In Vitro and In Vivo Oxidation of Methionine Residues in Small, Acid-Soluble Spore Proteins from Bacillus Species

Methionine residues in α/β-type small, acid-soluble spore proteins (SASP) of Bacillus species were readily oxidized to methionine sulfoxide in vitro by t-butyl hydroperoxide (tBHP) or hydrogen peroxide (H₂O₂). These oxidized α/β-type SASP no longer bound to DNA effectively, but DNA binding protected α/β-type SASP against methionine oxidation by peroxides in vitro. Incubation of an oxidized α/β-type SASP with peptidyl methionine sulfoxide reductase (MsrA), which can reduce methionine sulfoxide residues back to methionine, restored the α/β-type SASP’s ability to bind to DNA. Both tBHP and H₂O₂ caused some oxidation of the two methionine residues of an α/β-type SASP (SspC) in spores of Bacillus subtilis, although one methionine which is highly conserved in α/β-type SASP was only oxidized to a small degree. However, much more methionine sulfoxide was generated by peroxide treatment of spores carrying a mutant form of SspC which has a lower affinity for DNA. MsrA activity was present in wild-type B. subtilis spores. However, msrA mutant spores were no more sensitive to H₂O₂ than were wild-type spores. The major mechanism operating for dealing with oxidative damage to α/β-type SASP in spores is DNA binding, which protects the protein’s methionine residues from oxidation both in vitro and in vivo. This may be important in vivo since α/β-type SASP containing oxidized methionine residues no longer bind DNA well and α/β-type SASP-DNA binding is essential for long-term spore survival.     

Resistance of Bacillus subtilis Spore DNA to Lethal Ionizing Radiation Damage Relies Primarily on Spore Core Components and DNA Repair,with Minor Effects of Oxygen Radical Detoxification

The roles of various core components, including α/β/γ-type small acid-soluble spore proteins (SASP), dipicolinic acid (DPA), core water content, and DNA repair by apurinic/apyrimidinic (AP) endonucleases or nonhomologous end joining (NHEJ), in Bacillus subtilis spore resistance to different types of ionizing radiation including X rays, protons, and high-energy charged iron ions have been studied. Spores deficient in DNA repair by NHEJ or AP endonucleases, the oxidative stress response, or protection by major α/β-type SASP, DPA, and decreased core water content were significantly more sensitive to ionizing radiation than wild-type spores, with highest sensitivity to high-energy-charged iron ions. DNA repair via NHEJ and AP endonucleases appears to be the most important mechanism for spore resistance to ionizing radiation, whereas oxygen radical detoxification via the MrgA-mediated oxidative stress response or KatX catalase activity plays only a very minor role. Synergistic radioprotective effects of α/β-type but not γ-type SASP were also identified, indicating that α/β-type SASP''s binding to spore DNA is important in preventing DNA damage due to reactive oxygen species generated by ionizing radiation.     

Small, Acid-Soluble Spore Proteins of the α/β Type Do Not Protect the DNA in Bacillus subtilis Spores against Base Alkylation

Ethyl methanesulfonate (EMS) killed wild-type Bacillus subtilis spores as rapidly as spores lacking small, acid-soluble proteins (SASP) of the α/β type (α⁻β⁻ spores), and 20% of the survivors had obvious mutations. A recA mutation increased the EMS sensitivity of wild-type and α⁻β⁻ spores similarly but reduced their mutagenesis; EMS treatment of dormant spores also resulted in the induction of RecA synthesis during spore germination. EMS generated similar levels of alkylated bases in wild-type and α⁻β⁻ spore DNAs, in purified DNA, or in DNA saturated with α/β-type SASP. Ethylene oxide (EtO) also generated similar levels of base alkylation in wild-type and α⁻β⁻ spore DNAs. These data indicate that EMS and EtO kill spores at least in part by DNA damage but that α/β-type SASP, which protect DNA against many types of damage, do not protect spore DNA from base alkylation.     

