplexes or hybrids formed with the inserted sequences. -The terminal biotin label was visualized by complex formation with a streptavidin-ferritin conjugate.     

Reassociation of complementary strand-specific adenovirus type 2 DNA with viral DNA sequences of transformed cells.

Complementary strand-specific adenovirus DNA, either full length or from restriction enzyme cleavage fragments, was used to estimate the fractional representation and abundance of viral sequences in two adenovirus type 2 (Ad2)-transformed rat cell lines, A2F19 and A2T2C4. The reassociation method introduced is based on the linear relationship, after exhaustive hybridization, between the inverted fraction of hybrid DNA and the molar ratio of probe to cellular DNA in the reaction mixture. The amount of viral DNA in A2F19 cells represents 12 to 14% of the viral genome at a level of around seven copies per diploid cell equivalent. For the cell line A2T2C4, the pattern of integrated viral DNA sequences is more complex. With full-length Ad2 DNA strands as a probe, about 56% of the probe was represented in cellular DNA. When each of the four BamHI fragment strands of Ad2 DNA was used as a probe, the fraction of the viral DNA present also amounted to around 56% with one to five copies from different regions of the viral genome. The results demonstrate the advantage of using strand-specific viral DNA as a probe in reassociation analysis with denatured cell DNA. The method should be useful in any system in which complementary strand separation of viral DNA sequences can be achieved.     

Strandedness of newly synthesized short pieces of polyoma DNA from isolated nuclei.

The discontinuous synthesis of the complementary strands of polyoma DNA in isolated nuclei has been studied by hybridization techniques. The relative amounts of the newly synthesized complementary strands were compared by separately annealing them to denatured HpaII restriction fragments. In every case an excess (1.4- to 2.4-fold) of short pieces of the strand growing in the 3' leads to 5' direction was found.     

Complementary strand-specific sequences from unique fragments of adenovirus type 2 DNA for hybridization-mapping experiments

Separation of the complementary strands of adenovirus type 2 DNA by poly(U,G)-CsCl density gradient centrifugation permitted studies of Ad2³ DNA renaturation with independently variable concentrations of each complementary strand. Single-stranded DNA was isolated by hydroxylapatite chromatography following exhaustive incubation under such conditions, and was found to selectively represent sequences of the complement present in excess during the incubation. This result was exploited in a general method for isolation of complementary strand-specific sequences of radioactively labeled Ad2 DNA or restriction enzyme fragments of Ad2 DNA. Liquid phase saturation-hybridization experiments were carried out with labeled DNA representing each complementary strand of the six endo R.EcoRI cleavage fragments of Ad2 DNA and unlabeled messenger RNA prepared from HeLa cells late after productive infections with Ad2. The results were combined with the known endo R.EcoRI cleavage map of Ad2 DNA to construct a low-resolution map showing physically separated regions, on both complementary strands of Ad2 DNA, represented in mRNA late after infection.     

Genomic DNA regions whose complementary strands are prone to UV light-induced crosslinking

We prepared an extensive set of DNA restriction fragments, irradiated them with UV light, and detected crosslinked complementary strands by electrophoresis in denaturing agarose gels. These experimental data were quantified by densitometry to determine tetranucleotide contributions to crosslinking. The tetranucleotide contributions were used to predict genomic maps of the crosslinking probability that permitted us to identify two strongly crosslinking genomic regions having 295 and 389 base pairs in length. The two sequences shared the (ATTTTATA).(TATAAAAT) octamer, which is a candidate for the hotspot of UV light-induced crosslinking between the complementary strands of DNA.     

Preparative separation of the complementary strands of DNA restriction fragments by alkaline RPC-5 chromatography.

High pressure reversed phase chromatography (RPC-5) at pH 12 was used for preparative separation of the complementary strands of the smaller DNA fragments which are generated by the Hae III restriction endonuclease digestion of Col El DNA. A single high pressure RPC-5 chromatographic step at neutral pH served to purify duplex fragments 70, 172, 250 and 440 base pairs long; each of these yielded two elution peaks upon chromatography under alkaline denaturing conditions.     

Separation of the complementary strands of double-stranded cucumber mosaic virus-associated RNA 5 and peanut stunt virus-associated RNA 5

The double-stranded forms of CARNA 5 and PARNA 5, viral satellites of the cucumovirus group, after denaturation and polyacrylamide gel electrophoresis under appropriate conditions allow their complementary strands to be separated and fractionated. These fractionated (+) and (-) strands are free of contaminating viral RNA fragments. They serve as templates for the preparation of cDNAs of opposite polarity, which are used to probe the viral RNA-dependent replication of CARNA 5 and PARNA 5.     

