Manganese Oxidation by Spores and Spore Coats of a Marine Bacillus Species

Bacillus sp. strain SG-1 is a marine bacterial species isolated from a near-shore manganese sediment sample. Its mature dormant spores promote the oxidation of Mn²⁺ to MnO₂. By quantifying the amounts of immobilized and oxidized manganese, it was established that bound manganese was almost instantaneously oxidized. When the final oxidation of manganese by the spores was partly inhibited by NaN₃ or anaerobiosis, an equivalent decrease in manganese immobilization was observed. After formation of a certain amount of MnO₂ by the spores, the oxidation rate decreased. A maximal encrustment was observed after which no further oxidation occurred. The oxidizing activity could be recovered by reduction of the MnO₂ with hydroxylamine. Once the spores were encrusted, they could bind significant amounts of manganese, even when no oxidation occurred. Purified spore coat preparations oxidized manganese at the same rate as intact spores. During the oxidation of manganese in spore coat preparations, molecular oxygen was consumed and protons were liberated. The data indicate that a spore coat component promoted the oxidation of Mn²⁺ in a biologically catalyzed process, after adsorption of the ion to incipiently formed MnO₂. Eventually, when large amounts of MnO₂ were allowed to accumulate, the active sites were masked and further oxidation was prevented.     

Manganese(II)-Oxidizing Bacillus Spores in Guaymas Basin Hydrothermal Sediments and Plumes

Microbial oxidation and precipitation of manganese at deep-sea hydrothermal vents are important oceanic biogeochemical processes, yet nothing is known about the types of microorganisms or mechanisms involved. Here we report isolation of a number of diverse spore-forming Mn(II)-oxidizing Bacillus species from Guaymas Basin, a deep-sea hydrothermal vent environment in the Gulf of California, where rapid microbially mediated Mn(II) oxidation was previously observed. mnxG multicopper oxidase genes involved in Mn(II) oxidation were amplified from all Mn(II)-oxidizing Bacillus spores isolated, suggesting that a copper-mediated mechanism of Mn(II) oxidation could be important at deep-sea hydrothermal vents. Phylogenetic analysis of 16S rRNA and mnxG genes revealed that while many of the deep-sea Mn(II)-oxidizing Bacillus species are very closely related to previously recognized isolates from coastal sediments, other organisms represent novel strains and clusters. The growth and Mn(II) oxidation properties of these Bacillus species suggest that in hydrothermal sediments they are likely present as spores that are active in oxidizing Mn(II) as it emerges from the seafloor.     

Enzymatic Manganese(II) Oxidation by a Marine α-Proteobacterium

A yellow-pigmented marine bacterium, designated strain SD-21, was isolated from surface sediments of San Diego Bay, San Diego, Calif., based on its ability to oxidize soluble Mn(II) to insoluble Mn(III, IV) oxides. 16S rRNA analysis revealed that this organism was most closely related to members of the genus Erythrobacter, aerobic anoxygenic phototrophic bacteria within the α-4 subgroup of the Proteobacteria (α-4 Proteobacteria). SD-21, however, has a number of distinguishing phenotypic features relative to Erythrobacter species, including the ability to oxidize Mn(II). During the logarithmic phase of growth, this organism produces Mn(II)-oxidizing factors of ≈250 and 150 kDa that are heat labile and inhibited by both azide and o-phenanthroline, suggesting the involvement of a metalloenzyme. Although the expression of the Mn(II) oxidase was not dependent on the presence of Mn(II), higher overall growth yields were reached in cultures incubated with Mn(II) in the culture medium. In addition, the rate of Mn(II) oxidation appeared to be slower in cultures grown in the light. This is the first report of Mn(II) oxidation within the α-4 Proteobacteria as well as the first Mn(II)-oxidizing proteins identified in a marine gram-negative bacterium.     

