Superhelical Escherichia coli DNA: relaxation by coumermycin.

A class of compounds of the form: NH₂NHCO(CH₂)_nC(OR)₂CHR′X has been designed to allow selective blocking of specific genetic sequences of DNA and RNA (Summerton, unpublished data). This paper describes the synthesis and use of 6-bromo-5,5-dimethoxyhexanohydrazide for such site-specific inactivation. In model reactions it is shown that this compound can be attached to the C-4 position of cytidine and that, after activation, the cytidine-bound agent crosslinks to the N-7 position of guanosine. This reaction sequence has been applied to the crosslinking of bacteriophage T7 RNA to its complementary DNA in a highly specific fashion. The RNA is derivatized with the hydrazide reagent, activated, and incubated under annealing conditions with the complementary DNA, resulting in crosslinks between the two strands that are stable to denaturing conditions, dependent on the presence of the crosslinking agent, and specific for the complementary DNA sequence. These studies show that the title compound is a promising sequence-specific blocking agent for nucleic acids. The capability of introducing site-specific blocks in DNA and RNA in this way may have a wide variety of applications in the study of genetic processes. In particular, the combination of this compound with appropriate restriction fragments may enable systematic mapping and characterization of viral genomes.     

DNA crosslinks,single-strand breaks and effects on bacteriophage T4 survival from tritium decay of [2-3H]adenine, [8-3H]adenine and [8-3H]guanine

Escherichia coli and bacteriophage T4 DNA containing [2-³H]adenine accumulated crosslinks between the complementary strands. For T4 DNA stored in frozen solution there were 0.41 to 0.54 crosslinks formed per tritium decay. The crosslinks were demonstrated both by an increased DNA sedimentation rate in alkaline sucrose gradients and by an increasing amount of DNA that renatured quickly after denaturation by heat or alkali. Single-strand breaks were also formed with an efficiency of 0.08 to 0.50 breaks per tritium decay. DNA containing both [8-³H]adenine and [8-³H]guanine showed no crosslinking but did undergo single-strand breaks at a rate of 0.08 per tritium decay. T4 bacteriophage containing [2-³H]adenine lost plaque-forming ability when stored at 4 °C, with 0.34 lethal hits per tritium decay, whereas the same phage labeled with a mixture of [8-³H]adenine and [8-³H]guanine sustained only 0.12 lethal hits per tritium decay. The loss of plaque-forming ability in the latter case is probably due to a radiation effect from the emitted beta particle; the high lethal efficiency for tritium decay at 2-adenine is probably caused either by crosslinks between complementary strands or from some undetected lesion produced in the DNA.     

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.     

Arrangement of nucleotide sequences in adeno-associated virus DNA

There are two types of adeno-associated virus virions which contain complementary single-stranded DNA genomes of about 1.4 × 10⁶ daltons. The purified complementary single polynucleotide chains anneal to form duplex linear monomers, circular monomers, and linear dimers, in addition to other less well-defined structures, as identified by sedimentation and electron microscopy. All duplex species are formed by linear single polynucleotide chains of unit length, thus duplex circles and linear dimers are assumed to be held together by relatively short overlapping hydrogen-bonded regions. The initial linear monomers present after annealing the complementary single strands do not form duplex circles or oligomers when re-exposed to annealing conditions, but DNA which sediments as linear monomers after heating linear dimers at a temperature from 7 to 25 deg. C below the T_m of duplex AAV² DNA does re-form oligomers and circles when exposed to annealing conditions. Denaturation and reannealing of any duplex species leads to the formation of all forms, indicating that the over-all single strand composition of all species is equivalent. Disruption of duplex circles by limited exonucleolytic digestion using either 3′ or 5′ exonucleases leads to the conclusion that the overlap region may have either 3′ or 5′ termini and that the overlap region represents less than 6% of the length of the genome. Exonucleolytic digestion of linear monomers to the extent of 50% leaves polynucleotide chains which cannot reanneal after denaturation, thus AAV DNA is not randomly circularly permuted. Duplex linear monomers which do not form circles when exposed to annealing conditions do form duplex circles after 1% exonuclease III digestion. A model consistent with these data is one in which the linear single polynucleotide chains present in AAV virions consist of two or more permutations. All of these chains contain terminal repetitions and their start points occur within a limited region, representing < 6% of the length of the genome. According to this interpretation AAV DNA would exist within the virion as a linear single polynucleotide chain or is cleaved at a few specific sites during extraction.     

