A New Facet of Vitamin B12: Gene Regulation by Cobalamin-Based Photoreceptors

Living organisms sense and respond to light, a crucial environmental factor, using photoreceptors, which rely on bound chromophores such as retinal, flavins, or linear tetrapyrroles for light sensing. The discovery of photoreceptors that sense light using 5'-deoxyadenosylcobalamin, a form of vitamin B12 that is best known as an enzyme cofactor, has expanded the number of known photoreceptor families and unveiled a new biological role of this vitamin. The prototype of these B12-dependent photoreceptors, the transcriptional repressor CarH, is widespread in bacteria and mediates light-dependent gene regulation in a photoprotective cellular response. CarH activity as a transcription factor relies on the modulation of its oligomeric state by 5'-deoxyadenosylcobalamin and light. This review surveys current knowledge about these B12-dependent photoreceptors, their distribution and mode of action, and the structural and photochemical basis of how they orchestrate signal transduction and control gene expression.

Exploring the use of natural antimicrobial agents and pulsed electric fields to control spoilage bacteria during a beer production process

Different natural antimicrobials affected viability of bacterial contaminants isolated at critical steps during a beer production process. In the presence of 1 mg/ml chitosan and 0.3 mg/ml hops, the viability of Escherichia coli in an all malt barley extract wort could be reduced to 0.7 and 0.1% respectively after 2 hour- incubation at 4 degrees C. The addition of 0.0002 mg/ml nisin, 0.1 mg/ml chitosan or 0.3 mg/ml hops, selectively inhibited growth of Pediococcus sp. in more than 10,000 times with respect to brewing yeast in a mixed culture. In the presence of 0.1 mg ml chitosan in beer, no viable cells of the thermoresistant strain Bacillus megaterium were detected. Nisin, chitosan and hops increased microbiological stability during storage of a local commercial beer inoculated with Lactobacillus plantarum or Pediococcus sp. isolated from wort. Pulsed Electric Field (PEF) (8 kV/cm, 3 pulses) application enhanced antibacterial activity of nisin and hops but not that of chitosan. The results herein obtained suggest that the use of these antimicrobial compounds in isolation or in combination with PEF would be effective to control bacterial contamination during beer production and storage.

Effects of freezing on the survival of Escherichia coli and Bacillus and response to UV and chlorine after freezing

Escherichia coli (E. coli) and Bacillus megaterium bacteria were frozen at -15 degrees C using a freezer and a spray freezing method. The frozen Bacillus spores were also exposed to UV and free chlorine. An average of 4.7-log inactivation was obtained from the spray ice with 2-day storage time, while the freezer freezing only caused 0.84-log reduction with the same storage time. Significantly higher inactivation levels were observed for the E. coli cells with 2-day storage compared with those without storage. The spray freezing was found more effective in killing the E. coli cells, while more cells were sublethally injured by the freezer freezing. Freezing did not kill the Bacillus megaterium spores, but affected their response to UV and chlorine. Greater inactivation levels were observed at higher free chlorine doses or longer contact time, and the UV fluence-response curve showed initial rapid kill followed by tailing for the frozen spores.

Evidence for two recA genes mediating DNA repair in Bacillus megaterium

Isolation and subsequent knockout of arecA-homologous gene inBacillus megateriumDSM 319 resulted in a mutant displaying increased sensitivity to mitomycin C. However, this mutant did not exhibit UV hypersensitivity, a finding which eventually led to identification of a second functionalrecAgene. Evidence forrecAduplicates was also obtained for two otherB. megateriumstrains. In agreement with potential DinR boxes located within their promoter regions, expression of both genes (recA1andrecA2) was found to be damage-inducible. Transcription from therecA2promoter was significantly higher than that ofrecA1. Since arecA2knockout could not be achieved, functional complementation studies were performed inEscherichia coli. Heterologous expression in a RecA null mutant resulted in increased survival after UV irradiation and mitomycin C treatment, proving bothrecAgene products to be functional in DNA repair. Thus, there is evidence for an SOS-like pathway inB. megateriumthat differs from that ofBacillus subtilis.

