Effects of Ultraviolet Radiation on Respiration and Growth in Radiation-resistant and Radiation-sensitive Strains of Escherichia coli B

Ultraviolet (UV) irradiation at 254 nm causes different respiration and growth responses in log-phase cultures of Escherichia coli B/r and B(s-1). These differences are correlated with the ability and inability, respectively, of these bacterial strains to repair UV-induced lesions in deoxyribonucleic acid (DNA). After irradiation, B(s-1) cells (radiation-sensitive) exhibit uncoupling of growth and respiration; growth and synthesis cease, whereas respiration continues. B/r cells (radiation-resistant) grown on glycerol exhibit severe temporary inhibition of growth and respiration after UV, and the coupling of these two processes is maintained, except at a very high UV dose. Inhibition begins at about the time DNA synthesis resumes and continues for a period of time that is dependent upon dose. Glucose-grown cells do not exhibit severe respiratory, growth, and synthetic inhibitions; these processes remain coupled in the cells during the postirradiation period. Photoreactivation treatment delays uncoupling of growth and respiration in B(s-1) and prevents inhibition of respiration and growth in B/r. These results indicate that the postirradiation responses result from the presence of pyrimidine dimers in DNA. Ultraviolet irradiation of B/r and B(s-1) cells results in an accumulation of adenosine triphosphate by 30 min after UV. This accumulation decreases with time and does not appear to be related to the inhibition of respiration in glycerol-grown B/r cells. The results on B/r are interpreted in terms of a control mechanism for reestablishment of a balance among macromolecules in the irradiated cells so as to provide them with the potential to survive. The specific steps in such a reestablishment of balance appear to depend upon the substrate oxidized. In B(s-1) cells, which cannot repair UV-induced damage in DNA, some control mechanism that coordinates cellular processes may be inactivated.     

Relation Between Survival and Deoxyribonucleic Acid Replication in Ultraviolet-Irradiated Resistant and Sensitive Strains of Escherichia coli B/r

When arabinose-grown Escherichia coli B/r is ultraviolet (UV) irradiated in the logarithmic phase of growth, the dose inactivation curve for both colony formation and deoxyribonucleic acid (DNA) synthesis (based on the relative rates of synthesis) is exponential in nature. When protein synthesis is inhibited before UV-irradiation, both inactivation curves have a large shoulder. Pre-irradiation inhibition of protein synthesis increases considerably the colony-forming ability of a UV-irradiated Hcr(-) and Rec(-) strain of E. coli B/r. However, with the repair-deficient strains, both the shoulder and slope of the survival curve are affected. We investigated the effect of UV irradiation on DNA synthesis in Hcr(-) bacteria and found that pre-irradiation inhibition of protein synthesis increases UV resistance of DNA replication in this strain also. The results suggest that inhibition of protein synthesis before irradiation increases UV resistance in E. coli B/r by a mechanism which is independent of both the excision and recombination repair systems.     

Effect of dark repair on ultraviolet sensitivity of bacteriophage-infected bacteria

Feiner, R. R. (Columbia University, New York, N.Y.), and R. F. Hill. Effect of dark repair on ultraviolet sensitivity of bacteriophage-infected bacteria. J. Bacteriol. 91:1239-1247. 1966.-Changes in ultraviolet (UV) sensitivity of phage-host complexes during phage development have been studied for the following systems: T1 and Escherichia coli B, T1 and E. coli K-12S, lambda and E. coli K-12S. Complexes were formed with bacterial strains differing in ability to dark-repair UV damage to deoxyribonucleic acid and, after irradiation, were plated on bacteria differing similarly. In the first half of the latent period, the resistance of complexes formed with nonrepairing bacteria increased considerably; with T1 and E. coli B hcr(-), in 4 min the resistance became the same as that of complexes formed with repairing bacteria. The repair ability of plating bacteria affected survival curves only upon irradiation in the second half of the latent period after mature phages were present in the initial complex. Use of nonrepairing bacteria both for initial infection and for plating of late complexes resulted in a series of survival curves showing for all three systems the same pattern of change originally reported for T2-E. coli B complexes. Thus, a hitherto unexplained difference between radiation survival curves for T-even and T-odd phages seems due to repair of T-odd phages by the host.     

DNA Repair in Human/Embryonic Chick Heterokaryons: Ability of Each Species to Aid the Other in the Removal of Ultraviolet-Induced Damage

Cultured human and embryonic chick fibroblasts possess different enzyme-mediated processes to repair cyclobutyl pyrimidine dimers induced in their deoxyribonucleic acid (DNA) by ultraviolet (UV) radiation. While dimers are corrected in human cells by excision repair, a photoenzymatic repair process exists in embryonic chick cells for the removal of these potentially deleterious UV photoproducts. We have utilized a sensitive enzymatic assay to monitor the disappearance, i.e. repair, of dimer-containing sites in fused populations of human and chick cells primarily consisting of multinucleate human/chick heterokaryons. Fused cultures were constructed such that UV photoproducts were present only in chick DNA when evaluating excision repair and only in human DNA when evaluating photoenzymatic repair. Based on the kinetics of site removal observed in these cultures we are led to conclude the following: Within heterokaryons per se the photoreactivating enzyme derived from chick nuclei and at least one excision-repair enzyme (presumably a UV endonuclease) derived from human nuclei act on UV-damaged DNA in foreign nuclei with an efficiency equal to that displayed toward their own nuclear DNA. Hence, after cell fusion these chick and human repair enzymes are apparently able to diffuse into foreign nuclei and once therein competently attack UV-irradiated DNA independently of its origin. In harmony with the situation in nonfused parental cultures, in heterokaryons the chick photoenzymatic repair process rapidly removed all dimer-containing sites from human DNA including the residual fraction normally acted upon slowly by the human excision-repair process.     