Interaction of poly(I)·poly(C) with trans-dichloro-diammine-platinum (II)

The covalent binding of trans-Pt (NH₃)₂Cl₂ to the double-stranded poly(I)·poly(C) follows three types of reactions, depending on r_b and the concentration of polynucleotide in the reaction mixture. At r_b ? 0.1, the principal reaction is coordination to poly(I), giving rise to some destabilization of the double strand, as shown by uv and CD spectra, and a decrease in T_m values, giving rise to free loops of poly(C). At higher r_b and low polynucleotide concentration, the free cytidine bases react with platinum bound on the complementary strand to form intramolecular (interstrand) crosslinks that restabilize the double-stranded structure. At high r_b and high polynucleotide concentration, while the above reaction still occurs, the predominant one is the formation of intermolecular crosslinks. Under no conditions has strand separation been observed.     

Characterization of a rearrangement in viral DNA: mapping of the circular simian virus 40-like DNA containing a triplication of a specific one-third of the viral genome

Serial passage of the non-defective form of a simian virus 40-like virus (DAR) isolated from human brain results in the appearance of three distinct classes of supercoiled DNAs: R_I resistant, R_I sensitive (one cleavage site) and R_I “supersensitive” (three cleavage sites). The R_I cleavage product of the “super sensitive” form is one-third the physical size of simian virus 40 DNA (10.4 S) and reassociates about three times more rapidly than “standard” viral DNA. To identify the portions of the DAR genome present in the 10.4 S segment, the plus strand of each of the 11 fragments of ³²P-labeled simian virus 40 DNA, produced by cleavage with the Hemophilus influenzae restriction endonuclease, was hybridized in solution with the sheared R_I cleavage product of the “supersensitive” class of viral DNA. Reaction was observed with fragments located in two distinct regions of the simian virus 40 genome: (1) Hin-A and C; (2) Hin-G, J, F and K.Further studies indicated that simian virus 40 complementary RNA transcribed in vitro with Escherichia coli RNA polymerase from one strand of simian virus 40 DNA reacts with both strands of the denatured 10.4 S cleavage product when hybridization is monitored with hydroxyapatite. Treatment of the 10.4 S DNA-simian virus 40 cRNA hybrid with the single-strand spcific nuclease, S₁, converted approximately 50% of the radioactive counts to an acid-soluble product. These results indicate that the 10.4 S product contains a transposition of sequences originally present on one of the DAR DNA strands to the other strand. Examination of heteroduplexes formed between the 10.4 S segment and unique linear forms of DAR DNA produced with the R · Eco RI restriction endonuclease have confirmed these observations. Thus it appears that a molecular rearrangement(s) has resulted in the recombination and inversion of viral DNA sequences from two separate loci on the parental DAR genome. This 1.1 × 10⁶ dalton segment is reiterated three times in a supercoiled molecule equivalent in physical size to parental DAR DNA.     

Construction of viable and lethal mutations in the origin of bacteriophage 'phi' X174 using synthetic oligodeoxyribonucleotides