Photoabsorption study of Bacillus megaterium, DNA and related biological materials in the phosphorus K-shell edge region

We measured the X-ray transmission spectra of several biologically related samples in the phosphorus K-shell edge absorption region. These include red phosphorus, hydrated sodium phosphate (Na(3)PO(4).12 H(2)O), deoxyribonucleic acid (DNA), adenosine triphosphate (ATP), diolylphosphatidyl choline (DOPC), and Bacillus megaterium spores. Red phosphorus essentially displays an edge-jump. All other spectra are similar in form and energy position: Each is dominated by a narrower, more intense first peak and a broader but less intense second peak. The corresponding K-shell edge absorption thresholds are shifted toward higher energy relative to that for red phosphorus, as expected for increasing degrees of phosphorus oxidation. The B. megaterium spectrum has aspects common to both the phosphate and DNA spectra and is therefore interpreted as a composite of spectra arising from DNA, ribonucleic acid (RNA) and phosphates within the spore. The B. megaterium spore spectrum provides information for resonant radiation damage studies in the phosphorus K-shell edge absorption region by identifying candidate photoexcitations. In addition, the absorption spectra will be useful in X-ray microscopy and macromolecular crystallography studies at the phosphorus K-shell edge.

Structural and functional characterization of the Bacillus megaterium uvrBA locus and generation of UV-sensitive mutants

The Bacillus megaterium genes uvrB and uvrA, encoding two subunits of the (A)BC excinuclease, which is responsible for nucleotide excision repair, were isolated and functionally characterized. RNA analyses revealed co-transcription of both genes probably forming a bicistronic operon. Expression of uvrB and uvrA was inducible by the DNA-damaging agent mitomycin C. This finding agrees with the presence of a potential DinR box within the uvrBA promoter. Single inactivation of uvrB or uvrA as well as the parallel knockout of both genes resulted in mutants highly sensitive to UV irradiation. Thus, this locus represents an attractive target for generating biologically safe containment strains of B. megaterium.

Characterization of UV-peroxide killing of bacterial spores

Advantage is taken in many sterilization processes, especially for food packaging materials, of the synergy between H2O2 and UV irradiation for spore killing. The nature of the synergy is currently not well defined in terms of targets and mechanisms. We found that under some experimental conditions, the synergistic killing of spores of Bacillus megaterium ATCC 19213 appeared to be mainly UV-enhanced peroxide killing, while under other conditions, it appeared to be mainly peroxide-enhanced UV killing. Lethal combinations of H2O2 and UV irradiation for spores resulted in only modest increases in auxotrophic mutations among survivors, indicative of little DNA damage, in contrast to higher mutation levels after dry-heat damage at 115 degrees C. However, the combination of UV light and peroxide did lead to major inactivation of glucose 6-phosphate dehydrogenase, an enzyme that was used to monitor the damage to bacterial protein. Synergistic UV-H2O2 killing was reduced by agents such as pyruvate, thiosulfate, and iron or copper cations, which appeared to act at least in part by reacting chemically with H2O2, and was only slightly affected by the use of UV light at a wavelength of 222 nn rather than 254 nm. Hydrogen peroxide treatment can precede UV irradiation for synergistic killing by some hours with an interim of drying for spores of Bacillus subtilis A, a spore type used commonly for the validation of aseptic processes. Synergistic killing of dried spores or those in suspensions was accelerated at higher temperatures (50 degrees C) rather than at lower temperatures (25 degrees C).

