An unstable donor-recipient DNA complex in transformation of Bacillus subtilis.

Summary In re-extracted DNA obtained shortly after uptake of transforming DNA by Bacillus subtilis, increased amounts of donor DNA radioactivity banding at the position of donor-recipient DNA complex (DRC) are observed in CsCl gradients, if the cells are irradiated with high doses of UV prior to reextraction of the DNA. Qualitatively, the same phenomenon is observed if lysates of transforming cells are irradiated. UV-irradiation of lysates of competent cells to which single-stranded DNA is added after lysis, does not result in linkage of this DNA to the chromosomal DNA. Two observations argue in favour of the formation of a specific labile complex between donor and resident DNA during transformation. Firstly, heterologous donor DNA from Escherichia coli, although being processed to single-stranded DNA in competent B. subtilis, does not seem to be linked to the recipient chromosome upon UV-irradiation, and secondly, the labile complex of donor and recipient DNA can be stabilized by means of treatment of the lysates of transforming cells with 4, 5¹, 8-trimethylpsoralen in conjuction with long-wave ultra violet light irradiation. This indicates that base-pairing is involved in the formation of the complex. On the basis of these results we assume that the unstable complex of donor and recipient DNA is an early intermediate in genetic recombination during transformation.     

Fate of heterologous deoxyribonucleic acid in Bacillus subtilis.

CsCl density gradient fractionation of cell lysates was employed to follow the fate of Escherichia coli, phage T6, and non-glucosylated phage T6 deoxyribonucleic acid (DNA) after uptake by competent cells of Bacillus subtilis 168 thy minus trp minus. Shortly after uptake, most of the radioactive Escherichia coli or non-glucosylated T6 DNA was found in the denatured form; the remainder of the label was associated with recipient DNA. Incubation of the cells after DNA uptake led to the disappearance of denatured donor DNA and to an increase in the amount of donor label associated with recipient DNA. These findings are analogous to those previously reported with homologous DNA. By contrast, T6 DNA, which is poorly taken up, appeared in the native form shortly after uptake and was degraded on subsequent incubation. The nature of the heterologous DNA fragments associated with recipient DNA was investigated with Escherichia coli 2-H and 3-H-labeled DNA. Association of radioactivity with recipient DNA decreased to one-fourth in the presence of excess thymidine; residual radioactivity could not be separated from recipient DNA by shearing (sonic oscillation) and/or denaturation, but was reduced by one-half in the presence of a DNA replication inhibitor. Residual radioactivity associated with donor DNA under these conditions was about 5% of that originally taken up. Excess thymidine, but not the DNA replication inhibitor, also decreased association of homologous DNA label with recipient DNA; but, even in the presence of both of these, the decrease amounted to only 60%. It is concluded that most, or all, of the Escherichia coli DNA label taken up is associated with recipient DNA in the form of mononucleotides via DNA replication.     

Mechanism of conjugation and recombination in bacteria. XVII. Further evidence for single-stranded regions in recipient DNA during conjugation in Escherichia coli K-12.

The secondary structure of recipient DNA mated with Hfr strain was investigated by CsCl density gradient fractionation. After 45 min of HfrH64 X 3h-f-ab1157 mating one-fourth of the radioactive recipient DNA was recovered as a single-strand but only after shearing of cell lysates prior to centrifugation. This heavier than native DNA fraction of radioactive material (obtained after the first centrifugation) was degraded by single-strand specific nuclease S from Aspergillus oryzae. These findings thus confirm the authors' earlier results suggesting that in the course of mating are generated local single-stranded regions in recipient DNA.     