Six different synthetic deoxyhexadecamers complementary to the origin of bacteriophage φX174, corresponding to nucleotides 4299 to 4314, except for one preselected nucleotide change were used as primers for DNA synthesis on wild-type φX² DNA as a template. DNA synthesis was performed with Escherichia coli DNA polymerase I (Klenow fragment) in the presence of DNA ligase. Heteroduplex RFIV DNA was isolated and, after limited digestion with DNAase I, complementary strands containing the mutant primers were isolated. The biological activity of these complementary strands was assayed in spheroplasts. Spheroplasts were made from E. coli K58 ung^? (uracil N-glycosylase) to prevent degradation of the complementary strands caused by uracil incorporation (Baas et al., 1980a).Using (5′-³²P) end-labeled primers, it was shown that all tested DNA polymerase preparations, including phage T4 DNA polymerase, contained variable amounts of 5′ → 3′ exonuclease activity. This nick translation activity may result in removal of the mutation in the primers, and therefore in isolation of wild-type complementary DNA instead of mutant complementary DNA.Restriction enzyme analysis of completed RFIV DNA showed that the primers can initiate DNA synthesis at more than one place on the φX174 genome. These complications result in a mixed population of complementary strand DNAs synthesized in vitro. Nevertheless, the desired mutants were picked up with high frequency using a selection test that is based on the difference in ultraviolet light sensitivity of homoduplex and heteroduplex φX174 RF DNA. Heteroduplex φX174 RF DNA is two to three times more sensitive to ultraviolet light irradiation than is homoduplex φX174 RF DNA (Baas &; Jansz, 1971,1972). Phage DNA derived from single plaque lysates of two of the six mutant complementary strand DNA preparations yielded, after annealing with wild-type complementary strand DNA, heteroduplex DNA with high frequency. DNA sequence analysis in the origin region of RF DNA obtained from these two phage preparations revealed the presence of the expected mutation. RFI DNA of these two origin mutants was nicked by φX174 gene A protein in the same way as wild-type φX174 RFI DNA.Phage DNA derived from single plaque lysates of the other four mutant complementary strand DNA preparations yielded exclusively homoduplex DNA after annealing with wild-type complementary strand DNA. It is concluded that priming with these deoxyhexadecamers resulted in the synthesis of complementary φX174 DNA with lethal mutations. The implications of these results, the construction of two silent, viable φX174 origin mutants and the failure to detect four others, for the initiation mechanism of φX174 RF DNA replication are discussed.     

Xpf and Not the Fanconi Anaemia Proteins or Rev3 Accounts for the Extreme Resistance to Cisplatin in Dictyostelium discoideum

Organisms like Dictyostelium discoideum, often referred to as DNA damage “extremophiles”, can survive exposure to extremely high doses of radiation and DNA crosslinking agents. These agents form highly toxic DNA crosslinks that cause extensive DNA damage. However, little is known about how Dictyostelium and the other “extremophiles” can tolerate and repair such large numbers of DNA crosslinks. Here we describe a comprehensive genetic analysis of crosslink repair in Dictyostelium discoideum. We analyse three gene groups that are crucial for a replication-coupled repair process that removes DNA crosslinks in higher eukarya: The Fanconi anaemia pathway (FA), translesion synthesis (TLS), and nucleotide excision repair. Gene disruption studies unexpectedly reveal that the FA genes and the TLS enzyme Rev3 play minor roles in tolerance to crosslinks in Dictyostelium. However, disruption of the Xpf nuclease subcomponent results in striking hypersensitivity to crosslinks. Genetic interaction studies reveal that although Xpf functions with FA and TLS gene products, most Xpf mediated repair is independent of these two gene groups. These results suggest that Dictyostelium utilises a distinct Xpf nuclease-mediated repair process to remove crosslinked DNA. Other DNA damage–resistant organisms and chemoresistant cancer cells might adopt a similar strategy to develop resistance to DNA crosslinking agents.     

Preparation of AzoDNA and its use in affinity chromatography

A limited coupling reaction between 4-diazobenzoic acid ([¹⁴C]carboxyl) and sheared single-stranded DNA was employed to prepare a ligand capable of bonding covalently with aminopentane Sepharose C1-4B. The ligand AzoDNA demonstrated small changes in ultraviolet absorbance spectra yet, unlike the parent DNA, had a distinct fluorescence emission peak at 400 nm when excited at 292 nm in neutral or alkaline solutions. On hydroxyapatite thermal chromatography the AzoDNA eluted as single-stranded DNA, while following catalytic reduction, the associated fluorescence and [¹⁴C]azobenzoate radioactivity were removed in large part from the derivatized DNA. In the coupling reaction, prior derivatization of the ligand DNA was required for covalent bonding to aminopentane Sepharose C1-4B and, at optimal polydeoxynucleotide concentrations, about 75 μg was bound/ml of packed gel. DNA:DNA hybridization reactions were accomplished using AzoDNA aminopentane Sepharose C1-4B gels with 50% of the hybridized polynucleotide strands being eluted at temperatures approximating the T_m values measured optically. The use of the AzoDNA gel was extended to the hybridization of adenovirus 2 and vaccinia complementary RNA. The viral complementary RNAs were specifically bound to matrices containing the homologous AzoDNA and eluted under conditions consistent with destabilization of RNA:DNA hybrids. These applications indicate the potential utility of AzoDNA-extensor arm affinity chromatography for the isolation of specific viral RNA molecules.     

