ACTION SPECTRUM FOR GROWTH DELAY INDUCED BY NEAR-ULTRAVIOLET LIGHT IN E. coli B/r K*

Abstract— The action spectrum for growth delay induced by near-uv light was determined for Escherichia coli B/r growing in a defined medium. This spectrum agrees with and extends that determined earlier by Jagger and his co-workers for E. coli B growing in nutrient broth. The extended spectrum is indistinguishable from the absorption spectrum for 4-thiouridine above 320 nm, but deviates significantly at wavelengths shorter than this from the spectrum for 8–13 link formation in transfer RNA containing 4-thiouridine at position 8. These results extend the evidence that 4-thiouridine in transfer RNA is the chromophore for near-UV induction of growth delay, but weaken the case for linkage of a pyrimidine at position 13 in transfer RNA as the mechanism of growth delay.     

ULTRAVIOLET RADIATION INHIBITS BOTH ACCESSORY CELL AND RESPONDER T CELL FUNCTION IN THE PROLIFERATIVE RESPONSE TO HAPTENATED-SELF

Abstract— Photoprotection i. e. the increased resistance of the cells preilluminated with near ultraviolet light (300–380 nm) to the lethal action of 254 nm radiations is observed in wild-type Escherichia coli B cells (which exhibits the Fil phenotype) but requires either an integrated prophage or a rec A mutation to be detected in E. coli K12 strains. Here we have demonstrated that significant photoprotection occurs in an E. coli K12 rec A⁺ cell containing the Ion allele which is responsible for filamentous growth (Fil phenotype) after 254 nm irradiation. The Fil phenotype can be suppressed by the sfi A of sfi B suppressor genes. Since the E. coli K12 rec A⁺ Ion sfi B strain exhibits no more photoprotection, these data support the conclusion that in Ion strains photoprotection is due to the abolition of the 254 nm induced filamentation by the near ultraviolet treatment. In addition, we show here that near ultraviolet illumination of the cells leads to a severe restriction of the bulk protein synthesis, as well as of the inducibility of β-galactosidase and tryptophanase. These effects are observed only in nuv ⁺ cells that contains 4-thiouridine the chromophore responsible for photoprotection. We propose that in Ion (lysogenic) strains, photoprotection is due to prevention of the SOS response. During the growth lag, the low residual level of protein synthesis does not allow the induction of the SOS response and accordingly prevents filamentation (the lytic cycle). Concomitantly the SOS triggering signals are eliminated via DNA repair.     

REDUCTION BY NEAR-ULTRAVIOLET (334 nm) LIGHT OF E. COLI CAPACITY FOR PHAGE GROWTH DEPENDS UPON THE rel GENE AND 4-THIOURIDINE

Abstract— Near-ultraviolet radiation (near UV; 300–380 nm) has long been known to produce a transient reduction of the capacity of bacteria to support phage growth. The present work shows that, at high fluenœs (40–100 kJ/m²), 85% of 334-nm-induced reduction of capacity in Escherichia coli B/r requires the rel gene; that is, it results from rel -gene activity caused by the near-UV treatment. This rel -gene activity leads to (1) a bacterial growth delay and concomitantly lowered bacterial metabolism, and (2) a parallel delay in phage development, with a considerable depression of burst size. We propose that the observed effects on phage development are a consequence primarily of the lowered bacterial metabolism, but they may also result partly from a direct inhibition of phage DNA synthesis by the rel gene product, these effects together leading to the observed reduction of capacity in a rel ⁺ strain. The remaining 15% of capacity reduction, observed in a rel strain, has an unknown mechanism, but does appear to involve a delay in phage development.
At least 95% of the total capacity reduction observed in the rel ⁺ strain in the range 40–100 kJ/m² requires the presence of 4-thiouridine, an unusual base in E. coli transfer RNA, which is presumably both the chromophore and the target for near-UV-induced capacity reduction.     

MUTATIONAL INTERACTIONS BETWEEN NEAR-UV RADIATION AND DNA DAMAGING AGENTS IN Escherichia coli: THE ROLE OF NEAR-UV-INDUCED MODIFICATIONS IN GROWTH AND MACROMOLECULAR SYNTHESIS

Abstract— The mutational interactions between near-ultraviolet (near-UV, 334 nm, 365 nm) radiation and DNA damaging agents (far-UV (254 nm) and ethyl-methanesulphonate (EMS)) were studied in strains of Escherichia coli B/r trp thy with different susceptibilities to near-UV-induced growth delay (wild-type, rel and srd ). Far-UV induced reversion to tryptophan independence is reduced while forward mutation to streptomycin is enhanced by prior exposure of the rel+ srd+ strains to near-UV radiation. The observed interactions are reduced ( rel ) or absent ( srd ) in the two mutant strains as are the corresponding growth and macromolecular synthesis delays normally observed after near-UV treatment. Quantitatively, the degree of interaction induced by near-UV pre-treatment correlates closely with the degree of protein synthesis inhibition. We propose a mechanism for the contrasting interactions at the two genetic loci based on the different pathways by which pre-mutagenic lesions may be processed. The primary chromophore for the mutational interactions would appear to be 4-thiouracil-containing transfer RNA.     