Cobalt(II) Oxidation by the Marine Manganese(II)-Oxidizing Bacillus sp. Strain SG-1

The geochemical cycling of cobalt (Co) has often been considered to be controlled by the scavenging and oxidation of Co(II) on the surface of manganese [Mn(III,IV)] oxides or manganates. Because Mn(II) oxidation in the environment is often catalyzed by bacteria, we have investigated the ability of Mn(II)-oxidizing bacteria to bind and oxidize Co(II) in the absence of Mn(II) to determine whether some Mn(II)-oxidizing bacteria also oxidize Co(II) independently of Mn oxidation. We used the marine Bacillus sp. strain SG-1, which produces mature spores that oxidize Mn(II), apparently due to a protein in their spore coats (R.A. Rosson and K. H. Nealson, J. Bacteriol. 151:1027-1034, 1982; J. P. M. de Vrind et al., Appl. Environ. Microbiol. 52:1096-1100, 1986). A method to measure Co(II) oxidation using radioactive ⁵⁷Co as a tracer and treatments with nonradioactive (cold) Co(II) and ascorbate to discriminate bound Co from oxidized Co was developed. SG-1 spores were found to oxidize Co(II) over a wide range of pH, temperature, and Co(II) concentration. Leucoberbelin blue, a reagent that reacts with Mn(III,IV) oxides forming a blue color, was found to also react with Co(III) oxides and was used to verify the presence of oxidized Co in the absence of added Mn(II). Co(II) oxidation occurred optimally around pH 8 and between 55 and 65°C. SG-1 spores oxidized Co(II) at all Co(II) concentrations tested from the trace levels found in seawater to 100 mM. Co(II) oxidation was found to follow Michaelis-Menten kinetics. An Eadie-Hofstee plot of the data suggests that SG-1 spores have two oxidation systems, a high-affinity-low-rate system (K_m, 3.3 × 10^-8 M; V_max, 1.7 × 10^-15 M · spore^-1 · h^-1) and a low-affinity-high-rate system (K_m, 5.2 × 10^-6 M; V_max, 8.9 × 10^-15 M · spore^-1 · h^-1). SG-1 spores did not oxidize Co(II) in the absence of oxygen, also indicating that oxidation was not due to abiological Co(II) oxidation on the surface of preformed Mn(III,IV) oxides. These results suggest that some microorganisms may directly oxidize Co(II) and such biological activities may exert some control on the behavior of Co in nature. SG-1 spores may also have useful applications in metal removal, recovery, and immobilization processes.     

Messenger Ribonucleic Acid of Dormant Spores of Bacillus subtilis

Evidence of the presence of messenger ribonucleic acid (mRNA) in dormant spores of Bacillus subtilis has been obtained. The bulk RNA from spores was isolated and labeled in vitro with tritiated dimethyl sulfate. The spore RNA hybridized to 2.4 to 3.2% of the B. subtilis genome. The RNA hybridized to both the complementary heavy and light fractions of deoxyribonucleic acid (DNA). Bulk RNA from log-phase cells competed with virtually all the spore RNA for the heavy DNA fraction and with part of the spore RNA for the light DNA fraction. Bulk RNA from stage IV cells in sporulation also competed with all of the spore RNA for the heavy DNA fraction and with essentially all the spore RNA for the light DNA fraction. These results indicate that dormant spores contain mRNA species present in both log-phase cells and stage IV cells of sporulation. The RNA polymerase in the developing forespore must be able to recognize promotor sites for both log-phase and sporulation genes.     

Characterization of Ribosomes from Dormant Spores of Bacillus cereus

Characterization of ribosomes from dormant spores and vegetative cells of Bacillus cereus strain T has been carried out. Polyuridylic acid binding activity, ribonuclease activity associated with ribosomes, thermal denaturation profile, and sedimentation coefficients are essentially identical for both ribosomal preparations. However, ribosomal protein content of dormant spore ribosomes is about 70% of that of vegetative ribosomes. Polyacrylamide gel electrophoresis of ribosomal proteins shows that some ribosomal proteins are missing from dormant spore ribosomes. Sucrose density gradient centrifugation of ribosomes shows the existence of defective ribosomal subunits, in addition to 30S and 50S subunits, in dormant spore ribosomes. These results indicate that the ribosomes from dormant spores are distinctively different from those of vegetative cells.     

Direct Identification of a Bacterial Manganese(II) Oxidase, the Multicopper Oxidase MnxG, from Spores of Several Different Marine Bacillus Species

Microorganisms catalyze the formation of naturally occurring Mn oxides, but little is known about the biochemical mechanisms of this important biogeochemical process. We used tandem mass spectrometry to directly analyze the Mn(II)-oxidizing enzyme from marine Bacillus spores, identified as an Mn oxide band with an in-gel activity assay. Nine distinct peptides recovered from the Mn oxide band of two Bacillus species were unique to the multicopper oxidase MnxG, and one peptide was from the small hydrophobic protein MnxF. No other proteins were detected in the Mn oxide band, indicating that MnxG (or a MnxF/G complex) directly catalyzes biogenic Mn oxide formation. The Mn(II) oxidase was partially purified and found to be resistant to many proteases and active even at high concentrations of sodium dodecyl sulfate. Comparative analysis of the genes involved in Mn(II) oxidation from three diverse Bacillus species revealed a complement of conserved Cu-binding regions not present in well-characterized multicopper oxidases. Our results provide the first direct identification of a bacterial enzyme that catalyzes Mn(II) oxidation and suggest that MnxG catalyzes two sequential one-electron oxidations from Mn(II) to Mn(III) and from Mn(III) to Mn(IV), a novel type of reaction for a multicopper oxidase.     