Exobiology and the effect of physical factors on micro-organisms

A study of the action of different physical factors on micro-organisms is necessary for a further development of exobiology. The action of temperature on crystalline preparations of catalase and peroxidase was studied by means of oscillographic polarography. A determination of the height of polarographic waves at the decrease of temperature from 20 degrees C to 0 degrees C has shown that structural elements of the peroxidase molecule connected with the enzymatic activity are more stable with the decrease of temperature cf. catalase. A relative resistance of the dehydrogenase activity in Az. vinelandii cells to high vacuum was found. Incubation of azotobacter cells under vacuum of 10(-9) mm Hg during 72 hr did not decrease the activity of alcohol and succinic dehydrogenase. Bac. cereus spores can be preserved from bactericidal UV action by thin films of chrome. The thickness of chrome film being 200-670 angstroms, spores are killed by a dose of 7.8 x 10(7) erg/cm2 at 253.7 microns wave length. Spores covered by chrome film thicker than 800 angstroms remain alive after this treatment. Investigations carried out with an 'Artificial Mars' camera led to the following results. The growth of Bac. megaterium on liquid growth media in this camera ceases as a result of UV rays killing all cells after 3 weeks. Untreated bacteria grow in the camera for a long time. Spore-forming bacteria isolated from the sand of the Kara-Kum Desert grow in ground limonite (with the addition of 2% garden soil) having maximum hygroscopic humidity (3.8%). Freezing and thawing (from -60 degrees C to +25 degrees C) corresponding to day temperature deviations on Mars, low pressure (P=10 mm Hg) and the composition of the atmosphere (CO2-50%, N2-40%, Ar-10%) do not influence the growth of xerophylic bacteria under study. Humidity is the main factor limiting the growth of micro-organisms under 'Artificial Mars' conditions. According to the further development of the microbiological meteorite analysis methods, samples of rocks and stone meteorites were sterilized, incubated in the desert or on a snow surface in the Arctic and after different times (from 100 days to 7 months), investigated. In all cases, microbes were found only on the sample surfaces, whereas 1 cm from the surface and in the central parts micro-organism were completely absent. Hence, microbiological analysis of central parts of meteorites fallen in the Arctic or during dry periods of the year in the desert can give reliable results.

Prediction of growth of Bacillus megaterium spores as affected by gamma radiation dose and spore load

AIMS

To provide data on the interaction of radiation dose (x1) and microbial contamination load (x2), as predictor variables, on the percentage of vials exhibiting growth of Bacillus megaterium spores (y).

METHODS AND RESULTS

The influence of a wide range of spore loads (1-50 000 spores of B. megaterium vial-1) and gamma radiation doses (0.2-10 kGy) on the contaminated samples was determined. Each contamination load was studied by adding the specified number of spores to 100 vials containing nutrient broth and exposing them to various doses of gamma radiation. Curves representing the number of contaminated vials against the dose of radiation were sigmoidal in shape and the data showed an indirect relationship. Data were analysed by regression analysis which revealed a significant correlation (R2=0.85). The relationship among the tested variables is exponential and can be described by the following equation: y = 1 - (1 - e(0.0173x(1)))(x(2)) It was also estimated that, for each increase of 1 in the number of spores per vial, there is an increase of 1 in the number of contaminated vials.

CONCLUSION

The two variables (x1 and x2) have great influence on the radiation sterilization efficiency and the proposed mathematical model is valid for the prediction of this efficiency.

SIGNIFICANCE AND IMPACT OF THE STUDY

The results of the present investigation can be of useful industrial application and can help to set acceptance and rejection limits for the production of materials vulnerable to microbial contamination.

Spice extracts as dose-modifying factors in radiation inactivation of bacteria

Three spices, chili, black pepper, and turmeric, were tested for the effect of their aqueous extracts on the sensitivity of three bacteria, Escherichia coli, Bacillus megaterium, and Bacillus pumilusspores, to gamma-radiation. It was found that the extracts of the three spices offered protection to these organisms against inactivation by gamma-radiation. These spice extracts were also tested for their protection of naked plasmid DNA. Radiation-induced degradation of plasmid pUC18 DNA was reduced in the presence of the spice extracts. The maximum protection was offered by the chili extract followed by that of black pepper and turmeric. The two known antioxidants, curcumin and piperine from turmeric and black pepper, respectively, were shown to protect the plasmid DNA from the degradation by gamma-radiation. Experiments with the plasmid pUC18 DNA indicated that the spice extracts probably protected microorganisms by protecting their DNA. These studies indicated the importance of spices among ingredients in food as dose-modifying factors during radiation processing.

