The effect of low ionic strength on the radiation chemistry and physical properties of calf thymus DNA

Studies of ultraviolet and circular dichroism spectra of aqueous solutions of calf thymus (CT) DNA confirm the tendency of DNA to change conformation at low ionic strength. The qualitative shape and transition width of 260 nm melting curves below 1 mM NaCl differed significantly from those previously published for DNA solutions containing 1 mM NaCl and above. Neutral aqueous solutions of CT DNA at low ionic strengths (0.1 mM-10 mM NaCl) were irradiated with low doses of gamma-rays. The melting temperature, Tm, of irradiated DNA samples increased below 1 mM NaCl suggesting interstrand crosslinking of the denatured DNA or formation of regions of more thermally stable DNA conformation. The magnitudes of these radiation responses were found to be a function of the time elapsed between salt concentration changes and irradiation as well as time after irradiation. These results are consistent with the hypothesis that the purine and pyrimidine base chromophores in double stranded DNA are sheltered from radical attack by the sugar phosphate backbone. Low dose radiation studies (0.8-8.0 Gy) of CT DNA in 1 mM NaCl and below showed a split dose and dose rate dependence for the sample melting curves.     

The Effect of Freezing on the Radiation Sensitivity of Bacterial Spores

S ummary : Bacillus pumilus spores, irradiated under aerobic conditions, were inactivated exponentially at the same rate whether they were at room temperature (10–13°) in phosphate buffer or at -79° in phosphate buffer or in heart infusion broth.
Clostridium welchii spores were irradiated in Robertson's cooked meat medium under anaerobic conditions. With unheated spores, and those subjected to a heat shock before irradiation, the inactivation rate was the same at room temperature and -79°. The same applied to spores heat shocked after irradiation for doses up to 450 Krads, but above this dose level the spores irradiated frozen were more sensitive.
The effect of the heat shock, whether applied before or after irradiation, was to increase the number of survivors, and the proportionate increase appeared to vary with dose.     

Effect of ultraviolet radiation on cell division and microtubule organization inPetunia hybrida protoplasts

Summary Mesophyll protoplasts isolated fromPetunia hybrida were subjected to UV radiation (280–360 nm) in an attempt to assess whether (a) UV radiation has an effect on cortical microtubule organization, (b) UV radiation affects the progression of protoplasts through the cell cycle, and (c) there is a connection between the effect of UV radiation on cell division and the polymerization state of the microtubules. The proto plasts were irradiated with the following UV doses: 4, 8, 12, and 24mmol photons/m², 30 min after isolation. Cell cycle analysis and immuno-localization of microtubules were carried out 0, 24, 48, and 72 h after irradiation. The length of cortical microtubules was determined after irradiation and in corresponding controls. We found that UV radiation induced breaks in cortical microtubules resulting in shorter fragments with increasing dose. Also, the protoplasts were delayed in their progression through the cell cycle, with G1 and G2 phases being affected as well as the S phase. The commencement of DNA synthesis in the irradiated protoplasts followed the re-establishment of a microtubule network. At 48 h after irradiation the protoplasts in all treatments, except for the 24 mmol/m², had cortical microtubules of similar length, and at 72 h after irradiation only the protoplasts that had received 24 mmol photons/m² had not started dividing.Abbreviations BSA bovine serum albumin - DMSO dimethyl sulfoxide - FDA fluorescein diacetate - MT microtubules - MTSB microtubule stabilizing buffer - PAR photosynthetically active radiation (400–700 nm) - PBS phosphate buffered saline - UV ultraviolet     

Effect of temperature on the spectral properties of coenzyme F420 and related compounds.

The uv-visible spectra of 7,8-didemethyl-8-hydroxy-5-deazaflavin-5'-phosphoryllactyl glutamate (coenzyme F420), a naturally occurring 5-deazaflavin derivative, in three different buffers changed with a rise in temperature; the effect on the extinction coefficient at 420 nm (epsilon 420) was as follows: In phosphate-buffered solutions at pH less than 7.5, the epsilon 420 increased (at pH 5.0 for a temperature shift from 15 to 60 degrees C, delta epsilon 420 was +87%), but between pH 7.5 and 8, epsilon 420 changed very little. At pH greater than 8.0 in phosphate- or borate-buffered solutions, epsilon 420 decreased slightly. In morpholineethanesulfonic acid (Mes)-buffered F420 solutions at pH 5 and 5.5, epsilon 420 changed very little, whereas at pH 6-8, the epsilon 420 decreased. Absorbance of F420 at 401 nm in phosphate buffer at pH 5 to 9 was not significantly affected by temperature. Changes in epsilon 420 due to temperature change corresponded to changes in the pKa of 8-OH of the deazaflavin molecule; studies with adenylated F420 showed that the 8-OH of F420 was responsible for these changes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Escherichia coli Growth Changes by the Mediated Effects After Low-Intensity Electromagnetic Irradiation of Extremely High Frequencies