Analysis of Metabolism in Dormant Spores of Bacillus Species by 31P Nuclear Magnetic Resonance Analysis of Low-Molecular-Weight Compounds

This work was undertaken to obtain information on levels of metabolism in dormant spores of Bacillus species incubated for weeks at physiological temperatures. Spores of Bacillus megaterium and Bacillus subtilis strains were harvested shortly after release from sporangia and incubated under various conditions, and dormant spore metabolism was monitored by ³¹P nuclear magnetic resonance (NMR) analysis of molecules including 3-phosphoglyceric acid (3PGA) and ribonucleotides. Incubation for up to 30 days at 4, 37, or 50°C in water, at 37 or 50°C in buffer to raise the spore core pH from ∼ 6.3 to 7.8, or at 4°C in spent sporulation medium caused no significant changes in ribonucleotide or 3PGA levels. Stage I germinated spores of Bacillus megaterium that had slightly increased core water content and a core pH of 7.8 also did not degrade 3PGA and accumulated no ribonucleotides, including ATP, during incubation for 8 days at 37°C in buffered saline. In contrast, spores incubated for up to 30 days at 37 or 50°C in spent sporulation medium degraded significant amounts of 3PGA and accumulated ribonucleotides, indicative of RNA degradation, and these processes were increased in B. megaterium spores with a core pH of ∼7.8. However, no ATP was accumulated in these spores. These data indicate that spores of Bacillus species stored in water or buffer at low or high temperatures exhibited minimal, if any, metabolism of endogenous compounds, even when the spore core pH was 7.8 and core water content was increased somewhat. However, there was some metabolism in spores stored in spent sporulation medium.     

Direct Enzymatic Repair of Deoxyribonucleic Acid Single-Strand Breaks in Dormant Spores

With the alkaline sucrose gradient centrifugation method, it was found that dormant spores of Clostridium botulinum subjected to 300 krads of gamma radiation showed a distinct decrease in deoxyribonucleic acid (DNA) fragment size, indicating induction of single-strand breaks (SSB). A two- to threefold difference in radiation resistance of spores of two strains of C. botulinum, 33A (37% survival dose [D(37)] = 110 krads) and 51B (D(37) = 47 krads), was accompanied by relatively larger DNA fragments (molecular weight 7.9 x 10(7)) obtained during extraction from the radiation-resistant strain 33A and smaller DNA fragments (molecular weight 1.8 x 10(7)) obtained under identical conditions from radiation-sensitive strain 51B. The apparent number of DNA SSB produced by 300 krads in strains 33A and 51B was 0.37 and 3.50, respectively, per 10(8) daltons of DNA. Addition of 0.02 M ethylenediaminetetraacetic acid (EDTA) to spore suspensions during irradiation doubled the apparent number of SSB in strain 33A but had no effect on strain 51B. In vivo, 0.02 M EDTA present during irradiation to 100 to 300 krads decreased survival of spores of 33A by about 30% but had little or no effect on 51B. Survival of 33A was also reduced by about 45% when the spores were irradiated while frozen in dry ice (-75 C) and, after irradiation, immediately exposed to 0.03 M EDTA for 1 h to inhibit repair in the dormant spores. These results suggest that the highly radiation-resistant strain 33A may be able to accomplish repair of SSB during irradiation or after irradiation under nonphysiological conditions, i.e., in the dormant state. This repair can be inhibited by EDTA. Sedimentation patterns show that DNA from spores of both strains 33A and 51B did not show any postirradiation repair during the first 6 h of germination, as opposed to Bacillus subtilis spores, which exhibit repair immediately after germination. These observations suggest the existence of direct repair in physiological dormant spores of strain 33A in the cryptobiotic resting state in the absence of germination. The repair seems to be similar to that of polynucleotide ligase activity shown to be operative in some vegetative cells. Apparently radiation-sensitive strains such as 51B and B. subtilis are generally poor in DNA repair enzyme activity under conditions of spore dormancy, which may account for the approximately threefold difference in radiation sensitivity or DNA fragility of different strains, or both.     