IN VIVO INDUCTION OF 4-THIOURIDINE-CYTIDINE ADDUCTS IN tRNA OF E. COLI B/r BY NEAR-ULTRAVIOLET RADIATION*

Abstract— Near-ultraviolet (near-UV; 320–405 nm) irradiation of Escherichia coli B/r induces the formation in vivo of ⁴Srd-Cyd adducts in transfer RNA, as evidenced by (1) fluorescence spectrum changes of tRNA extracted from irradiated cells and reduced with NaBH₄, (2) thin-layer chromatography on cellulose of hydrolysates of trichloroacetic acid-precipitable extracts of irradiated cells, and (3) comparison of these findings with adduct formation induced by near-UV irradiation of purified mixed tRNA from E. coli. The kinetics of induction of the ⁴Srd-Cyd adduct in vivo, and the near-UV fluences required, provide strong support for our earlier hypothesis that formation of these adducts is responsible for near-UV-induced growth delay in E. coli.     

The roles of the rel+ gene and of 4-thiouridine in killing and photoprotection of Escherichia coli by near-ultraviolet radiation

Abstract— Photoprotection is a reduction in response to far-UV (190–300. nm) radiation in cells that have been previously exposed to longer wavelengths. It has been proposed that photoprotection operates by means of a growth delay that permits more time for dark repair. Growth delay in Escherichia coli utilizes 4-thiouridine (⁴Srd) in transfer RNA as a chromophore and it requires the rel⁺ gene, which exerts a stringent control upon RNA synthesis. Mutants that were either rel or ⁴Srd^? were isolated from E. coli B, utilizing a near-UV-induced growth-delay selection technique. The rel mutants, which undergo little growth delay after near-UV irradiation, show only 50% as much photoprotection as wild types, while ⁴Srd^? mutants show no photoprotection at all. Thus, photoprotection appears to utilize ⁴Srd as its sole chromophore in E. coli B and B/r, and no more than 50% of photoprotection in these strains can be a result of near-UV-induced growth delay.     

INTRAMOLECULAR ENERGY TRANSFER IN NATIVE tRNA AT ROOM TEMPERATURE

Abstract— The odd nucleoside 4-thiouridine, which is present in position 8 of 70% of E. coli tRNAs, possesses unusual spectroscopic properties which make it suitable for intramolecular energy transfer studies. Both its luminescence excitation spectrum and the action spectrum (230–380 nm) for the 8–13 link formation have been established in native E. coli tRNA at room temperature. The spectra are identical and present a new unexpected peak around 260 nm. At this wavelength, they are amplified by a factor of nine as compared with the absorption and excitation spectra of the free nucleoside in aqueous solution.
The origin of this new peak is discussed and it is concluded that energy transfer does occur from the common nucleosides to the 4-thiouridine residue. Using the values of the nucleosides to 4-thiouridine distances inferred from the sets of atomic coordinates obtained on yeast tRNA^phe crystals, a satisfactory account of our finding can be obtained assuming singlet-singlet energy transfer. The efficiency of the mechanism is probably favoured by a good overlap between the emission spectra of the common nucleosides and the absorption spectrum of 4-thiouridine.     

DELAY IN GROWTH AND DIVISION INDUCED BY NEAR ULTRAVIOLET RADIATION IN ESCHERICHIA COLI B AND ITS ROLE IN PHOTOPROTECTION AND LIQUID HOLDING RECOVERY

Abstract. Microscopic observations show that growth delay and division delay occur on nutrient agar after Escherichia coli B has been irradiated at 3341 Å. These effects also occur in nutrient broth.
A near u.v. action spectrum for growth delay in nutrient broth has been obtained. It shows a single peak at 3380 Å and is indistinguishable from the action spectrum for photo-protection from far u.v. (2537 Å) killing in the same organism. Furthermore, photoprotected cells show a much greater growth delay than cells that have not been photoprotected. These, as well as kinetic data, suggest that the essential action of a photoprotection treatment consists in the induction of a growth-division delay. This delay would presumably permit more time for intracellular recovery systems to operate on the far u. v. damage to nucleic acids.
Liquid holding recovery (effected by holding cells in phosphate buffer after far u. v. irradiation) shows complete overlap with photoprotection. It is concluded that photoprotection and liquid holding recovery operate on the same far u. v. damage. As with photoprotection, it is probable that the essential action of a liquid holding treatment is the induction of a growth-division delay.
No photoprotection is observed of intracellular T2 bacteriophage or of E. coli B_s-l (Hill).     