Water is the major constituent of environmental medium and biological systems. The effects occurring in water as a result of low-intensity electromagnetic irradiation (EMI) in extremely high frequencies are supposed to be the primary mechanism to create conditions for biological responses. The EMI effects on Escherichia coli, after irradiation of their suspension, are most probably water-mediated. Indirect effects of EMI at 51.8, 53, 70.6, and 73 GHz frequencies on bacteria, through water, assay buffer (Tris–phosphate buffer with inorganic salts at low or moderate concentrations), or peptone growth medium were studied. The mediated effects of 70.6 and 73 GHz irradiated water, assay buffer, and growth medium on E. coli growth characteristics were insignificant. But the results were different for 51.8 and 53 GHz. EMI mediated effects on bacterial growth were clearly demonstrated. The effects were more strongly expressed with 53 GHz. Moreover, it was shown that 70.6 and 73 GHz similarly suppressed the cell growth after direct irradiation of E. coli in water or on solid medium. Interestingly, for 51.8 and 53 GHz the bacterial growth decreases after suspension irradiation was less, compared to the direct irradiation of bacteria on solid medium. Especially, it was also more expressed in case of 53 GHz. Also with electron microscopy, EMI-induced bacterial cell sizes and structure different changes were detected. In addition, the distinguished changes in surface tension, oxidation–reduction potential and pH of water, assay buffer, growth medium, and bacterial suspension were determined. They depended on EMI frequency used. The differences could be associated with the partial absorbance of EMI energy by the surrounding medium, which depends on a specific frequency. The results are crucial to understand biophysical mechanisms of EMI effects on bacteria.     

Cytokine profiles in mice tissues after irradiation of the thymus projection area with femtosecond laser

The effects of pulsed femtosecond laser irradiation in the near ultraviolet region on the levels of cytokines in the thymus, blood, and skin of irradiated mice have been studied. Irradiation of the thymus projection area with low-intensity laser radiation in the near UV region of the spectrum showed significant changes in cytokine levels in the skin and thymus and, to a lesser extent, in the blood of irradiated mice. Laser irradiation with a power density of 20 mW/cm² affects the cytokine profile in the thymus: IFN-γ, IL-3, IL-4, IL-5, eotaxin, GM-CSF, and chemokine KC–factors that can affect differentiation and proliferation of the cells of the immune system in the gland. Conclusions: It is assumed that changes in the expression of cytokines in the thymus after laser irradiation are explained by the rearrangement of biochemical processes possibly associated with the maturation of cells in the gland.     

Effects of gamma radiation on beta-lactoglobulin: oligomerization and aggregation

The conformational changes and aggregation process of beta-lactoglobulin (beta-LG) subjected to gamma irradiation are presented. Beta-LG in solutions of different protein concentrations (3 and 10 mg/ml) and in solid state with different water activities (a(w)) (0.22; 0.53; 0.74) was irradiated using a Cobalt-60 radiation source at dose level of 1-50 kGy. Small-angle X-ray scattering (SAXS) was used to study the conformational changes of beta-LG due to the irradiation treatment. The irradiated protein was also examined by high performance size exclusion chromatography (HPSEC) and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under nonreducing and reducing conditions and fluorescence. SAXS analysis showed that the structural conformation of irradiated beta-LG in solid state at different a(w) and dose level was essentially the same as the nonirradiated beta-LG. The scattering data also showed that the irradiation of beta-LG in solution promoted the formation of oligomers. Interestingly, from the data analysis and model building, it could be shown that the formed oligomers are linear molecules, built by linear combinations of beta-LG dimers (tetramers, hexamers, etc). The formation of oligomers was also evidenced by SDS-PAGE analysis and HPSEC chromatograms, in which products with higher molecular mass than that of the dimeric beta-LG were detected. Formation of intermolecular cross-linking between tyrosyl radicals are proposed to be at least partially responsible for this occurrence. From the results it could be shown that the samples irradiated in solution presented some conformational changes under gamma irradiation, resulting in well ordered oligomers and aggregates formed by cross-linking of beta-LG dimers subunits, while the samples irradiated in the solid state were not modified.     