Antisense-RNA-Mediated Decreased Synthesis of Small, Acid-Soluble Spore Proteins Leads to Decreased Resistance of Clostridium perfringens Spores to Moist Heat and UV Radiation

Previous work has suggested that a group of α/β-type small, acid-soluble spore proteins (SASP) is involved in the resistance of Clostridium perfringens spores to moist heat. However, this suggestion is based on the analysis of C. perfringens spores lacking only one of the three genes encoding α/β-type SASP in this organism. We have now used antisense RNA to decrease levels of α/β-type SASP in C. perfringens spores by ~90%. These spores had significantly reduced resistance to both moist heat and UV radiation but not to dry heat. These results clearly demonstrate the important role of α/β-type SASP in the resistance of C. perfringens spores.     

Roles of the major, small, acid-soluble spore proteins and spore-specific and universal DNA repair mechanisms in resistance of Bacillus subtilis spores to ionizing radiation from X rays and high-energy charged-particle bombardment

The role of DNA repair by nonhomologous end joining (NHEJ), homologous recombination, spore photoproduct lyase, and DNA polymerase I and genome protection via α/β-type small, acid-soluble spore proteins (SASP) in Bacillus subtilis spore resistance to accelerated heavy ions (high-energy charged [HZE] particles) and X rays has been studied. Spores deficient in NHEJ and α/β-type SASP were significantly more sensitive to HZE particle bombardment and X-ray irradiation than were the recA, polA, and splB mutant and wild-type spores, indicating that NHEJ provides an efficient DNA double-strand break repair pathway during spore germination and that the loss of the α/β-type SASP leads to a significant radiosensitivity to ionizing radiation, suggesting the essential function of these spore proteins as protectants of spore DNA against ionizing radiation.     

Comparative Study of Pressure-Induced Germination of Bacillus subtilis Spores at Low and High Pressures

We have studied pressure-induced germination of Bacillus subtilis spores at moderate (100 MPa) and high (500 to 600 MPa) pressures. Although we found comparable germination efficiencies under both conditions by using heat sensitivity as a criterion for germination, the sensitivity of pressure-germinated spores to some other agents was found to depend on the pressure used. Spores germinated at 100 MPa were more sensitive to pressure (>200 MPa), UV light, and hydrogen peroxide than were those germinated at 600 MPa. Since small, acid-soluble proteins (SASPs) and dipicolinic acid (DPA) are known to be involved in spore resistance to UV light and hydrogen peroxide, we studied the fate of these compounds during pressure germination. DPA was released upon both low- and high-pressure germination, but SASP degradation, which normally accompanies nutrient-induced germination, occurred upon low-pressure germination but not upon high-pressure germination. These results adequately explain the UV and hydrogen peroxide resistance of spores germinated at 600 MPa. The resistance to pressure inactivation of 600-MPa-germinated spores could also, at least partly, be attributed to α/β-type SASPs, since mutants deficient in α/β-type SASPs were more sensitive to inactivation at 600 MPa. Further, germination at 100 MPa resulted in rapid ATP generation, as is the case in nutrient-induced germination, but no ATP was formed during germination at 600 MPa. These results suggest that spore germination can be initiated by low- and high-pressure treatments but is arrested at an early stage in the latter case. The implications for the use of high pressure as a preservation treatment are discussed.     

Role of the Nfo and ExoA apurinic/apyrimidinic endonucleases in repair of DNA damage during outgrowth of Bacillus subtilis spores

Germination and outgrowth are critical steps for returning Bacillus subtilis spores to life. However, oxidative stress due to full hydration of the spore core during germination and activation of metabolism in spore outgrowth may generate oxidative DNA damage that in many species is processed by apurinic/apyrimidinic (AP) endonucleases. B. subtilis spores possess two AP endonucleases, Nfo and ExoA; the outgrowth of spores lacking both of these enzymes was slowed, and the spores had an elevated mutation frequency, suggesting that these enzymes repair DNA lesions induced by oxidative stress during spore germination and outgrowth. Addition of H₂O₂ also slowed the outgrowth of nfo exoA spores and increased the mutation frequency, and nfo and exoA mutations slowed the outgrowth of spores deficient in either RecA, nucleotide excision repair (NER), or the DNA-protective α/β-type small acid-soluble spore proteins (SASP). These results suggest that α/β-type SASP protect DNA of germinating spores against damage that can be repaired by Nfo and ExoA, which is generated either spontaneously or promoted by addition of H₂O₂. The contribution of RecA and Nfo/ExoA was similar to but greater than that of NER in repair of DNA damage generated during spore germination and outgrowth. However, nfo and exoA mutations increased the spontaneous mutation frequencies of outgrown spores lacking uvrA or recA to about the same extent, suggesting that DNA lesions generated during spore germination and outgrowth are processed by Nfo/ExoA in combination with NER and/or RecA. These results suggest that Nfo/ExoA, RecA, the NER system, and α/β-type SASP all contribute to the repair of and/or protection against oxidative damage of DNA in germinating and outgrowing spores.     