MUTATION INDUCTION BY AND MUTATIONAL INTERACTION BETWEEN MONOCHROMATIC WAVELENGTH RADIATIONS IN THE NEAR-ULTRAVIOLET AND VISIBLE RANGES

Abstract— The induction of mutations (reversion to tryptophan independence) by various UV (254, 313, 334 and 365 nm) and visible (405 and 434 nm) wavelengths was measured in exponential phase populations of Escherichia coli B/r thy trp and B/r thy trp uvrA by assay of irradiated populations on semi-enriched media. No mutations were induced in the repair proficient strain at wavelengths longer than 313 nm. Mutations were induced in the excisionless strain at wavelengths as long as 405 nm but less than expected from the known amount of DNA damage induced. Irradiation at the longer wavelengths (434, 405, 365 and 334 nm) suppressed the appearance of 254- or 313-nm-induced mutations in the repair competent strain but not in the excision deficient strain. The relative dose-requirement for mutation suppression was related to the relative efficiency of these wavelengths in inducing growth delay. These results suggest that the growth delay induced by near-UV and visible wavelengths allows more time for the 'error-free" excision repair process to act on the potentially mutagenic lesions induced by 254- and 313-nm radiations, thereby reducing the mutation frequency observed in the repair-proficient strain. The level of near-UV mutation induced in the excision deficient strain is lower than expected from the DNA damage known to be induced. It is possible that near-UV radiation induces a class of lethal lesions that are not susceptible to error-prone repair.     

Transient reduction in the tRNA 4-thiouridine content induced by ultraviolet A during post-irradiation growth in Enterobacter cloacae

The influence of previous exposure to ultraviolet-A radiation (UVA) was studied on the susceptibility of Enterobacter cloacae to undergo the growth delay effect. Comparison of growth curves corresponding to irradiated and control cells showed that a previous treatment with UVA almost abolished the growth delay effect. UV absorption spectra of tRNA, and reverse phase HPLC analysis of hydrolysed tRNA, demonstrated a low content of 4-thiouridine in E. cloacae cells grown after UVA exposure at low doses. Since 4-thiouridine is the UVA target responsible for initiation of growth delay, this observation explained the influence of previous exposure to UVA on the susceptibility of this organism to undergo growth delay. A similar but weaker alteration was found when Escherichia coli was assayed. The results suggest that, in addition to cross-linking with cytidine residues, the content of 4-thiouridine in tRNA may be modified by UVA by an unknown mechanism.     

DIFFERENTIAL, LETHAL AND MUTAGENIC ACTION OF 254 nm AND 320–400 nm RADIATION ON SEMI-DRIED BACTERIA

Abstract— The effect of culture conditions on the lethal and mutagenic action of 254 nm (u.v.) and 320–400 nm (b.l.) light has been examined. Ten strains of Escherichin coli were used in these investigations. It was found that semi-dehydration in aerosols greatly enhanced the lethal and mutagenic actions of both U.V. and b.l., Mutations induced by U.V. were found to be of a random kind, while those produced by b.l. were specific and of a particular biochemical type depending on the strain of cell and its stage of development. The presence of oxygen during irradiation enhanced b.l. effects but had no effect on U.V. damage while anaerobic growth endowed the cells with added resistance to b.l. and u.v., Stationary phase cells of E. coli B/r were found to be mutated by b.l. specifically at a thymine locus and to be more sensitive than E. coli B to the inhibition by b.l. of respiration. Some mutations induced by b.l. in E. coli B/r were found to hinder the cells ability to carry out the photoreversal of U.V. damage. It is suggested that b.1. affects a specific piece of DNA which is in contact with the cytochrome chain of the cytoplasmic membrane and that this contact point between the cytochrome chain and DNA alters sequentially as the cell proceeds through its life cycle.     