Isolation of Bacillus megaterium mutants that produce high levels of heterologous protein, and their use to construct a highly mosquitocidal strain

A xylose-regulated plasmid expression system for producing high levels of recombinant proteins in Bacillus megaterium has recently been described [Appl Microbiol Biotechnol 35:594, 1991]. Using an antibiotic resistance protein as the expressed protein, we have been able to select mutant plasmids that produce increased levels of heterologous protein. The mutant plasmids show increased segregational stability and have lost the ability to be transformed into Escherichia coli. The same selection protocol has been used to isolate a mutant strain producing high levels of the Bacillus sphaericus mosquitocidal binary toxin. This strain shows toxicity to Culex quinquefasciatus larvae that is comparable toB. sphaericus 2362 and higher than a B. megaterium strain with the original expression plasmid. This approach may be generally useful for high-level regulated protein expression in B. megaterium.

Purine and its analogues and radiation damage in Bacillus megaterium spores

As an extension of results obtained from radiation studies on caffeine both in other laboratories and more recently in this laboratory using the bacterial spore as the test system, six compounds with chemical structures closely resembling that of caffeine were tested as radiation modifiers. Of these compounds, purine, adenine and hypoxanthine resembled caffeine in sensitizing spores to radiation, while theobromine, xanthine and theophylline did not. These responses are discussed in relation to the electron sequestration hypothesis of cellular sensitization to high-energy radiation.

Rhodium(III) as a potentiator of the effects of X-rays on cells

A rhodium compound, Rh(NH3)3Cl3, does not sensitize the spores of Bacillus megaterium to X-rays. However, it is a very effective sensitizer of vegetative cells of Staphylococcus aureus, raising the sensitivity four times in O2 and over 100 times in anoxia. The inhibition by oxygen of the sensitizing action of Rh(III), which operates over a wide range of [O2], is noteworthy. These experiments were performed in saline-phosphate buffer using 50 kVp X-rays. The results are discussed in terms of the known radiation chemistry of this compound.

Radiation sensitization of Bacillus megaterium spores by trans-dichlorodiammineplatinum(II)

The radiation sensitivity of spores of Bacillus megaterium is markedly increased by transplatin in both N2 and O2, and in a manner suggesting the involvement of hydroxyl radicals in both instances, thus differing mechanistically from its isomer cisplatin.

Isolation of recombination-defective and UV-sensitive mutants of Bacillus megaterium

Mutants of Bacillus megaterium QMB1551 sensitive to mitomycin C or methyl methanesulfonate were isolated and characterized phenotypically. Cell survival after UV-light and gamma-ray exposure was determined, as was transductional recombination. Of the mutants tested, three were sensitive to UV but remained recombination proficient. The UV-sensitive mutants were also reduced in host cell reactivation. At least three mutants had undetectable transduction frequencies, i.e., less than 0.3 to 1.3% of the parental strain frequencies, and so appear to be recombination deficient. Sensitivities of these mutant strains to UV light and gamma radiation were compared with those of parental B. megaterium as well as parental, recE4, recA1, uvrA19, and uvrB109 strains of Bacillus subtilis. In each case, the strains of B. megaterium, including the parental strains, showed a higher percentage of cell survival than B. subtilis.