Photosensitization of DNA by dipicolinic acid, a major component of spores of Bacillus species.

The DNA in spores of Bacillus species exhibits a relatively novel photochemistry, as 5-thyminyl-5,6-dihydrothymine (spore photoproduct (SP)) is by far the major UV photoproduct whereas cyclobutane dimers (CPDs) and (6-4) photoproducts (6-4PPs) are the major photoproducts in growing cells. Dehydration and more importantly complexation of DNA by alpha/beta-type small, acid-soluble spore proteins (SASP) have been shown to partly explain the photochemistry of spore DNA. The large amount ( approximately 10% of dry weight) of the spore's dipicolinic acid (DPA) also has been shown to play a role in spore DNA photochemistry. In the present work we showed by exposing spores of various strains of B. subtilis to UVC radiation that DPA photosensitizes spore DNA to damage and favors the formation of SP. The same result was obtained in either the presence or absence of the alpha/beta-type SASP that saturate the spore chromosome. Addition of DPA to dry films of isolated DNA or to frozen solutions of thymidine also led to a higher yield of SP and increased ratio of CPDs to 6-4PPs; DPA also significantly increased the yield of CPDs in thymidine exposed to UVC in liquid solution. These observations strongly support a triplet energy transfer between excited DPA and thymine residues. We further conclude that the combined effects of alpha/beta-type SASP and DPA explain the novel photochemistry of DNA in spores of Bacillus species.     

Heat Killing of Bacillus subtilis Spores in Water Is Not Due to Oxidative Damage

The heat resistance of wild-type spores of Bacillus subtilis or spores (termed α⁻β⁻) lacking DNA protective α/β-type small, acid-soluble spore proteins was not altered by anaerobiosis or high concentrations of the free radical scavenging agents ethanethiol and ethanedithiol. Heat-killed wild-type and α⁻β⁻ spores exhibited no increase in either protein carbonyl content or oxidized bases in DNA. These data strongly suggest that oxidative damage to spore macromolecules does not contribute significantly to spore killing by heat.     

DNA in dormant spores of Bacillus species is in an A-like conformation

The DNA in dormant spores of Bacillus species is associated with alpha/beta-type small, acid-soluble proteins (SASP), which are double-stranded DNA-binding proteins whose amino acid sequence has been highly conserved in evolution. In vitro these proteins bind most strongly to DNA which readily adopts an A-like conformation, as binding of alpha/beta-type SASP causes DNA to assume an A-like conformation. As predicted by this conformational change in DNA, binding of alpha/beta-type SASP to relaxed but covalently closed plasmid DNA results in the introduction of a large number of negative supercoils. Associated with the conformational change in DNA brought about by alpha/beta-type SASP binding is a change in its photochemistry such that ultraviolet irradiation does not generate pyrimidine dimers, but rather a thyminyl-thymine adduct termed spore photoproduct (SP). The latter two properties of DNA complexed with alpha/beta-type SASP in vitro are similar to those of DNA in dormant spores of Bacillus species in which: (i) plasmid DNA has a much higher number of negative supercoils than plasmid in growing cells; and (ii) ultraviolet irradiation produces SP and no pyrimidine dimers, while only pyrimidine dimers are formed in growing cells. During sporulation these changes in the properties of spore DNA take place in parallel with synthesis of alpha/beta-type SASP, and the magnitude of the changes is greatly reduced in mutants that make low amounts of these proteins. A straightforward interpretation of these data is that DNA in dormant spores of Bacillus species is in an A-like conformation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of DNA Protection and Repair in Resistance of Bacillus subtilis Spores to Ultrahigh Shock Pressures Simulating Hypervelocity Impacts