A study of beating frequency of a single myocardial cell : II. Ultraviolet micro-irradiation of the nucleus and of the cytoplasm

Single rat myocardial cells were irradiated with the UV micro-irradiation technique over a nuclear or cytoplasmic area of 5 μm of diameter. The contractile response was studied immediately after the irradiation. After 10³ ergs mm⁻² of UV light (254 nm), 4% and 21% of the cells irradiated in the nucleus and the cytoplasm, respectively, showed a temporary increase of the beating rhythm. Moreover, cytoplasmic regions rich in mitochondria were more excitable than other cytoplasmic regions. The ultrastructure and the survival of these cells 24 h after the irradiation did not differ from the control cells. The change of the contractile response according to the localization of the irradiation indicates that the main target organelles are mitochondria; the role of the membrane is not excluded when higher doses of irradiation are considered.     

Effect of Temperature of Liquid Nitrogen on Radiation Resistance of Spores of Clostridium botulinum

An apparatus consisting of a Dewar flask and a relay system controlling the flow of liquid nitrogen permitted the irradiation of samples in tin cans or Pyrex tubes at temperatures ranging from 0 ± 1.5 C to -194 ± 2 C. An inoculated pack comprising 320 cans of ground beef containing 5 × 10⁴ spores of Clostridium botulinum 33A per can (10 cans per radiation dose) was irradiated with Co⁶⁰ at 0 and -196 C. Incubation was carried out at 30 C for 6 months. Approximately 0.9 Mrad more radiation was required to inactivate the spores at -196 C than at 0 C. Cans irradiated at -196 C showed partial spoilage at 3.6 Mrad and no spoilage at 3.9 Mrad; the corresponding spoilage-no spoilage doses at 0 C were 2.7 and 3.0, respectively. The majority of positive cans swelled in 2 to 14 days; occasional swelling occurred as late as 20 days. At progressively higher doses, swelling was delayed proportionally to the radiation dose received. The remaining nonswollen cans had no toxin after 6 months of storage, although occasional cans contained very low numbers of viable spores comprising on the average 0.1% of the original spore inoculum. The D₁₀ values in phosphate buffer were 0.290 Mrad for 0 C and 0.396 Mrad for -196 C; in ground beef, the corresponding D₁₀ values were 0.463 Mrad and 0.680 Mrad, respectively. These D₁₀ values indicate that the lethal effect of γ rays decreased at -196 C as compared with 0 C by 13.5% in phosphate buffer, and by 47% in ground beef.     

Light and scanning electron microscopic observations on the two contrasting types of sister chromatid differential staining after ultraviolet light irradiation

Chinese hamster cells were grown with 50 M 5-bromodeoxyuridine (BrdU) during the penultimate S phase to obtain chromosomes with the TB-TT chromatid constitution. Chromosome preparations made by the air-drying method were used to study the sister chromatid differential staining (SCD) resulting from ultraviolet (UV) irradiation followed by Giemsa staining by light and scanning electron microscopy (SEM). When chromosomes irradiated with UV light (253.7 nm, 5.2 J/m²/s) for more than 5 h were stained with 1% to 4% Giemsa in phosphate buffered saline (PBS) or in distilled water, the resulting SCD invariably belonged to the B-light type in which the TB-chromatid stained lightly. SEM observations of these chromosomes suggested that the B-light SCD was due to the selective photolysis of the TB-chromatid. On the other hand, when chromosomes were irradiated for only 10 min, and stained with 1% Giemsa in PBS, they showed a B-dark type SCD in which the TB-chromatid stained darkly. However, when chromosomes irradiated for 10 min were stained with 4% Giemsa in PBS or 1% Giemsa in distilled water, the resulting SCD again belonged to the B-light type. These findings indicate that when the irradiation dose is small, the resultant SCD is not a simple reflection of selective photolysis in the TB-chromatids and the type of SCD depends not only on the concentration of Giemsa but also on the salinity of the staining solution.     