Single-stranded conjugation in Escherichia coli K-12

Summary The mutation BT43 in the gene dnaB leads to the inhibition of vegetative and conjugational DNA synthesis at 42°. The consequences in case of conjugation are very unusual. The fragment of donor DNA tramsmitted to the recipient cell remains single-stranded and is integrated as such into the recipient chromosome similar to the main events during transformation. We call this process single-stranded (SS) conjugation.The evidence for this statement comes from the measurement of the time of expression of the gene tsx, containing the genetic information for the receptor of phage T6. The gene tsx is introduced into a dnaBT43 recipient cell alternatively by two different donors Hfr H and Hfr C, which are characterized by opposite directions of transfer. Therefore both donors introduce into the recipient cell alternatively the informational or noninformational DNA strand. If conjugation is performed at a nonpermissive temperature, the transferred DNA piece remains single-stranded and is integrated as such into the recipient chromosome. If it is the informational strand (case of Hfr H), it is transcribed very fast and yields the protein in question in about 20 min. If the noninformational strand is integrated (Hfr C) about 40 min additional time is required to effect cell division.SS-conjugation is very sensitive to the action of exonucleases Exo I and Exo V and is much enhanced in the absence of both nucleases in the recipient.The exogenous DNA pieces are integrated as short insertions, this leads to the disjoining of linked markers and to a very short scale of the genetic map. Because the donor DNA undergoes recombination in the single-stranded state heteroduplex regions originate which are subsequently corrected by the enzymes of the recipient cell. The situation leads to a very special but predictable heterogeneity of the progeny of transconjugants.The fact of the existence of this special process, SS-conjugation, drastically different from common conjugation in many respects, suggests that common conjugation leads to the integration of double-stranded DNA pieces into the recipient chromosome.     

Extensive regions of single-stranded DNA in aphidicolin-treated melanoma cells

We have looked for the presence of single-stranded DNA in human melanoma cells. Single-stranded DNA was observed by lysis of cells in dilute alkali (to partly denature the DNA) followed by CsCl gradient centrifugations. In normally growing cells we did not observe single-stranded DNA whereas large amounts were present in cells treated with aphidicolin (an inhibitor of DNA polymerase alpha). The single-stranded DNA is much larger (greater than 20 kb) than Okazaki fragments. When the cells were washed free of aphidicolin, the single-stranded DNA was converted to high molecular weight DNA. Furthermore, when DNA synthesis is recovering after drug treatment, the single-stranded DNA disappears. The single-stranded DNA represents a transient step during the maturation of newly synthesized DNA.     

Macromolecular Content of Inclusions Produced by a Canine Adenovirus

Early inclusions induced by a canine adenovirus in a canine cell line, appearing before the formation of infectious virus particles, were purified by differential centrifugation in sucrose followed by CsCl density gradient centrifugation. Chemical analysis of these inclusions revealed that they contained deoxyribonucleic acid (DNA), ribonucleic acid, and protein. On the basis of density gradient centrifugation, the DNA extracted from the inclusions was found to be viral DNA. Electron microscope autoradiography showed that these inclusions were the sites of DNA synthesis. In addition, association of DNA polymerase activity with the inclusions was detected by incorporation of radioactivity from (3)H-thymidine triphosphate into a DNA product. The in vitro product of the enzyme had a density equal to that of viral DNA rather than host DNA. The level of DNA polymerase activity in exponentially growing infected and uninfected whole cells was similar, but in cells in stationary phase the enzyme activity of infected cells was twice that in noninfected cells. Furthermore, nuclei isolated from infected cells showed a fourfold increase in DNA polymerase activity over the noninfected cells.     

Fate of adenovirus type 12 genomes in nonpermissive cells

The fate of ³H-thymidine-labeled adenovirus type 12 deoxyribonucleic acid (DNA) was studied in Nil-2 cells of Syrian hamster origin. It was found that a substantial fraction of ³H-adenovirus type 12 DNA became degraded within 24 hr after infection and was released into the culture fluid. After infection of 5-bromodeoxyuridine (BUdR)-prelabeled cells with ³H-adenovirus type 12, viral DNA became readily separable from cellular DNA by equilibrium centrifugation in CsCl. Part of the viral radioactivity was found to shift gradually to the position of cellular DNA as time progressed after infection. When exponentially growing cells were exposed simultaneously to BUdR, 5-fluorodeoxyuridine, and ³H-adenovirus type 12, up to 50% of the viral radioactivity shifted within 24 hr from the density of viral DNA to that of cellular DNA after equilibrium centrifugation in CsCl. Upon denaturation of the cellular DNA, the isotope was preferentially found to be associated with the “heavy” strand which was synthesized after infection. Upon hybridization of the “heavy” and the “light” strands with sonically treated, denatured ³H-adenovirus type 12 DNA, small and nearly equal amounts of counts hybridized with both strands. The number of counts annealed was in a range similar to that of those annealed with the same amount of DNA derived from adenovirus type 12-transformed hamster cells. These results demonstrate that (i) a substantial proportion of the adsorbed virus becomes degraded within 24 hr; (ii) part of the degradation products is reutilized for cellular DNA synthesis; (iii) only a small fraction, mainly fragments, of viral DNA becomes integrated into both the newly synthesized and the parental strands of cellular DNA.     