Impact-induced ejections of rocks from planetary surfaces are frequent events in the early history of the terrestrial planets and have been considered as a possible first step in the potential interplanetary transfer of microorganisms. Spores of Bacillus subtilis were used as a model system to study the effects of a simulated impact-caused ejection on rock-colonizing microorganisms using a high-explosive plane wave setup. Embedded in different types of rock material, spores were subjected to extremely high shock pressures (5 to 50 GPa) lasting for fractions of microseconds to seconds. Nearly exponential pressure response curves were obtained for spore survival and linear dependency for the induction of sporulation-defective mutants. Spores of strains defective in major small, acid-soluble spore proteins (SASP) (α/β-type SASP) that largely protect the spore DNA and spores of strains deficient in nonhomologous-end-joining DNA repair were significantly more sensitive to the applied shock pressure than were wild-type spores. These results indicate that DNA may be the sensitive target of spores exposed to ultrahigh shock pressures. To assess the nature of the critical physical parameter responsible for spore inactivation by ultrahigh shock pressures, the resulting peak temperature was varied by lowering the preshock temperature, changing the rock composition and porosity, or increasing the water content of the samples. Increased peak temperatures led to increased spore inactivation and reduced mutation rates. The data suggested that besides the potential mechanical stress exerted by the shock pressure, the accompanying high peak temperatures were a critical stress parameter that spores had to cope with.     

Prevention of DNA damage in spores and in vitro by small, acid-soluble proteins from Bacillus species.

The DNA in dormant spores of Bacillus species is saturated with a group of nonspecific DNA-binding proteins, termed alpha/beta-type small, acid-soluble spore proteins (SASP). These proteins alter DNA structure in vivo and in vitro, providing spore resistance to UV light. In addition, heat treatments (e.g., 85 degrees C for 30 min) which give little killing of wild-type spores of B. subtilis kill > 99% of spores which lack most alpha/beta-type SASP (termed alpha - beta - spores). Similar large differences in survival of wild-type and alpha - beta - spores were found at 90, 80, 65, 22, and 10 degrees C. After heat treatment (85 degrees C for 30 min) or prolonged storage (22 degrees C for 6 months) that gave > 99% killing of alpha - beta - spores, 10 to 20% of the survivors contained auxotrophic or asporogenous mutations. However, alpha - beta - spores heated for 30 min at 85 degrees C released no more dipicolinic acid than similarly heated wild-type spores (< 20% of the total dipicolinic acid) and triggered germination normally. In contrast, after a heat treatment (93 degrees C for 30 min) that gave > or = 99% killing of wild-type spores, < 1% of the survivors had acquired new obvious mutations, > 85% of the spore's dipicolinic acid had been released, and < 1% of the surviving spores could initiate spore germination. Analysis of DNA extracted from heated (85 degrees C, 30 min) and unheated wild-type spores and unheated alpha - beta - spores revealed very few single-strand breaks (< 1 per 20 kb) in the DNA. In contrast, the DNA from heated alpha- beta- spores had more than 10 single-strand breaks per 20 kb. These data suggest that binding of alpha/beta-type SASP to spore DNA in vivo greatly reduces DNA damage caused by heating, increasing spore heat resistance and long-term survival. While the precise nature of the initial DNA damage after heating of alpha- beta- spores that results in the single-strand breaks is not clear, a likely possibility is DNA depurination. A role for alpha/beta-type SASP in protecting DNA against depurination (and thus promoting spore survival) was further suggested by the demonstration that these proteins reduce the rate of DNA depurination in vitro at least 20-fold.     

Roles of Small,Acid-Soluble Spore Proteins and Core Water Content in Survival of Bacillus subtilis Spores Exposed to Environmental Solar UV Radiation