LETHAL INTERACTION BETWEEN ULTRAVIOLET-VIOLET RADIATIONS AND METHYL METHANE SULPHONATE IN REPAIR PROFICIENT AND REPAIR DEFICIENT STRAINS OF ESCHERICHIA COLI

Abstract— The lethal interaction between monochromatic radiation at various wavelengths and methyl methane sulphonate was tested in strains of Escherichia coli proficient and deficient in DNA repair. In the repair proficient wild-type strain K12 AB1157, the efficiency of sensitization to MMS as a function of dose (at 334 nm, 365 nm and 405 nm) was found to be directly correlated with the dose necessary to remove the shoulder from the survival curve at the wavelength employed. The 365 nm: MMS interaction was also observed in other repair proficient E. coli strains (W3110 and B/r) but was absent in a recA and a polA strain. Pre-treatment of AB1157 with MMS leads to a much larger interaction than pre-irradiation with 365 nm. It is concluded that dose-dependent damage to DNA repair by the near-UV radiation is involved in the interaction and possibly that MMS causes irreversible damage 10 repair enzymes.     

FLUENCE-RATE DEPENDENCE OF MONOPHOTONIC REACTIONS OF NUCLEIC ACIDS IN VITRO AND IN VIVO

The Bunsen-Roscoe law, also known as the reciprocity law ( E = f(F) with F = I t ) has only limited validity for monophotonic reactions of nucleic acids. Especially at low fluence rates, the extent of in vitro and in vivo photoreactions of nucleic acids in the far-UV and near-UV range is a function of the fluence and of the fluence rate ( E = f (F;I)). In vitro experiments with poly(dA)poly(dT) clearly show that the far-UV (254 nm) response, indicated by the changes of the ellipticity at 315 nm, does not obey the Bunsen-Roscoe law at low fluence rates in the range between 1 W m^-2 and 20 W m^-2. In vivo experiments with Escherichia coli revealed very similar anomalies. Studying the growth delay after irradiation with far-UV light at 280 nm or near-UV light at 334 nm, we have confirmed the lack of reciprocity in both spectral ranges. The failure of the Bunsen-Roscoe law for the 280 nm and 334 nm UV irradiation effect at low fluence rates was in the range O < I < 40 W m^-2. In both cases reciprocity occurred at higher fluence rates (40 < I < 100 W m^-2).     

THE ROLE OF 4-THIOURIDINE IN LETHAL EFFECTS AND IN DNA BACKBONE BREAKAGE CAUSED BY 334 nm ULTRAVIOLET LIGHT IN Escherichia coli

Strains of Escherichia coli that lack 4-thiouridine (⁴Srd) are killed by monochromatic 334 nm UV light (UV) less efficiently than their wild-type parents, which contain ⁴Srd. Oxygen enhancement ratios (OER) at 10% survival are 3.3 for a strain that possesses ⁴Srd, and 2.6 for one that lacks ⁴Srd. Single-strand breaks in DNA caused by 334 nm UV accumulate more than twice as fast in the wild-type strains than in the strains lacking ⁴Srd. The results suggest that ⁴Srd is an important chromophore in some near-UV lethal effects. The results also suggest that the excitation energy from 334 nm UV light may be passed from RNA to DNA, resulting in single-strand breaks.     

THE ROLE OF HOST-CELL REPAIR IN LIQUID-HOLDING RECOVERY OF U.V.-IRRADIATED ESCHERICHIA COLI

Abstract— The experiments reported give evidence that liquid-holding recovery (LHR) of u.v. irradiated E. coli cells involves basically the same type of dark repair which causes reactivation of phage and which results in much increased survival of the cells themselves [host-cell reactivation (HCR)]. LHR is very small in the two HCR(-) strains B syn^- and B_s-1, but occurs to larger but different extents in the three HCR(+) strains B, B/r, and B/r (Λ). LHR is inhibited if the liquid contains caffeine or acriflavine, both of which are known to inhibit HCR. The results indicate that most of the LHR effect, if not all, occurs during the liquid holding, rather than under growth conditions after liquid holding. It is assumed that the holding itself allows a prolonged time for, and therefore an enhancement of, HCR. It is thus implicit that LHR can be observed only where otherwise HCR of repairable u.v. damage would be incomplete, and that different extents of LHR, as observed in the three HCR(+) strains, reflect different extents of incompleteness of HCR. It is concluded that the repairable u.v. hits which are not fully repaired by HCR are predominantly those concerned with the extra u.v. sensitivity of the strains B and B/r (Λ), relative to B/r.     