Rejoining of radiation-induced single-strand breaks in deoxyribonucleic acid of Escherichia coli: effect of phenethyl alcohol.

Single-strand breaks in deoxyribonucleic acid of Escherichia coli B/r cells exposed to 20 krads of gamma radiation could be rejoined by incubation of irradiated cells in growth medium. In the presence of 0.25% phenethyl alcohol, this repair was completely inhibited although deoxyribonucleic acid and protein syntheses were suppressed only partially.     

Chromosome Replication and the Division Cycle of Escherichia coli B/r

The average amount of deoxyribonucleic acid (DNA) per cell was measured in steady-state cultures of Escherichia coli B/r grown at 37 C in glucose-limited chemostats or in batch cultures in the exponential growth phase as maintained with one of several carbon sources. Within experimental errors, DNA content was dependent only on growth rate and independent of the type of culture, the carbon source, or the addition of growth factors. The amount of DNA per cell increased continuously with growth rate over the range of 0.02 to 3 divisions per hour. The data over the entire range of growth rates are in agreement with a constant time for a single replication point to traverse the entire genome, 47 min, and with cell division following 25 min after termination of replication. The measured amount of DNA per genome was 4.2 x 10(-15) g (or 2.5 x 10(9) daltons).     

Efficiency of Thymidine Incorporation in Escherichia coli B/r as a Function of Growth Rate

Short-term labeling with radioactive thymidine led to inaccurate estimates of deoxyribonucleic acid synthesis at some growth rates in steady-state cultures of Escherichia coli B/r. Estimates were corrected in chemostat cultures by adding adenosine, a known inhibitor of thymidine phosphorylase.     

Growth in cadmium-containing medium induces resistance to heat in E. coli

We have shown that 10 microM Cd2+ in the growth medium can induce resistance to subsequent heat treatment in E. coli B/r. Resistance was shown by cells during an extended lag phase and, especially, during log phase. The results contrast with the effect of Cd2+ exposure on radiation lethality, for which sensitization was previously reported in cells from lag and stationary phase cultures.     

Chromosome replication during the division cycle in slowly growing, steady-state cultures of three Escherichia coli B/r strains.

The period of DNA synthesis C during the cell cycle was determined over a broad range of generation times in slowly growing, steady-state batch cultures in the exponential phase and in chemostat cultures of three strains of Escherichia coli, strains B/r A, B/r K, and B/r TT, utilizing measurements of average amounts of DNA per cell and cell survival after radioactive decay of 125I incorporated into the DNA of synthesizing cells. At each growth rate, values for cell survival and for C periods were the same within experimental errors for the three strains. The length of the DNA synthesis period increased linearly with generation (doubling) time T of the culture and approached a limiting value of C = 0.36T at very long generation times. In very slowly growing cultures, DNA replication was limited almost entirely to the final third of the cell cycle. D periods, between termination of DNA replication and cell division, were found to be relatively short at all growth rates for each strain. Average amounts of DNA per cell measured in slowly growing cultures of strains B/r A and B/r TT were indistinguishable from results for strain B/r K at the same growth rates. Amounts of DNA per cell calculated from the cell survival values alone are completely consistent with the measured DNA per cell.     

Deoxyribonucleic Acid Repair Replication after Ultraviolet Light or X-Ray Exposure of Bacteria

A comparison of repair synthesis after ultraviolet light (UV) or X-ray exposure was made in Escherichia coli strains 15T(-) (555-7) and B/r by use of a D, (15)N, (13)C density labeling system. During the initial 15 min of incubation after UV irradiation, both a "repair" synthesis and a reduced semiconservative deoxyribonucleic acid (DNA) synthesis occurred. In the so-called "physiological" dose range used, the latter was greater than the former. X-irradiation of cells, at doses producing similar levels of cell death as in the UV-exposed cultures, did not lead to a similar repair replication process. However, a density heterogeneity of the DNA synthesized in the initial 10 min after exposure was observed. This is interpreted in terms of X ray-induced DNA degradation. Normal cells showed only a semiconservative type of replication and, therefore, within the limits of resolution of the system used (the incorporation of 1,000 to 5,000 nucleotides per replicating chromosome could be measured), DNA in normal cells did not appear to undergo a repair synthesis involving thymine exchange. These results indicate that not all repair mechanisms mimic that found after UV exposure.