Oxygen protection of bacteriophage T1 against ionizing radiations

Bacteriophage T1 was suspended in distilled water and in phosphate buffer, saturated with oxygen, nitrogen, hydrogen, and carbon monoxide, and irradiated with gamma rays and x-rays. Under the same conditions phage was exposed to hydrogen peroxide. Oxygen acted as a protective agent against both irradiation and hydrogen peroxide inactivation. As a protective agent against irradiation, oxygen was more efficient in distilled water than in buffer. The phage was much more sensitive to irradiation in the presence of hydrogen or nitrogen than in the presence of oxygen. Survivals of phage irradiated in suspensions saturated with hydrogen and with nitrogen did not differ significantly. From this it was concluded that oxygen did not protect T1 by removing atomic hydrogen from the irradiated medium, since the hydrogen-saturated medium increased the yield of atomic hydrogen but did not increase the yield of inactivated phage. It was presumed, therefore, that phage is sensitive to OH radicals and this was confirmed by irradiating phage with UV in the presence of hydrogen peroxide and comparing this survival with the survivals obtained from hydrogen peroxide alone and from UV alone. The combined effect of hydrogen peroxide and UV acting simultaneously was greater than the effect attributable to hydrogen peroxide and UV acting separately. Evidence for sensitivity to HO₂ radicals was considered, and the effect was attributed chiefly to an oxidizing action since phage sensitivity is greater at higher hydrogen ion concentrations, which favor oxidation by HO₂ radicals. Since the OH radical is a more efficient oxidizing agent than O^-, the former being favored in an acid medium, the latter in an alkaline medium, and since the phage is more sensitive in the first situation than in the second, the present tests proved the importance of oxidation as the mechanism of inactivation. Since some inactivation was encountered when phage was exposed to reducing agents, independently of irradiation, it was concluded that phage is somewhat sensitive to reducing agents, but the inactivation attributable to ionizing radiations is due chiefly to oxidation, against which these reducing agents are very efficient protectors. Under no circumstances did hydrogen peroxide protect T1, whether produced by irradiation in the medium or added beforehand to the medium to be irradiated. The first point was investigated by irradiating T1 in the presence of hydrogen and oxygen combined; this produced a higher yield of hydrogen peroxide but a lower survival of T1. In all these tests phage survival under irradiation was directly correlated with oxygen content of the medium rather than with production of hydrogen peroxide. It is proposed that the protective effect of oxygen is due to a reaction between the phage and oxygen, and this complex confers stability upon the phage.     

Light scattering from suspensions of membrane fragments derived from sonication of beef heart mitochondria.

The intensity of light scattering from suspensions of membrane fragments prepared by sonication of beef heart mitochondria in the presence of EDTA at alkaline pH (ESMP) was determined at 45, 90, and 135 degrees with light of wavelength 546 nm. The dissymmetry ratio Z = I45 degrees c/I135 degrees c, where I45 degrees c and I135 degrees c are the scattering intensities at 45 and 135 degrees extrapolated to zero particle concentration and corrected for reflectance effects, was used to calculate particle size from the Rayleigh-Gans-Debye theory. An average particle diameter D of 184-190 nm was obtained, within the range of particle diameter 50-300 nm determined previously by electron microscopy. This average diameter determined by light scattering is a useful parameter for characterization of ESMP particle size. We propose the term: light scattering average particle diameter, DLS, for this parameter. The refractive index of ESMP was determined to be 1.443 by measurement of scattering intensity in buffer solutions of varying sucrose concentration. The value of Z was independent of sucrose concentration in this determination, showing that the particles are osmotically inactive toward sucrose. The values of average particle diameter DLS and of refractive index fall within the range of validity of the Rayleigh-Gans-Debye theory, for which light scattering changes are attributable solely to dimension change, rather than to change in particle refractive index. Uptake of water accompanying energy-linked salt uptake in ESMP was calculated from light scattering changes to be 0.18 mul of H2O/mg of protein, compared with 0.49 mul of H2O/mg of protein measured by dextran inaccessibility. Measurement of light scattering changes provides a rapid and sensitive method for determining volume changes of ESMP. The magnitude of the volume change observed during energy-linked water and salt uptake and the initial degree of hydration suggests that ESMP are analogous to polyelectrolyte gels with regard to sorption of strong electrolytes and that the Donnan formulation for ion exchange equilibria may be usefully applied to these processes in ESMP.     