LIQUID HOLDING RECOVERY OF PHOTODYNAMIC DAMAGE IN E. COLI

Escherichia coli cells lose viability when irradiated with visible light in the presence of acridine dyes. There has been some controversy about whether such photodynamic damage can be repaired. Several investigations on different E. coli strains failed to reveal any significant difference in the sensitivity to photodynamic damage between radiation-resistant E. coli B/r and radiation-sensitive E. coli B_s-1 strains (Uretz, 1964; Janovska et al. , 1970) suggesting the absence of repair. On the contrary, other investigators (Rupp, 1966; Harm, 1968) strongly predicted the existence of a dark-repair mechanism for such damage. No systematic study of liquid-holding recovery of photodynamic damage has yet been reported and knowledge of repair capacity for photodynamic damage is still incomplete. In the present communication, liquid-holding-repair capability of E. coli B/r and B_s-1 for photodynamic inactivation in the presence of acridine orange or acriflavine has been investigated. These studies show that B/r can repair photodynamic damage while B_s-1 is deficient in this ability.     

OXYGEN EFFECT IN SURVIVAL OF Dictyostelium discoideum TREATED WITH NEAR ULTRAVIOLET RADIATION

Abstract— Fluence-response survival curves have been measured for the cellular slime mold Dictyostelium discoideum exposed to near ultraviolet radiation. Data were obtained for a wild type strain and three UV-sensitive mutant strains in exponential growth phase. Fluences for 10% survival (F₁₀) are about 1 MJ m⁻² for cells irradiated in saline solution saturated with nitrogen. When air is bubbled through the saline, the Fm values are only one third as large. Strain HPS50, which is the strain most sensitive to gamma radiation and to 254 nm UV, also exhibits the greatest sensitivity to near UV. However, the difference in sensitivity to near UV between wild type and mutant strains is small compared to other physical and chemical agents known to damage DNA.     

LETHAL EFFECTS OF NATURAL SOLAR ULTRAVIOLET RADIATION IN REPAIR PROFICIENT AND REPAIR DEFICIENT STRAINS OF ESCHERICHIA COLI: ACTIONS AND INTERACTIONS

Abstract— The inactivation of repair proficient ( Escherichia coli K12 AB 1157, E. coli B/r) and repair deficient ( E. coli K12 AB 1886 uvrA , AB 2463 recA and AB 2480 uvrA recA ) strains of bacteria by noon sunlight has been measured. The use of biological dosimetry based on an ultraviolet (UV) sensitive strain of Bacillus subtilis spores has allowed a quantitative comparison of bacterial inactivation by solar, 254 and 302 nm radiations. Our analysis indicates that: (1) uvrA and recA gene products are involved in repair of a substantial portion of the solar DNA damage, (2) 302 nm is a more appropriate wavelength than 254 nm to represent the DNA-damaging action of sunlight and that (3) repair proficient strains are inactivated by sunlight more rapidly than expected from the levels of DNA damage induced. When populations of repair proficient bacteria are exposed to noon sunlight for 20 min, they become sensitive to the lethal action of far-UV (254 nm), MMS (0.1 M ) and to a lesser extent, mild heat (52°C).     

NEAR ULTRAVIOLET INACTIVATION STUDIES ONESCHERICHIA COLI TRYPTOPHANASE AND TRYPTOPHAN SYNTHETASE

Abstract— –The response of two pyridoxal-phosphate-requiring enzymes of E. coli, tryptophanase and tryptophan synthetase, to near UV light (320–400 nm) has been studied. Tryptophanase is inactivated both in vivo and in vitro, but tryptophan synthetase is resistant to near UV under both conditions. This shows that near UV inactivation is not general for pyridoxal-phosphate-requiring enzymes. Substrate protection against light inactivation is demonstrated for tryptophanase. It is furthermore shown that pyridoxal phosphate is required for inactivation of this enzyme. However, the action spectrum for this inactivation does not coincide with the absorption spectrum of tryptophanase or of pyridoxal phosphate.     

LOSS OF PHOTOREACTIVABILITY DURING LIQUID-HOLDING IN ESCHERICHIA COL1 WP2

Loss of photoreactivability during liquid-holding occurs much faster in Escherichia coli WP2 than has been reported for another strain of B/r (Harm, 1968). The underlying mechanism considerably reduces the maximum photoreactivation attainable within 30 min. The addition of caffeine to UV irradiated strain WP2 prevents the loss of photoreactivation activity. Similarly, a uvr A mutant also fails to show this loss of photoreactivation capacity. These results are consistent with the view that in WP2 the initial steps of excision repair take place during liquid-holding and that they can preclude photoreactivation at a high rate. But it remains to be elucidated why different strains of B/r differ with respect to this rate.