X-ray diffraction studies on cation-collapsed DNA

The polyamines spermidine, spermine and putrescine are now known to induce tertiary collapse of DNA. In this collapsed state DNA assumes a compact toroidal conformation. However, the structural details of DNA in these compact particles and the forces that stabilize the collapsed state are not clear. We show here that the structural arrangement of DNA in this tertiary conformation is determined by the chemical structure of the agent used to collapse. We have used aliphatic triamines (NH₃⁺-(CH₂)₃-NH₂⁺-(CH₂)_n-NH₃⁺ with n = 3, 4, 5 and 8) and diamines (NH₃⁺-(CH₂)_x-NH₃⁺ with x = 2, 3, 4 and 6) to collapse DNA. We find that the Bragg spacing and the calculated interhelical spacing for a hexagonal packing model vary systematically with the length of the methylene bridge. We also find that the ionic strength of the solution has no effect on the Bragg spacing. This observation suggests that the arrangement of DNA strands in the complexes is determined by the structure of the polycation, and argues against suggestions that the structure of the collapsed state is maintained by the balance of long-range electrostatic repulsive and attractive forces. Instead we propose that DNA helices form a hexagonal array with counterions in the interstices between the helices resulting in a stable three-dimensional phase with high structural order. Arguments are presented favoring such a model in terms of stabilizing and destabilizing thermodynamic forces.     

Intracellular inactivation of specific nucleotide sequences: a general approach to the treatment of viral diseases and virally-mediated cancers.

A general approach is proposed for development of anti-viral complexes capable of specific intracellular inactivation of viral genetic sequences. Such complexes would consist of a specially designed bifunctional crosslinking agent bound to a single-stranded segment of virus-specific nucleic acid (the carrier). Pairing this complex with its complementary target sequence would generate covalent interstrand crosslinks between carrier and target, thereby irreversibly inactivating the target sequence. Since cells have natural mechanisms for taking up nucleic acids and pairing the newly-taken-up material with complementary sequences within the cell, it is proposed such mechanisms can be exploited for delivery of nucleic acid-agent complexes to their intracellular viral targets. The feasibility of developing and delivering such antiviral complexes is discussed in light of currently available compounds and techniques.     

Association of poly(ADP-ribose) polymerase with nuclear subfractions catalyzed with sodium tetrathionate and hydrogene peroxide crosslinks

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme which catalyzes the transfer of ADP-ribose units from NAD⁺ to a variety of nuclear proteins under the stimulation of DNA strand break. To examine its role in DNA repair, we have been studying the interaction of PARP with other nuclear proteins using disulfide cross-linking, initiated by sodium tetrathionate (NaTT). Chinese Hamster Ovary (CHO) cells were extracted sequentially with Nonidet P40 (detergent), nucleases (DNase + RNase), and high salt (1.6 M NaCl) with and without the addition of a sulfhydryl reducing agent. The residual structures are referred to as the nuclear matrix, and are implicated in the organization of DNA repair and replication. Treatment of the cells with NaTT causes the crosslinking of PARP to the nuclear matrix. Activating PARP by pretreating the cells with H₂O₂ did not increase the cross-linking of PARP with the nuclear matrix, suggesting a lack of additional interaction of the enzyme with the nuclear matrix during DNA repair. Both NaTT and H₂O₂ induced crosslinks of PARP that were extractable with high salt. To shorten the procedure, these crosslinks were extracted from cells without nucleases and high salt treatment, using phosphate buffer. Using western blotting, these crosslinks appeared as a smear of high molecular weight species including a possible dimer of PARP at 230 kDa, which return to 116 kDa following reduction with -mercaptoethanol.     

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.     