Initiation of recombination during transformation of Bacillus subtilis requires no extensive homologous sequences

Summary Lysates obtained shortly after entry of transforming DNA to Bacillus subtilis contain donor-recipient DNA complexes, in which the donor moiety is associated with the recipient DNA in an unstable way. The complexes could be artificially stabilized by crosslinking with 4,5,8-trimethylpsoralen. The unstable complexes dissociated upon helix-destabilizing treatments, such as heating at 70°C, and CsCl gradient centrifugation at pH 11.2, but remained stable during CsCl gradient centrifugation at pH 10. Donor-recipient DNA complexes were not formed after entry of heterologous pUB110 DNA. These observations suggest that base-pairing is involved in the unstable association. The donor moiety of the unstable complexes was completely, or almost completely, digestible by nuclease S₁, indicating that the donor and recipient base-sequences are only paired over very short distances.The unstable donor-recipient DNA complexes are true recombination intermediates because (i) strain 7G224 (recE4) was impaired in the formation of the unstable complexes, and (ii) the unstable complexes were rapidly converted to stable complexes in recombination proficient strains, whereas their conversion was delayed in the recombination deficient strain 7G84.Unstable complexes were also formed with Escherichia coli donor DNA, but to a lesser extent. Apparently a limited degree of base-sequence homology is sufficient to initiate recombination.     

Transformation in Bacillus subtilis: characterization of an intermediate in recombination observed during transformation.

Summary From recombination-proficient competent cells of Bacillus subtilis in which the donor DNA entered at 17°, and which were kept at the same temperature, a complex of donor DNA and the recipient chromosome can be obtained which has a relatively high buoyant density in CsCl gradients. Exposure of the isolated complex to nuclease S1 liberates donor radioactivity. The limited biological activity of DNA re-extracted from cells attempting to recombine at 17° is decreased upon incubation with nuclease S1. If recombination is allowed to proceed at 30°, the high buoyant density of the donor-recipient complex decreases to normal values and less radioactivity can be liberated from the complex by nuclease S1. Concomitantly the biological activity of re-extracted DNA becomes less vulnerable to nuclease S1 under these conditions. On the basis of these observations we assume that the intermediate complex partly consists of unpaired single-stranded donor DNA.Support for the correctness of this assumption is derived from experiments with a mutant, which is delayed in the processing of high buoyant density donor-recipient complex to normal buoyant density donor-recipient complex. This delay is reflected in the time of acquisition of resistance to nuclease S1 digestion of the isolated complex.     

Radiotoxicity of 5-[123I]iodo-2'-deoxyuridine in V79 cells: a comparison with 5-[125I]iodo-2'-deoxyuridine

The toxic effects of the short-lived (T 1/2 = 13.2 h) Auger-electron-emitting isotope 123I, incorporated in the form of 123IUdR into the DNA of V79 cells in vitro, have been investigated and compared to those of 125IUdR. For the concentrations tested, the rate of incorporation of 123IUdR at any time is proportional to the concentration of extracellular radioactivity. The curve for survival of clonogenic cells decreases exponentially and exhibits no shoulder at low doses. The mean lethal dose (D37) to the nucleus is 79 +/- 9 cGy and is about the same as that obtained previously with 125IUdR. However, the total number of decays needed to produce this D37 with 123IUdR is about twice that required with 125IUdR, approximately equal to the ratio of the energy deposited in microscopic volumes by 125I and 123I, respectively. This correlation suggests that nuclear recoil, electronic excitation, and chemical transmutation are probably of minor importance to the observed biological toxicity with either isotope. The results also indicate that there are no saturation effects in the decay of 125IUdR in the DNA of V79 cells (i.e., all of the emitted energy is biologically effective) and that each of the two steps involved in the 125I decay is equally effective in causing biological damage.     