Photon radiation-induced structural and functional changes in the myocardium of hypertensive spontaneously hypertensive rats

Hypertensive SHR rates were irradiated with orange-red light using a Korobkov photon light-emitting diode matrix with a maximum radiation at 612 nm; irradiation was performed daily for 1 h for 13 days. After the course of irradiation, the rhythmoinothropic characteristics of the cardiac papillary muscle significantly improved. Morphological analysis revealed active rearrangement in myocytes, which were observed primarily in the structure of the sarcoplasmic reticulum (SR), whose relative area increased more than twice compared to the control. Apparently, photon therapy of hypertensive rats normalizes calcium homeostasis in myocytes and improves the calcium-transport function of SR. The normalization of structural and functional characteristics of the myocardium with hypertensive rates may result from an increase in the SR buffer capacity and activation of SR Ca²⁺-ATPase. Furthermore, qualitative and quantitative changes in the proportion of capillaries, myofibrils, and mitochondria in myocytes indicate the development of adaptive-compensatory processes leading to the activation of biosynthetic processes and an increase in the energy potential of the myocardium.     

The inhibition of mitosis in tissue culture cells by blue light

Blue light (wavelength 350-480 nm) irradiation of the early mitotic (prophase and prometaphase) tissue culture cells at the dose of 50-3000 J/cm2 delay mitosis or completely block it at the metaphase. Cell sensitivity to the near UV light (wavelength 360 nm) was few times more as compared with the sensitivity to the visible light (wavelength 400-480 nm). Mitotic cells irradiated with the green light (wavelength more than 500 nm; dose up to 7500 J/cm2) completed division normally. The effect of the blue light did not depend on the presence of phenol red in tissue culture medium. Rhodamin 123 staining did not show any changes in the mitochondrial system in the irradiated mitotic cells. Blue light irradiation with the dose enough for the induction of mitotic delay appears to be insufficient to affect the proliferation of interphase cells.     

Survival and death of Chara internodal cells in electrolyte solutions and calcium release from the cell wall

Abstract. Survival and death of Chara internodal cells were investigated in one of the alkali metal salts KCl, some of the alkali earth metal salts CaCl₂, Ca(NO₃)₂, MgCl₂, Mg(NO₃)₂, SrCl₂, Sr(NO₃)₂, BaCl₂ and Ba(NO₃)₂, potassium phosphate pH buffer solution (pH 7.0), Tris-maleate pH buffer solution (pH 7.0), HEPES (N-2-hydroxyethylpiperazine-N′-2-ethanesulphonic acid)-KOH (pH 7.0) pH buffer solution, calcium buffer solutions, and deionized water. Most of the internodal cells died within a day or a few days in KCl, MgCl₂, Mg(NO₃)₂, BaCl₂ and Ba(NO₃)₂ solutions of higher concentrations, calcium buffer solutions of pCa 6.0, 10.0 mol m^-3 potassium phosphate pH buffer solution and 10.0 mol m^-3 Trismaleate pH buffer solution. However, all of the internodal cells survived more than 10 d in deionized water, 80.0 mol m^-3 CaCl₂, 80.0 mol m^-3 Ca(NO₃)₂, 80.0 mol m^-3 SrCl₂, 80.0 mol m^-3 Sr(NO₃)₂ calcium buffer solutions of pCa 4.0 and pCa 5.0, and 10.0 mol m^-3 HEPES-KOH (pH 7.0) pH buffer solution. Addition of Ca²⁺ or Sr²⁺ to K⁺, Mg²⁺ and Ba²⁺ salt solutions increased the survival rates of the internodal cells. Calcium release from the internodal cell wall was measured in deionized water, KCl, NaCl, MgCl₂, CaCl₂, SrCl₂ and BaCl₂ solutions. Except in deionized water and CaCl₂ solution, most of the calcium binding to the cell wall was released within one or a few hours in respective electrolyte solutions. Thus, survival and death of the internodal cells in the electrolyte solutions tested were interpreted in terms of the calcium release from the cell wall and the cell membrane, and intrinsic ability of Sr²⁺ to maintain the cell membrane normal.     