Spores of Bacillus subtilis contain a number of small, acid-soluble spore proteins (SASP) which comprise up to 20% of total spore core protein. The multiple α/β-type SASP have been shown to confer resistance to UV radiation, heat, peroxides, and other sporicidal treatments. In this study, SASP-defective mutants of B. subtilis and spores deficient in dacB, a mutation leading to an increased core water content, were used to study the relative contributions of SASP and increased core water content to spore resistance to germicidal 254-nm and simulated environmental UV exposure (280 to 400 nm, 290 to 400 nm, and 320 to 400 nm). Spores of strains carrying mutations in sspA, sspB, and both sspA and sspB (lacking the major SASP-α and/or SASP-β) were significantly more sensitive to 254-nm and all polychromatic UV exposures, whereas the UV resistance of spores of the sspE strain (lacking SASP-γ) was essentially identical to that of the wild type. Spores of the dacB-defective strain were as resistant to 254-nm UV-C radiation as wild-type spores. However, spores of the dacB strain were significantly more sensitive than wild-type spores to environmental UV treatments of >280 nm. Air-dried spores of the dacB mutant strain had a significantly higher water content than air-dried wild-type spores. Our results indicate that α/β-type SASP and decreased spore core water content play an essential role in spore resistance to environmentally relevant UV wavelengths whereas SASP-γ does not.Spores of Bacillus spp. are highly resistant to inactivation by different physical stresses, such as toxic chemicals and biocidal agents, desiccation, pressure and temperature extremes, and high fluences of UV or ionizing radiation (reviewed in references 33, 34, and 48). Under stressful environmental conditions, cells of Bacillus spp. produce endospores that can stay dormant for extended periods. The reason for the high resistance of bacterial spores to environmental extremes lies in the structure of the spore. Spores possess thick layers of highly cross-linked coat proteins, a modified peptidoglycan spore cortex, a low core water content, and abundant intracellular constituents, such as the calcium chelate of dipicolinic acid and α/β-type small, acid-soluble spore proteins (α/β-type SASP), the last two of which protect spore DNA (6, 42, 46, 48, 52). DNA damage accumulated during spore dormancy is also efficiently repaired during spore germination (33, 47, 48). UV-induced DNA photoproducts are repaired by spore photoproduct lyase and nucleotide excision repair, DNA double-strand breaks (DSB) by nonhomologous end joining, and oxidative stress-induced apurinic/apyrimidinic (AP) sites by AP endonucleases and base excision repair (15, 26-29, 34, 43, 53, 57).Monochromatic 254-nm UV radiation has been used as an efficient and cost-effective means of disinfecting surfaces, building air, and drinking water supplies (31). Commonly used test organisms for inactivation studies are bacterial spores, usually spores of Bacillus subtilis, due to their high degree of resistance to various sporicidal treatments, reproducible inactivation response, and safety (1, 8, 19, 31, 48). Depending on the Bacillus species analyzed, spores are 10 to 50 times more resistant than growing cells to 254-nm UV radiation. In addition, most of the laboratory studies of spore inactivation and radiation biology have been performed using monochromatic 254-nm UV radiation (33, 34). Although 254-nm UV-C radiation is a convenient germicidal treatment and relevant to disinfection procedures, results obtained by using 254-nm UV-C are not truly representative of results obtained using UV wavelengths that endospores encounter in their natural environments (34, 42, 50, 51, 59). However, sunlight reaching the Earth''s surface is not monochromatic 254-nm radiation but a mixture of UV, visible, and infrared radiation, with the UV portion spanning approximately 290 to 400 nm (33, 34, 36). Thus, our knowledge of spore UV resistance has been constructed largely using a wavelength of UV radiation not normally reaching the Earth''s surface, even though ample evidence exists that both DNA photochemistry and microbial responses to UV are strongly wavelength dependent (2, 30, 33, 36).Of recent interest in our laboratories has been the exploration of factors that confer on B. subtilis spores resistance to environmentally relevant extreme conditions, particularly solar UV radiation and extreme desiccation (23, 28, 30, 34 36, 48, 52). It has been reported that α/β-type SASP but not SASP-γ play a major role in spore resistance to 254-nm UV-C radiation (20, 21) and to wet heat, dry heat, and oxidizing agents (48). In contrast, increased spore water content was reported to affect B. subtilis spore resistance to moist heat and hydrogen peroxide but not to 254-nm UV-C (12, 40, 48). However, the possible roles of SASP-α, -β, and -γ and core water content in spore resistance to environmentally relevant solar UV wavelengths have not been explored. Therefore, in this study, we have used B. subtilis strains carrying mutations in the sspA, sspB, sspE, sspA and sspB, or dacB gene to investigate the contributions of SASP and increased core water content to the resistance of B. subtilis spores to 254-nm UV-C and environmentally relevant polychromatic UV radiation encountered on Earth''s surface.     