Differential modification of oxic and anoxic components of radiation damage in Bacillus megaterium spores by caffeine

Studies were carried out on the effect of caffeine on the X-irradiation sensitivity of B. megaterium spores with the following results: Caffeine exerts a concentration-dependent modifying action on oxygen-dependent components of X-ray-induced damage in B. megaterium spore suspensions causing an 'over-O2 effect' at about 1 X 10(-4) mol dm-3, and as the concentration is increased to 1 X 10(-3) mol dm-3 or above, a small but consistent protection is seen. In the absence of O2, at a wide range of concentrations (8.5 X 10(-5) to 1 X 10(-1) mol dm-3), caffeine enhances the inactivation constant, k, from 1.17 to about 1.50 kGy-1. Both ethanol and t-butanol (5 X 10(-2) mol dm-3) remove the 'over O2-effect' produced by 1.10(-4) mol dm-3 caffeine in O2; such an effect, however, is not accompanied by reduction in the H2O2 concentrations in the spore suspensions. Ethanol prevents caffeine-induced anoxic sensitization, as well as H2O2 buildup. t-BuOH has no influence on either the low dose part of the log fraction survival curve or on the H2O2 yield in the spore suspensions. Caffeine reacts with radiation-induced eaq and .OH with rate constants of 1.5 X 10(10) and 6.9 X 10(9) dm3 mol-1s-1, respectively.

Influence of catalase on the radiation sensitizing effect of misonidazole

The radiation modifying action of misonidazole and catalase was investigated in Bacillus megaterium spores at various oxygen concentrations. Catalase (120 micrograms/ml) decreased the radiation sensitizing action of misonidazole. Misonidazole as an electron affinic radiation sensitizer enhanced the build up of H2O2, thus promoting the reaction with catalase. Protection by catalase was not enough to eliminate the total radiation sensitizing effect of misonidazole.

Combination of misonidazole and lipoic acid on the radiation sensitivity of Bacillus megaterium spores

The radiation sensitizing action of a combination of misonidazole and lipoic acid was investigated in Bacillus megaterium spores at various oxygen concentrations. Lipoic acid and misonidazole were applied in two concentrations (0.1 and 1.0 mmol/l) and four combinations were prepared from them. No uniform correlation was found, neither to the combination of the compounds nor to the gas conditions. The combination of two radiation sensitizing compounds with in all probability different action mechanisms does not unequivocally enhance the radiation sensitizing effect under anoxic and hypoxic conditions.

The effect of superoxide dismutase on the radiosensitivity of bacterial spores at various oxygen concentrations

Superoxide dismutases are considered to be essential protective agent against radiation injury. Experiments were carried out to investigate the effect of extracellularly added SOD on the radiosensitivity of Bacillus megaterium spores. 120 micrograms/ml SOD had no effect on the radiosensitivity of Bacillus megaterium spores at different oxygen concentrations. Relative enzyme activity obtained at various oxygen concentrations indicating the lack of oxygen effect in the radiation-induced inactivation of SOD.

A comparison of UV induced DNA photoproducts from isolated and non-isolated developing bacterial forespores

UV-induced photoproduct formation has been compared in non-isolated and isolated developing forespores. We have found that levels of spore type photoproducts are greatly affected by mother cell DNA. We have also observed the presence of the photoproduct 6-4'-(pyrimidin-2'-one)-thymine in developing forespores. We conclude from these and other data in the literature that the degree of hydration around the forespore DNA is reduced by the presence of dipicolinic acid which influences photoproduct formation without causing a change in conformational state.

Synergistic damage from H2O2 and OH radicals in irradiated cells

The anoxic sensitization of bacterial spores by added H2O2 has been studied. Two mechanistic pathways for damage from H2O2 were found; one of these requires the presence of OH radicals. For this kind of damage, the relationship between H2O2 and OH appears to be that they are reactants. O-2 (and/or HO2), the product of such a reaction, is likely the agent which actually causes damage. These results with reagent H2O2 are compared with results of experiments in which H2O2 and OH are present as radiolytic products.

Physical determinants of radiation sensitivity in bacterial spores

Several factors modifying radiation sensitivity in dry bacterial spores are described and discussed. Vacuum inducing the loss of critical structural water, very low dose rates of radiation from which the cell may recover, radiations of high linear energy transfer, and the action of temperature over long periods of time on previously irradiated cells are recognized from extensive laboratory work as important in determining survival of spores exposed to low radiation doses at low temperatures for long periods of time. Some extensions of laboratory work are proposed.