Effect of pH, ionic strength and univalent inorganic ions on the reconstitution of aspartate aminotransferase

1. The effect of pH change on the reconstitution of aspartate aminotransferase (EC 2.6.1.1), i.e. the reactivation of the apoenzyme with coenzyme (pyridoxal phosphate and pyridoxamine phosphate), was studied in the pH range 4.2-8.9 by using three buffer systems at concentrations ranging from 0.025 to 0.1m. 2. Although the profile of the reconstitution rate-pH curve in the range pH5.2-6.8 (covered by sodium cacodylate-HCl buffer) reflects the influence of the H(+) concentration on the reconstitution process, the profile of the curve in the pH ranges 4.2-5.6 and 7.2-8.25 (covered respectively by sodium acetate-acetic acid and Tris-HCl buffers) appears to be influenced by the ionic strength of the buffer. 3. The reconstitution is also influenced by univalent inorganic ions such as halide ions and, to a lesser extent, alkali metal ions, which are known to alter the water structure.     

Light-induced chloroplast rearrangements and their action spectra as measured by absorption spectrophotometry

Summary A new combination technique of using both dual-wavelength and opalglas methods for scanning translucent biological samples was applied to leaves of terrestrial plants in order to observe their absorption changes by irradiation and the action spectra for the absorption changes. The measurements of true absorption, free from various effects of scattering, by this technique showed an increase of absorption by weak blue light and a decrease of absorption by strong blue light for almost all of the leaves of 20 plant species examined. These weak- and strong-light responses in absorption were reversible. The fractional increase and decrease of absorbance at 678 nm by weak and strong light were highest, +20% and -31%, for leaves of Begonia semperflorens Link et Otto, and +12% and -13% for leaves of foxtail, Setaria viridis (L.) Beauv., the species examined in further experiments. The response to strong light proceeded to completion earlier than did that to weak light. The strong-light response could be observed separately from the weak-light response by using a leaf pre-irradiated with weak blue light. The responses were measured as a function of light intensity by scanning a single leaf irradiated locally at different intensities, and the action spectra for these responses were measured by scanning a leaf irradiated locally at different wavelengths but at identical intensities. The action spectra for these opposite responses were similar, and showed a band at 450 nm with shoulders but no band in the red region. Microscopic observations of chloroplasts in leaves during irradiation indicated that these changes in absorption are mostly due to rearrangements of chloroplasts in cells caused by irradiation.     

Inhibition of the Induced Formation of Tryptophanase in Escherichia coli by Near-Ultraviolet Radiation

Induced formation of tryptophanase in Escherichia coli B/r is temporarily inhibited by near-ultraviolet (UV) irradiation. The inhibition is greater when irradiation is at 5 C than when at room temperature. Hence, the inhibition is the result of a photochemical, rather than photoenzymatic, alteration of some cellular component. The action spectrum has a peak in the region of 334 nm and is similar to that for growth delay. However, inhibition of tryptophanase formation is more sensitive to near-UV irradiation than are growth, respiration, and the induced formation of beta-galactosidase. Thus, for tryptophanase the lack of formation cannot be due to general inhibition of metabolism. Pyridoxal phosphate absorbs in the near-UV region of the spectrum and is a cofactor for tryptophanase, but this enzyme in induced cells is not inactivated by near UV-radiations. An experiment in which toluene-treated suspensions from irradiated and unirradiated cells were mixed showed that irradiation does not cause the formation of an inhibitor of tryptophanase activity. The possibility remains that the absorption of radiant energy by pyridoxal phosphate interferes with the synthesis of tryptophanase.     

Strand breaks and alkali-labile bonds induced by ultraviolet light in DNA with 5-bromouracil in vivo.

Supercircular gamma phage DNA with 10 bromouracils/100 thymine bases, irradiated with 313 nm light in Tris buffer and sedimented on alkaline and neutral gradients, showed 4.6 alkali-labile bonds per true single-strand break, in agreement with Hewitt and Marburger (1975 Photochem. Photobiol. 21:413). The same DNA irradiated in Escherichia coli host cells showed about the same number of breaks in alkaline gradients for equal fluence, but only 0.5 alkali-labile bond per true break. Similarly, E. coli DNA with bromouracil irradiated in the cells showed only 10--20% more breaks when denatured with 0.1 M NaOH than under neutral conditions with 9 M sodium perchlorate at 50 degrees C. These results show that true single-strand breaks occur more frequently than alkali-labile bonds after ultraviolet irradiation of DNA containing bromouracil in cells.