Small, Acid-Soluble Proteins as Biomarkers in Mass Spectrometry Analysis of Bacillus Spores

The use of 1 N HCl for extraction of small, acid-soluble proteins (SASP) from different Bacillus spore species was examined. The extracts were analyzed by high-performance liquid chromatography and matrix-assisted laser desorption mass spectrometry and were found to be both qualitatively and quantitatively superior to extraction by acetonitrile-5% trifluoroacetic acid (70:30, vol/vol). Both major and minor α/β- and γ-type SASP were characterized by their molecular masses or tryptic peptide maps and by searches of both protein and unannotated genome databases. For all but 1 pair (B. cereus T and B. thuringiensis subsp. Kurstaki) among the 11 variants studied the suites of SASP masses are distinctive, consistent with the use of these proteins as potential biomarkers for spore identification by mass spectrometry.     

Analysis of deamidation of small, acid-soluble spore proteins from Bacillus subtilis in vitro and in vivo.

Deamidation of one specific asparagine residue in an alpha/beta-type small, acid-soluble spore protein (SASP) of Bacillus subtilis took place readily in vitro (time for 50% deamidation [t(1/2)], approximately 1 h at 70 degrees C), and the deamidated SASP no longer bound to DNA effectively. However, DNA binding protected against this deamidation in vitro. A mutant alpha/beta-type SASP in which the reactive asparagine was changed to aspartate also failed to bind to DNA in vitro, and this protein did not restore UV radiation and heat resistance to spores lacking the majority of their alpha/beta-type SASP. When expressed in Escherichia coli, where it is bound to DNA, the alpha/beta-type SASP deamidated with a t(1/2) of 2 to 3 h at 95 degrees C. However, the alpha/beta-type SASP was extremely resistant to deamidation within spores (t(1/2), >50 h at 95 degrees C). A gamma-type SASP of B. subtilis also deamidated readily in vitro (t(1/2) for one net deamidation, approximately 1 h at 70 degrees C), but this protein (which is not associated with DNA) deamidated fairly readily in spores (t(1/2), approximately 1 h at 95 degrees C). Total spore core protein also deamidated in vivo, although the rate was two- to threefold slower than that of deamidation of total protein in heated vegetative cells. These data indicate that protein deamidation is slowed significantly in spores, presumably due to the spore's environment. However, alpha/beta-type SASP are even more strongly protected against deamidation in vivo, presumably by their binding to spore DNA. Thus, not only do alpha/beta-type SASP protect spore DNA from damage; DNA also protects alpha/beta-type SASP.     

Role of dipicolinic acid in resistance and stability of spores of Bacillus subtilis with or without DNA-protective alpha/beta-type small acid-soluble proteins

Dipicolinic acid (DPA) comprises approximately 10% of the dry weight of spores of Bacillus species. Although DPA has long been implicated in spore resistance to wet heat and spore stability, definitive evidence on the role of this abundant molecule in spore properties has generally been lacking. Bacillus subtilis strain FB122 (sleB spoVF) produced very stable spores that lacked DPA, and sporulation of this strain with DPA yielded spores with nearly normal DPA levels. DPA-replete and DPA-less FB122 spores had similar levels of the DNA protective alpha/beta-type small acid-soluble spore proteins (SASP), but the DPA-less spores lacked SASP-gamma. The DPA-less FB122 spores exhibited similar UV resistance to the DPA-replete spores but had lower resistance to wet heat, dry heat, hydrogen peroxide, and desiccation. Neither wet heat nor hydrogen peroxide killed the DPA-less spores by DNA damage, but desiccation did. The inability to synthesize both DPA and most alpha/beta-type SASP in strain PS3664 (sspA sspB sleB spoVF) resulted in spores that lost viability during sporulation, at least in part due to DNA damage. DPA-less PS3664 spores were more sensitive to wet heat than either DPA-less FB122 spores or DPA-replete PS3664 spores, and the latter also retained viability during sporulation. These and previous results indicate that, in addition to alpha/beta-type SASP, DPA also is extremely important in spore resistance and stability and, further, that DPA has some specific role(s) in protecting spore DNA from damage. Specific roles for DPA in protecting spore DNA against damage may well have been a major driving force for the spore's accumulation of the high levels of this small molecule.     