Oxygen effect, hydrogen peroxide yields, and time scale of interaction of potentially damaging species in electron pulse irradiated bacterial spores

A given integrated radiation dose delivered from a LINAC as a train of pulses (50/s), characteristically of 0.1 to 5 microseconds pulse length with dose rates within the pulse between 0.38 and 38 krads/microsecond, inactivates bacterial spores in water suspension more effectively than the same dose given as Co60 gamma rays. This enhancement of radiation damage occurs both in the presence and in the absence of oxygen and is not explained by either pulse dose rate or pulse length alone, but is monotonically related to the product of these pulse parameters, pulse dose. The enhancement appears to result from the interaction, within individual spores, of free radical species of average lifetime of about 2-5 microseconds. The time scale over which these species operate suggests that they are freely diffusable. Prevention, in part, of their damaging effect by the presence of selective scavenging agents is evidence that OH radicals are involved. Measurements of H2O2 yield for irradiation conditions that show a gradation of enhancement of damage correlate strongly with the extent of damage observed.

Breaking survival curves and oxygen removal times in irradiated bacterial spores

Although there are ambiguities about these results and their interpretations, this unambiguous experimental observation was made: the two kinds of experiments designed to measure deoxygenation times did not give the same answer, for a given N2 flushing rate, unless t-butanol was present. The addition of t-butanol caused large changes in the positions of the survival curve breakpoints, but only small changes in the 'times to anoxia' in the pre-irradiation glushing experiments. Although careful additional work is needed, these initial results suggest that in the spore, the survival curve breakpoint probably does not represent the dose at which anoxia is reached unless t-butanol is present.

Time effects in molecular radiation biology

Radiation action occurs over a broad timescale which extends from the very early physical processes associated with energy absorption to the very late biological effects, such as carcinogenesis which may not become apparent until many years later. The various temporal stages of radiation action are classified and their interrelationships described. Experimental projects in cellular radiation chemistry, including pulse radiolysis, are discussed, together with some applications of the techniques in this general area. The paper also deals with some aspects of the oxygen effect in radiobiology and the mechanisms of its action. Various studies employing fast response techniques have been useful in verifying the role of fast free radical reactions in the oxygen effects and examples are given of some applications. Investigations with other hypoxic cell sensitizers, the electron affinic agents, are also briefly discussed, with an account of how studies of the timescale of radiation sensitization can be valuable in understanding mechanisms. Possible mechanisms of action of radiation sensitization by oxygen and other agents, including radical fixation and direct action processes, are considered in the light of evidence from some model systems.

Effects of some hypoxic cell radiosensitizers on the decay of potentially lethal oxygen-dependent damage in fully hydrated spores

Using a stopped-flow mixing and pulsed irradiation apparatus, a study has been made of the decay, to a harmless form, of radiation-induced species that would otherwise be lethal to spores on contact with oxygen. Aqueous suspensions of Bacillus megaterium spores were irradiated with electrons for approximately 1 s; at various times after irradiation oxygen in solution was added. As the interval between anoxic irradiation and introduction of oxygen increased, the fraction of spores surviving increased. This change in survival reflects the decay of potentially lethal species. The presence of electron-affinic radiosensitizers during irradiation enhanced the decay rate of this damage, the greatest enhancement being seen with sensitizers of the highest electron affinity. In contrast, the nitroxyl-free radical sensitizer TAN fixed the radiation-induced damage so that no increase in survival, and hence no decay, was seen.

The decay of potentially lethal oxygen-dependent damage in fully hydrated Bacillus megaterium spores exposed to pulsed electron irradiation

Using a stopped-flow mixing and pulsed irradiation apparatus, a study has been made of the decay, to a harmless form, of radiation-induced species which would otherwise be lethal to spores on contact with oxygen. Aqueous suspensions of Bacillus megaterium spores were irradiated with 600 krad of electrons given over approximately 1 s; at various times after irradiation oxygen in solution was added. As the interval between irradiation and introduction of oxygen increased, the fraction of spores surviving increased. For spores irradiated in a deoxygenated condition the decay of the potentially lethal species, reflected by this change in survival, proceeded as if two parallel first-order reactions with half-lives of 9 and 120 s operate. In contrast, for spores equilibrated with oxygen and then irradiated, the decay is described by a single first-order expression with an associated half-life similar to that of the faster of the two reactions operating in anoxia.