Multigeneration Cross Contamination of Mail with Bacillus Species Spores by Tumbling

In 2001, envelopes loaded with Bacillus anthracis spores were mailed to Senators Daschle and Leahy as well as to the New York Post and NBC News buildings. Additional letters may have been mailed to other news agencies because there was confirmed anthrax infection of employees at these locations. These events heightened the awareness of the lack of understanding of the mechanism(s) by which objects contaminated with a biological agent might spread disease. This understanding is crucial for the estimation of the potential for exposure to ensure the appropriate response in the event of future attacks. In this study, equipment to simulate interactions between envelopes and procedures to analyze the spread of spores from a “payload” envelope (i.e., loaded internally with a powdered spore preparation) onto neighboring envelopes were developed. Another process to determine whether an aerosol could be generated by opening contaminated envelopes was developed. Subsequent generations of contaminated envelopes originating from a single payload envelope showed a consistent two-log decrease in the number of spores transferred from one generation to the next. Opening a tertiary contaminated envelope resulted in an aerosol containing 10³ B. anthracis spores. We developed a procedure for sampling contaminated letters by a nondestructive method aimed at providing information useful for consequence management while preserving the integrity of objects contaminated during the incident and preserving evidence for law enforcement agencies.In September and October of 2001, letters containing Bacillus anthracis spores were distributed through the U.S. Postal Service (USPS), resulting in contamination of the mail processing and distribution center in Hamilton, NJ, as well as affiliated processing centers in Washington, DC, in New York City, NY, and in Wallingford, CT, as well as postal facilities along the path transited by letters mailed to a targeted media company in Florida. Subsequently, 22 individuals, including postal workers, persons who received or handled the contaminated letters, and persons exposed to environments contaminated by the letters, developed cases of anthrax, including both the inhalation and cutaneous forms of the disease (5, 18-20). Five of these cases of anthrax resulted in death (4, 7). There have been investigations into the relationships of infection and exposure in areas where known exposures occurred (1, 6, 8). However, for two of the individuals who developed inhalational anthrax, an elderly woman in Connecticut and a nurse in New York City, no B. anthracis spores were detected (based on environmental sampling) on their mail or in their homes (2, 17, 19, 20). A third individual, a bookkeeper from New Jersey, survived a cutaneous anthrax infection, and only a single positive environmental sample in her workplace was identified (19).For the three specific cases mentioned above, the authors of the corresponding studies hypothesized that infection may have resulted from exposure to mail cross contaminated by mail that went through the same sorting equipment around the time that the letters to Senators Leahy and Daschle were processed. Without evidence of B. anthracis spores in their homes and other areas they were known to have frequented and the lack of additional cases in these geographic areas, there is no way to confirm the route of their exposure. We hypothesize that these people may have been exposed by inhaling spores released from envelopes that they tore open and then discarded. The delay between exposure and disease would have been sufficient to permit the discarded items to enter into the solid waste or recycling stream, and any residual spores may have been removed by normal housekeeping activities. Alternatively, the true source of exposure may have been undetectable due to a low concentration of spores.Those cases of anthrax raise the question of what, if any, hazards may have been encountered in handling mail with secondary and tertiary contamination. These cases raise particular questions concerning the ability of disease-causing organisms to spread through cross contamination of second- and even third-generation fomites in sufficient numbers to cause infection and possible death.Following the attacks, numerous studies were conducted in the contaminated postal buildings to assess the degree of contamination and to better understand sampling methodologies. Subsequent laboratory studies have been performed to improve B. anthracis sample collection and detection (11, 16, 22, 24, 30). Programs have monitored aerosols within federal buildings, hospitals, and mail facilities (10, 15, 25, 27). Additionally, studies of mail sorting machinery and the potential of this machinery to cross contaminate mail have been done (3, 10). However, to date, no laboratory studies that examined the potential for cross contamination of mail through contact or mixing with contaminated letters have been published.Reaerosolization in general is a poorly studied phenomenon. Characterization of reaerosolization under a variety of circumstances was undertaken following the B. anthracis incidents in 2001 (21, 29). The concept of fomite-to-fomite transference of powdered pathogen residues has been even less well studied.The settling of a primary aerosol comprised of charged particles may be due at least in part to an increase in the mass of these charged particles that occurs when they interact with oppositely charged particles. Once deposited on a surface, several factors may act against reaerosolization. Charged particles that have interacted with oppositely charged particles and have effectively increased in mass may be substantially more difficult to entrain in an aerosol than the initial particles. For charged particles that have not interacted with other particles, there