Preparation of large quantities of separated strands from simian virus 40 DNA restriction fragments by low-temperature low-salt agarose gel electrophoresis.

We have used agarose gel electrophoresis to separate complementary DNA strands obtained from simian virus 40 DNA restriction fragments produced by HindII and III or by EcoRI and HpaII digestion. By modifying existing methods we have virtually eliminated the problematic renaturation of DNA during electrophoresis. This has allowed us to recover large quantities of separated DNA strands (approximately 20 μg of DNA per 12-mm-diameter preparative tube gel). By using a combination of low temperature and low buffer concentration during electrophoresis, we have also significantly improved the resolution of DNA strands.     

Crosslinking of the complementary strands of DNA by UV light: dependence on the oligonucleotide composition of the UV irradiated DNA

UV light crosslinks the complementary strands of DNA. The interstrand crosslinks may contribute to the biological and pathological effects that UV irradiation is known to bring about. Here alkaline agarose gel electrophoresis was used to assess the crosslinked fraction of 31 selected restriction fragments of six viral and plasmid DNA molecules exposed to UVC light irradiation. As many as 17 independent experiments were performed with the particular DNA fragments to get sufficiently precise data suitable for quantitative analyses. The data were used to determine how the crosslinked fraction depended on the dinucleotide, trinucleotide and tetranucleotide contents of the irradiated DNA fragments. This analysis demonstrated that DNA conformation and/or flexibility, rather than the local double helix thermostability, governed the phenomenon of crosslinking. For example, (GA).(TC) suppressed the crosslink formation in DNA more than any dinucleotide composed of only G and C. In addition, (CTAG).(CTAG) promoted crosslinking much more than any other tetranucleotide, including e.g. (TATA).(TATA), whereas the closely related (CATG).(CATG) belonged among the tetranucleotides that most suppressed the UV light induced crosslinks between the complementary strands of DNA. The present data reproduced crosslinking of the analyzed 31 restriction fragments with a correlation coefficient exceeding 0.90. This result will be useful to predict crosslinking along the whole human genome.     

Transcription map for adenovirus type 12 DNA.

The regions of the adenovirus type 12 genome which encode l- and r-strand-specific cytoplasmic RNA were mapped by the following procedure. Radioactive, intact, separated complementary strands of the viral genome were hybridized to saturating amounts of unlabeled late cytoplasmic RNA. The segments of each DNA strand complementary to the RNA were then purified by S1 nuclease digestion of the hybrids. The arrangement of the coding regions of each strand was deduced from the pattern of hybridization of these probes to unlabeled viral DNA fragments produced by digestion with EcoRI, BamHI, and HindIII.. The resulting map is similar, if not identical, to that of adenovirus type 2. The subset of the late cytoplasmic RNA sequences which are expressed at early times were located on the map by hybridizing labeled, early cytoplasmic RNA to both unlabeled DNA fragments and unlabeled complementary strands of specific fragments. Early cytoplasmic RNA hybridized to the r-strand to EcoRI-C and BamHI-B and to the l-strand of BamHI-E. Hybridization to BamHI-C was also observed. The relative rates of accumulation of cytoplasmic RNA complementary to individual restriction fragments was measured at both early and late times. Early during infection, most of the viral RNA appearing in the cytoplasm was derived from the molecular ends of the genome. Later (24 to 26 h postinfection) the majority of the newly labeled cytoplasmic RNA was transcribed from DNA sequences mapping between 25 and 60 map units on the genome.     

Evaluation and comparison of random amplification of polymorphic DNA, pulsed-field gel electrophoresis and ADSRRS-fingerprinting for typing Serratia marcescens outbreaks

Amplification of DNA fragments surrounding rare restriction sites (ADSRRS-fingerprinting) is a novel assay based on suppression of polymerase chain reaction (PCR). This phenomenon allows the amplification of only a limited subset of DNA fragments, since only those with two different oligonucleotides ligated at the ends of complementary DNA strands are amplified in the PCR. The DNA fragments can be easily analyzed on polyacrylamide gels, stained with ethidium bromide. We have implemented this method using a set of clinical Serratia marcescens isolates from three outbreaks ongoing in the Public Hospital in Gdańsk (Poland). Clustering of ADSRRS-fingerprinting data matched epidemiological, microbiological, random amplification of polymorphic DNA (RAPD) and pulsed-field gel electrophoresis (PFGE) data. Based on this study, we found that there is at least a similar power of discrimination between the present 'gold-standard' PFGE and the novel method, ADSRRS-fingerprinting. Although the ADSRRS-fingerprinting method may appear to be more complex than the RAPD technique, we found it fast and reproducible.     