Replication of the deoxyribonucleic acid of multiple-drug-resistance factor in Escherichia coli.

1. It was shown that a system previously described for labelling R-factor DNA during transfer to an irradiated recipient strain of Escherichia coli did not allow high selectivity in the incorporation of thymine into R-factor DNA. 2. Lack of selectivity was shown to be due to cross-feeding from recipient to donor strain. 3. An improved system using a nalidixic acid-resistant recipient strain is described in which incorporation of thymine into the DNA of donor cells is minimized by addition of nalidixic acid after completion of transfer of the plasmid during conjugation.     

Molecular Recombination in T4 Bacteriophage Deoxyribonucleic Acid I. Tertiary Structure of Early Replicative and Recombining Deoxyribonucleic Acid

A replicative hybrid resulting from the infection of heavy (substituted with 5-bromodeoxyuridine) bacteria with light (not substituted with 5-bromodeoxyuridine) radioactive bacteriophage was isolated from a CsCl density gradient. Sedimentation studies indicate that 60% of the deoxyribonucleic acid (DNA) behaves as if it were in units more than four times as large as an intact reference molecule. Under the electron microscope, hybrid molecules appeared tangled, showed puffs and loops, occupied a small area, and often had a total length twice that of mature phage. This indicates that sucrose gradient sedimentation is not applicable as a method for estimating the relative molecular size of replicative forms of DNA. After denaturation, the separated strands of hybrid were of the same size as those of reference DNA. CsCl density gradient analysis revealed no terminal covalent addition of new material to the old parental strand. The possibility of a continuous growth of the DNA molecule, either on a single-stranded level or as a double helical structure, is disproved. When chloramphenicol (CM) was added at critical times after infection, DNA synthesis continued at a constant rate. The parental label soon assumed and retained a hybrid density, despite concomitant synthesis of DNA, throughout the rest of the period of incubation in CM. The hybrid moiety, however, actively participated in replication and exchanged its partner strand for a new one; this was demonstrated by changing the density label during incubation in CM. A new enzyme synthesized shortly after infection introduced single-stranded "nicks" into the parental DNA. Since nicking can be inhibited by chloramphenicol, the responsible enzyme is not of host origin. The time of the appearance of this enzyme coincided with the onset of molecular recombination. Another enzyme, which mediates the repair of the continuity of the polynucleotide chain after recombination, appeared after recombination. If selectively inhibited by chloramphenicol, recombinant molecules remained unrepaired, and, upon denaturation, the parental fragment was liberated in pure form.     

On the Nature of Recombinants Formed during Transformation in Hemophilus influenzae

During the process of transformation in Hemophilus influenzae integration of donor DNA, i.e. the formation of recombinant DNA, involves the incorporation of single-stranded DNA. Evidence was obtained from cesium chloride density gradient centrifugation of DNA from donor-recipient complexes that integration was accompanied by the formation of hybrid DNA with a density intermediate with respect to heavy, ²H, ¹⁵N, donor and light, ¹H, ⁴N recipient DNA. On denaturation the position of the heavy donor DNA moved closer to, but not all the way toward, the density position of the original donor DNA. In addition to supporting the idea of single-stranded incorporation, this evidence suggested that the integrated donor DNA was covalently linked to light recipient DNA. The DNA was taken up in the double-stranded form and no detectable amounts of denatured DNA could be found during the transformation process. However, during the process of integration an amount of donor atoms, equivalent to the amount of hybrid DNA formed, appeared in recipient DNA, and indicated that while one strand of DNA was integrated the other was broken down and resynthesized. The density of the hybrid DNA, as well as rebanding of denatured hybrid, indicated that the size of the integrated piece of DNA was large, approximately 6 x 10⁶ daltons.     

Structural defects in rat liver deoxyribonucleic acid. Endogenous single-strained regions in comparison with damage induced in vivo by a carcinogen.