Irradiation of bacterial spores in water: three classes of oxygen-denpendent damage

Studies of irradiated bacterial spores in aqueous suspension indicate that the sensitization of spores by oxygen can depend on three chemical processes. One of these processes involves reactions of hydroxyl radicals; the other two apparently do not.

Effects of some -OH scavengers on the radiation sensitization of bacterial spores by p-nitroacetophenone and O2 in suspension

Spores of Bacillus megaterium were irradiated in suspension with 50 kVp X-rays under three reference conditions: in anoxia (i.e., 100 per cent N2); in anoxia with 2mM p-nitroacetophenone (PNAP), a concentration that shows the maximum amount of sensitization by this agent; and in air. The responses were then measured when different concentrations of an hydroxyl radical scavenger were also present. Allyl alcohol, t-amyl alcohol, t-butanol, ethanol, glycerol, the formate ion, and methanol were the -OH scavengers that were used. A comparison of the effects these additives have on the three reference responses provides indirect, comparative information on the sensitizing processes of PNAP and O2. Neither t-amyl alcohol nor t-butanol affects the response in air or N2 alone. Both these additives, however, can reduce the sensitization from PNAP slightly. The other additives have significant protective effects under the three conditions. In general, the additives have similar effects in air and in 100 per cent N2 but much greater protective effects in PNAP. Although the sensitizing mechanisms are not identified by these experiments, the effects of O2 and PNAP, as judged by the desensitizing actions of these additives, appear quite different.

Identification and localization of the major proteins degraded during germination of Bacillus megaterium spores

Of the 15 to 20% of total spore protein which is degraded during germination of spores of Bacillus megaterium, greater than 80% is derived from a protein fraction soluble in dilute acids such as acetic acid that contains two major proteins, termed A and B. These two proteins are low or absent in germinated spores, log phase cells, and early stationary phase cells, but both are synthesized and appear in parallel late in sporulation after the appearance of nonrefractile forespores but before the appearance of refractile spores. These proteins accumulate during the time that the developing spore becomes resistant to ultraviolet light but well before acquisition of heat resistance. Both proteins are located in the core of the dormant spore, but analysis of ruptured spores has revealed no binding of protein A or B to ribosomes, membranes, or DNA.

Two components in the radiation sensitization of bacterial spores by p-nitroacetophenone: the -OH component

p-Nitroacetophenone (PNAP) sensitizes Bacillus megaterium spores under anoxic conditions to the lethal effects of 50 kVp X-rays. Concentrations between approximately 5 X 10(-4) M and 3-8 X 10(-3) M produce the maximum effect, an increase of about 30 per cent over the anoxic response when the spores are irradiated in water. Compounds that scavenge -OH decrease, but cannot completely eliminate, this maximum amount of sensitization. These results indicate that PNAP acts to increase spores' radiation sensitivity through two separable types of chemical reactions: one which involves -OH and one which does not. Possible mechanisms responsible for these two components of damage are discussed. In these experiments 1/15 M phosphate buffer acts in several unexpected ways. This concentration itself increased the anoxic spore response by about 9 per cent (relative to the anoxic response in water). In addition, although the maximum amounts of sensitization were the same, the amounts of sensitization from lower PNAP concentrations differed when the suspending fluid was buffer instead of water. An interaction was also seen during the PNAP-t-butanol experiments; again, the responses at low PNAP concentrations were different in buffer and in water. No mechanisms for these actions of this buffer were suggested, although somewhat similar effects may occur with other organisms. Clearly, such effects must be recognized and evaluated before quantitative analyses of the actions of sensitivity-modifying agents can be completed.