Effect of lig-7 on strand joining in repair of damaged DNA and on cutting of intact homologous DNA (cutting in trans) in Escherichia coli

Genetic recombination in Escherichia coli depends on the recA⁺ gene and can be increased in frequency by certain treatments that damage DNA. In previous studies (Ross &; Howard-Flanders, 1977a,b), E. coli (λ) cells were infected with undamaged λ phages and then with λ phages that were either undamaged, or had interstrand crosslinks produced in their DNA by treatment with psoralen and light. When the superinfecting DNA contained psoralen crosslinks, the intact DNA was cut. This cutting, referred to as cutting in trans, occurred only in DNA genetically homologous to the damaged DNA, required recA⁺ and behaved as expected of a step in damage-induced genetic recombination.In the present studies, we investigated the effect on cutting in trans of lig-7, a thermosensitive allele of the structural gene for E. coli polynucleotide ligase and also of uvrA, which controls the excision of damaged bases from DNA. The ligase deficiency caused gaps due to the action of the uvrA⁺ endonuclease on damaged DNA to remain open for at least 25 minutes. For low levels of damage, cutting in trans was also enhanced in the lig-7 cells at non-permissive temperatures but was not increased in wild-type cells. The enhanced cutting in trans depended upon genetic homology, as expected if it reflected elevated levels of damage-induced genetic recombination. Presumably, the unrepaired gaps in the damaged DNA made it a good substrate for the enzymes that promote cutting in trans of its homologs.     

Testing models of the arrangement of DNA inside bacteriophage lambda by crosslinking the packaged DNA

Bis-psoralens can make crosslinks between two adjacent segments of a condensed DNA molecule. We have used bis-psoralen crosslinking as a covalent means of preserving structural features of DNA packaged inside bacteriophage λ. A single bis-crosslink prevents normal electron microscopic spreading of intact λ DNA: after deproteinization the molecules appear as tangled rosettes which are presumably due either to trapped knots or supercoils. However, restriction nuclease digestion of the crosslinked DNA yields fragments that spread normally. The location of crosslinks can be studied by their appearance in such a digest as X-shaped molecular features. Significant crosslinking frequencies are found between all six possible pairs of the four largest BglII fragments of λ DNA. Little or no evidence is seen for crosslinked loops within individual fragments. These results are inconsistent with two previously suggested models of intraphage DNA packaging. Determination of the positions of crosslinks within restriction fragments yields a pattern of DNA contacts too complex for any simple analysis. The finding of hints of periodicity in the sites of crosslinks, preferential crosslinking of some restriction fragments, and the occurrence of one particularly efficient crosslinking reaction between two restriction fragments appear to rule out purely random packaging arrangements.     

Underwound loops in self-renatured DNA can be diagnostic of inverted duplications and translocated sequences

DNA that contains inverted duplications separated by non-inverted sequences often can form characteristic “underwound loops” when it is denatured and reannealed. An underwound loop is a partially double-stranded, partially denatured segment between the inverted duplications and is produced as follows. During the early stages of the reannealing, intrastrand stem-loop structures form with first-order kinetics when the inverted duplications pair. In a slower second-order reaction, complementary strands (each with a stem-loop) reanneal. The stem-loop structures produce a cruciform in the hybrid. Because of the unpaired sequences in the loop, the cruciform is unstable. It can isomerize to a linear duplex by double-strand exchange of complementary sequences in the stems. This process requires co-ordinated axial rotation of the stems and the flanking duplexes as well as rotation of the loops. If, however, complementary sequences in the loops start to pair, axial rotation is prevented and the stem-loop structures are trapped in a metastable state. The strands of separate, closed rings cannot interwind when they pair. Consequently, the loops observed by electron microscopy have variable patterns of single-stranded denaturation bubbles and duplex segments with both right-handed and left-handed winding.We have used underwound loops to identify a short inverted duplication flanking the γδ recombination sequence of Escherichia coli F factor (isolated on φ80 d₃ilv⁺ transducing phage) and to study DNA from phages Mu and P1 in which the G segments are flanked by inverted duplications. When deproteinized adenovirus-2 DNA was denatured and reannealed, some underwound circles the length of the entire chromosome were observed by electron microscopy. These resulted from the restricted interaction of complementary single-stranded rings generated when pairing of the short inverted terminal duplications closed the ends of single strands. Another type of underwound loop was seen in heteroduplexes containing complementary insertion loops located at different positions in the hybridized strands, such as occurs with P1 cam DNAs. All these underwound structures are similar in appearance to the hybrids formed when topologically separate, complementary single-stranded circles of Colicin E₁ DNA were allowed to anneal.