Rat liver DNA may be separated into two fractions by stepwise elution from benzoylated-DEAE-cellulose with NaCl and caffeine solutions respectively. Other studies using bacterical and yeast DNA suggested that the first fraction contains native DNA, whereas the second may exhibit some degree of single-stranded character. In the present experiments, chromatography of DNA was monitored by labelling in vivo with [methyl-3H]thymidine in rats previously subjected to partial hepatectomy. In animals killed up to 1 h after thymidine injection, radioactivity eluted in the second fraction was inversely related to the incorporation time, being greatest when animals were killed 10 min after radioisotope injection. However, for most experiments, animals were allowed to survive 2-4 weeks after surgery before use, analysis being made on non-dividing DNA. Under these conditions, the proportion of caffeine-eluted DNA was decreased by subjecting the preparation to shear, before chromatography. A procedure that resulted in 12% of the recovered radioactivity being eluted with caffeine was adopted for experiments involving comparisons of the two DNA fractions. Under these conditions, cross-contamination could be detected by rechromatography, but this did not preclude distinction being made between the two fractions in terms of DNA structure. NaCl-eluted DNA did not bind to nitrocellulose filters. Caffeine-eluted DNA was retained by the filters and released by washing with 3mM-Tris/HCl,pH9.4. The fractions did not differ in terms of isopycnic centrifugation in CsCl. The NaCl-eluted fraction migrated as a single band in polyacrylamide gels, and this pattern was not modified by prior digestion with Neurospora crassa endonuclease. In contrast, caffeine-eluted DNA contained a minor component having a wide molecular-weight distribution and was subject to limited digestion by the endonuclease. The kinetics of denaturation of NaCi-eluted DNA in the presence of formaldehyde, in common with unfractionated DNA, were consistent with double-stranded structure. The same analysis of caffeine-eluted DNA revealed structural abnormality equivalent to two defects per 10000 base-pairs. The data are consistent with the minor fraction of rat liver DNA, separated by using benzoylated-DEAE-cellulose, containing regions of local denaturation. We previously showed that administration of the hepatocarcinogen dimethylnitrosamine is associated with an increase in the proportion of caffeine-eluted DNA. In terms of most analysis, differences between DNA fraction from nitrosamine-treated rats were similar to differences exhibited by preparations from control animals. However, structural analysis using denaturation kinetics indicated defects in both the NaCl- and caffeine-eluted DNA isolated from nitrosamine-treated rats. The two fractions differed from each other in that caffeine-eluted DNA exhibited a degree of structural damage far greater than that detected in any preparation from control animals...     

Conjugation in the cyanobacterium Anacystis nidulans

Summary Genetic recombination in the cyanobacterium Anacystis nidulans was first reported by Kumar (1962) and confirmed by Bazin (1968). Although genetic transformation in this organism was demonstrated by Shestakov and Khyen (1970) and Herdman (1973), conjugation does not seem to have been reported so far. In Escherichia coli, one common mode of gene transfer involves conjugation between donor and recipient cells. This conjugation is mediated by the formation of a pilus or conjugation tube through which the chromosome of the male cell passes into the recipient (female) cell (Hayes 1962). Offprint requests to: H.D. Kumar (Bot., B.H.U., Varanasi, India, after November only)     

Specific Alterations of Coxsackievirus B3 Eluted from Hela Cells

After the attachment of radioactive coxsackievirus B3 to HeLa cells at 0 C and subsequent incubation at 37 C, 50 to 80% of attached virus radioactivity was eluted from the cells within 1 hr. Eluted virus had a buoyant density of 1.21 in a potassium tartrate gradient, sedimented more slowly than native virus in sucrose gradients, was resistant to ribonuclease, was unstable in CsCl centrifugation, and did not reattach to uninfected cells. Electrophoretic studies of sodium dodecyl sulfate-disrupted B3 virus in sodium dodecyl sulfate-polyacrylamide gels revealed four radioactive virus polypeptides (VP 1 to 4), of which the three largest migrated slightly faster than their poliovirus T1 counterparts. In contrast, electrophoretic analysis of eluted virus, after banding in a tartrate gradient or pelleting by centrifugation, showed the absence of the fastest migrating polypeptide, VP 4. VP 4 was recovered in the supernatant fluid when the eluted virions were removed by high-speed centrifugation. The results indicate that VP 4 is located at the surface of the native virion, and its dissociation from the capsid may represent the first specific alteration of the virion after virus-receptor interaction at the cell surface.     