Role of the Nfo and ExoA apurinic/apyrimidinic endonucleases in radiation resistance and radiation-induced mutagenesis of Bacillus subtilis spores

The roles of DNA repair by apurinic/apyrimidinic (AP) endonucleases alone, and together with DNA protection by α/β-type small acid-soluble spore proteins (SASP), in Bacillus subtilis spore resistance to different types of radiation have been studied. Spores lacking both AP endonucleases (Nfo and ExoA) and major SASP were significantly more sensitive to 254-nm UV-C, environmental UV (>280 nm), X-ray exposure, and high-energy charged (HZE)-particle bombardment and had elevated mutation frequencies compared to those of wild-type spores and spores lacking only one or both AP endonucleases or major SASP. These findings further implicate AP endonucleases and α/β-type SASP in repair and protection, respectively, of spore DNA against effects of UV and ionizing radiation.     

The Bacillus subtilis HBsu protein modifies the effects of alpha/beta-type, small acid-soluble spore proteins on DNA

HBsu, the Bacillus subtilis homolog of the Escherichia coli HU proteins and the major chromosomal protein in vegetative cells of B. subtilis, is present at similar levels in vegetative cells and spores ( approximately 5 x 10(4) monomers/genome). The level of HBsu in spores was unaffected by the presence or absence of the alpha/beta-type, small acid-soluble proteins (SASP), which are the major chromosomal proteins in spores. In developing forespores, HBsu colocalized with alpha/beta-type SASP on the nucleoid, suggesting that HBsu could modulate alpha/beta-type SASP-mediated properties of spore DNA. Indeed, in vitro studies showed that HBsu altered alpha/beta-type SASP protection of pUC19 from DNase digestion, induced negative DNA supercoiling opposing alpha/beta-type SASP-mediated positive supercoiling, and greatly ameliorated the alpha/beta-type SASP-mediated increase in DNA persistence length. However, HBsu did not significantly interfere with the alpha/beta-type SASP-mediated changes in the UV photochemistry of DNA that explain the heightened resistance of spores to UV radiation. These data strongly support a role for HBsu in modulating the effects of alpha/beta-type SASP on the properties of DNA in the developing and dormant spore.     

Spore Photoproduct Lyase from Bacillus subtilis Spores Is a Novel Iron-Sulfur DNA Repair Enzyme Which Shares Features with Proteins such as Class III Anaerobic Ribonucleotide Reductases and Pyruvate-Formate Lyases

The major photoproduct in UV-irradiated spore DNA is the unique thymine dimer 5-thyminyl-5,6-dihydrothymine, commonly referred to as spore photoproduct (SP). An important determinant of the high UV resistance of Bacillus subtilis spores is the accurate in situ reversal of SP during spore germination by the DNA repair enzyme SP lyase. To study the molecular aspects of SP lyase-mediated SP repair, the cloned B. subtilis splB gene was engineered to encode SP lyase with a molecular tag of six histidine residues at its amino terminus. The engineered six-His-tagged SP lyase expressed from the amyE locus restored UV resistance to spores of a UV-sensitive mutant B. subtilis strain carrying a deletion-insertion mutation which removed the entire splAB operon at its natural locus and was shown to repair SP in vivo during spore germination. The engineered SP lyase was purified both from dormant B. subtilis spores and from an Escherichia coli overexpression system by nickel-nitrilotriacetic acid (NTA) agarose affinity chromatography and was shown by Western blotting, UV-visible spectroscopy, and iron and acid-labile sulfide analysis to be a 41-kDa iron-sulfur (Fe-S) protein, consistent with its amino acid sequence homology to the 4Fe-4S clusters in anaerobic ribonucleotide reductases and pyruvate-formate lyases. SP lyase was capable of reversing SP from purified SP-containing DNA in an in vitro reaction either when present in a cell-free extract prepared from dormant spores or after purification on nickel-NTA agarose. SP lyase activity was dependent upon reducing conditions and addition of S-adenosylmethionine as a cofactor.