Generalized Poland-Scheraga model for DNA hybridization

The Poland-Scheraga (PS) model for the helix-coil transition of DNA considers the statistical mechanics of the binding (or hybridization) of two complementary strands of DNA of equal length, with the restriction that only bases with the same index along the strands are allowed to bind. In this article, we extend this model by relaxing these constraints: We propose a generalization of the PS model that allows for the binding of two strands of unequal lengths N1 and N2 with unrelated sequences. We study in particular (i) the effect of mismatches on the hybridization of complementary strands, (ii) the hybridization of noncomplementary strands (as resulting from point mutations) of unequal lengths N1 and N2. The use of a Fixman-Freire scheme scales down the computational complexity of our algorithm from O(N1(2)N2(2) to O(N1N2). The simulation of complementary strands of a few kilo base pairs yields results almost identical to the PS model. For short strands of equal or unequal lengths, the binding displays a strong sensitivity to mutations. This model may be relevant to the experimental protocol in DNA microarrays, and more generally to the molecular recognition of DNA fragments. It also provides a physical implementation of sequence alignments.     

Two-dimensional gel electrophoretic method for mapping DNA replicons.

We describe in detail a method which allows determination of the directions of replication fork movement through segments of DNA for which cloned probes are available. The method uses two-dimensional neutral-alkaline agarose gel electrophoresis followed by hybridization with short probe sequences. The nascent strands of replicating molecules form an arc separated from parental and nonreplicating strands. The closer a probe is to its replication origin or to the origin-proximal end of its restriction fragment, the shorter the nascent strands that are detected by the probe. The use of multiple probes allows determination of directions of replication fork movement, as well as locations of origins and termini. In this study, we used simian virus 40 as a model to demonstrate the feasibility of the method, and we discuss its applicability to other systems.     

Reassociation rate limited displacement of DNA strands by branch migration.

Large branched DNA structures are constructed by two-step reassociation of separated complementary strands from restriction fragments of different lengths. The displacement of DNA strands initially annealed to longer complementary DNA sequences, a process mediated by branch migration, is very rapid and has thus far been followed only under conditions which are second order, DNA reassociation rate limiting. The average lifetime of branched DNA leading to displacement of 1.6 Kb strands is estimated to be less than 10 seconds under conditions of DNA reassociation, Tm-25 degrees C. Several DNA-binding drugs, including intercalating dyes, have been tested to determine their influence, if any, on the kinetics of DNA strand displacements by branch migration. Only actinomycin D was found to have significant effect under the conditions we have described. The kinetics of the strand displacement in the presence of low concentrations of actinomycin D remain second order and slower rate of strand displacement must be attributed to decreased rate of reassociation of DNA strands to form the branched intermediates. Consideration is given to the potential manipulation of DNA structures at site-directed branches and the limitations due to rapid strand displacements. The feasibility of constructing sufficiently large branched DNA regions to approach first order, branch migration rate limiting kinetics is also discussed.     

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.     

Two strands of DNA are not equivalent as probes in hybridizations at low stringency

Only one of the two complementary strands of a restriction fragment hybridizes under low stringency conditions to a cloned Arabidopsis thaliana genomic DNA fragment. We propose that this effect is caused by the energetic nonequivalence of the two possible mismatched duplexes, resulting from the accumulation of mismatches and extrahelical bases. These mismatches will differ between the two duplexes. The choice of probe strand may therefore be important for the success of heterologous hybridizations utilizing single-stranded probes.     

Improved method for detecting poliovirus negative strands used to demonstrate specificity of positive-strand encapsidation and the ratio of positive to negative strands in infected cells.

We have developed a ribonuclease protection method suitable for sensitive detection of an RNA species in the presence of a large excess of its complementary strand, as for the detection of negative strands of positive-strand RNA viruses. By using this method to probe for poliovirus negative strands in virions, we found that positive strands are present in at least 40,000-fold excess over negative strands. Thus, we have confirmed that poliovirus encapsidation is highly specific for positive strands and have demonstrated that the genome-linked protein VPg, which is covalently attached to the 5' ends of both positive and negative strands, cannot be the sole determinant of RNA packaging. We tested the ratios of viral positive strands to negative strands in cells at different times during infection; this value ranged from approximately 40/1 to 70/1, being highest at 4 h and lower at 2 and 6 h postinfection.