Incorporation of Iododeoxyuridine into Cellular Deoxyribonucleic Acid Synthesized After Infection with Simian Virus 40

Primary monkey kidney cells (Cerocpithecus aethiops) in the stationary phase of growth were labeled with (14)C-thymidine for 24 hr prior to infection with simian virus 40 (strain 777). (3)H-deoxyadenosine and 5-iodo-2'-deoxyuridine (IUdR) were added to some of the cultures 24, 48, or 72 hr after infection; 24 hr later the deoxyribonucleic acid (DNA) was extracted from these cultures and centrifuged in a CsCl density gradient. The portion of DNA which had become heavier because of incorporation of IUdR could be seen as a second peak in the sedimentation profile. This peak contained (14)C as well as (3)H activity. The possibility that the (14)C-labeled cellular DNA might be degraded and used for the synthesis of viral DNA could be excluded. On the basis of these results, it must be assumed that the infection of monkey kidney cells with simian virus 40 induces the synthesis of cellular DNA.     

Structure of replicating DNA molecules of Bacillus subtilis bacteriophage phi 29.

We isolated phi 29 DNA replicative intermediates from extracts of phage-infected Bacillus subtilis, pulsed-labeled with [3H]thymidine, by velocity sedimentation in neutral sucrose followed by CsCl equilibrium density gradient centrifugation. During a chase, the DNA with a higher sedimentation coefficient in neutral sucrose and a lower sedimentation rate in alkaline sucrose than that of viral phi 29 DNA was converted into mature DNA. The material with a density higher than that of mature phi 29 DNA consisted of replicative intermediates, as analyzed with an electron microscope. We found two major types of molecules. One consisted of unit-length duplex DNA with one single-stranded branch at a random position. The length of the single-stranded branches was similar to that of one of the double-stranded regions. The other type of molecules was unit-length DNA with one double-stranded region and one single-stranded region extending a variable distance from one end. Partial denaturation of the latter molecules showed that replication was initiated with a similar frequency from either DNA end. These findings suggest that phi 29 DNA replication occurs by a mechanism of strand displacement and that replication starts non-simultaneously from either DNA end, as in the case of adenovirus.     

Composition and synthesis of DNA in synchronously growing cells of Chlorella pyrenoidosa

Summary The composition and synthesis of DNA in synchronous cultures of Chlorella pyrenoidosa strain 211/8b has been investigated. Analytical CsCl density gradient centrifugation gave a homogenous major DNA component with a (G+C) content of 51% and a minor component containing 28% (G+C). The (G+C) contents derived from melting profiles were 2–3% lower. A second minor component with approximately 41% (G+C) content was inferred from banding patterns of labelled DNA in preparative CsCl density gradients. ¹⁴C-uracil was readily incorporated into the pyrimidine moieties of the major (nuclear) DNA between the 10th and 18th hour after beginning of the light period, but not at any other time. ¹⁴C-uracil incorporation into the minor (satellite) component was low but continuous throughout the whole cell cycle. The incorporation is correlated with an increase in the proportion of satellite DNA from 6% up to 20% during the time when no nuclear DNA replication takes place. The results suggest that different regulatory mechanisms exist for the nuclear and for satellite DNA synthesis.     

Effect of rhesus or vervet cytomegalovirus infection of DNA synthesis in untreated and 5-iodo-2''-deoxyuridine-arrested cells.

Infection of permissive cells with either rhesus or vervet cytomegalovirus resulted in suppression of cellular DNA synthesis, only viral DNA was resolved by isopycnic centrifugation after 24 h postinoculation. Infection of 5-iodo-2'-deoxyuridine (IUdR)-arrested cells with either of the simian cytomegaloviruses, however, induced synthesis of cellular DNA of normal density; synthesis of cellular DNA substituted with IUdR as evidenced by resolution of a heavy DNA peak after isopycnic centrifugation was not observed. Stimulation of DNA synthesis in IUdR-arrested cells was not observed with virus inactivated with UV light.