may be a direct electrostatic interaction between the charged particle and the surface on which it has landed which would tend to hold these particles onto the surface. Both of these effects should reduce the potential for reaerosolization.Particulate preparations have a variety of properties, such as hydrophobicity, zeta potential, particle shape, and other characteristics that may also affect the potential for reaerosolization. It would be interesting to characterize a large number of powders, to create a database of the characteristics and their potential for aerosol formation and reaerosolization of these powders, and to use this database of information for comparison of unknown powders. Knowing this information may assist in the public health and risk management decision making processes. Unfortunately, there is no comprehensive database for these characteristics, nor is there any well-accepted unifying theory for deriving the likelihood of reaerosolization from the characteristics of powders that are commonly measured. In addition, there may be unknown variables that have an impact on aerosolization or reaerosolization that become known over time with improvements in understanding the theory of aerosolization and technology for measurement of these variables. A further confounding factor would be the inability to collect this information from the actual material used in any incident. In the case of the 2001 attacks (and likely in future incidents), there was (and will likely be) little material available for such study. The material used in the attacks is inherently hazardous and must be handled in highly controlled settings. The material is therefore difficult and expensive to work with (23). Material used in an attack is also generally sequestered as evidentiary material, and information concerning preparation of a biological weapon used in an attack may be considered too sensitive for public release. This sensitivity may include unwillingness to provide access to information on the efficacy of a specific preparation method to malevolent individuals and the requirement to preserve information for use in successful identification and prosecution of the perpetrator of such an attack. However, it may be possible to collect fomites contaminated with trace amounts of the agent in the course of public health investigations. The current study details a method for dealing with these contaminated fomites to yield information useful for public health protection.A confounding factor in these cases may be the necessity to treat as much of the available bulk material as can be collected as evidence. As evidence, even small amounts of this material may not be available for scientific testing. There may also be restrictions on the handling and treatment of fomites contaminated with residual traces of biological threat agents. For instance, the owners of the fomites may value them highly and may not wish to see them destroyed in the hope that the object may be somehow decontaminated and returned or the owner may wish to prevent public disclosure of the nature or contents of a contaminated object, such as a letter. It is therefore incumbent upon researchers to develop methods that are as minimally invasive and destructive as possible to investigate the potential for fomite-to-fomite transmission.We constructed a device designed to expose uncontaminated fomites to envelopes bearing a powdered preparation of spores or to fomites that had been exposed to other fomites contaminated by the initial powder-bearing envelope. Specifically, fomites used in this study were envelopes containing a piece of paper. This device was designed to conduct the exposure in a consistent, reproducible manner and to allow investigation of the interaction and cross contamination that might be encountered between a “payload” letter (a letter that had been loaded internally with a powdered spore preparation) and other pieces of mail. Uncontaminated envelopes were tumbled with a single envelope containing a payload of milled Bacillus atrophaeus subsp. globigii spores. After tumbling three successive generations of envelopes, CFU counts from the outsides of the envelopes were taken. These estimates of spore loads on the outside of these envelopes may be compared to published human 50% lethal dose (LD₅₀) estimates for aerosolized B. anthracis spores (12, 13). An additional series of envelopes was exposed to envelopes that had been contaminated during this first round of exposures, and those envelopes were found to be externally contaminated as well. We also studied opening an envelope that had been exposed to a payload envelope with either a finger or a letter opener to determine if these activities caused an aerosolization or reaerosolization of a sufficient number of spores to pose a risk of disease through inhalation.It is difficult to balance the concerns of making information public during a public health response and providing sufficient information for information risk management decision making while at the same time preserving the evidence for use by law enforcement agencies for eventual prosecution of individuals accused of committing crimes. We identified a nondestructive procedure by which contaminated mail can be analyzed and biological material collected while still preserving evidence for law enforcement agencies, allowing the payload envelope to be used as evidence while still permitting an assessment of its biological contaminant burden.     

Enzymatic manganese(II) oxidation by metabolically dormant spores of diverse Bacillus species

Bacterial spores are renowned for their longevity, ubiquity, and resistance to environmental insults, but virtually nothing is known regarding whether these metabolically dormant structures impact their surrounding chemical environments. In the present study, a number of spore-forming bacteria that produce dormant spores which enzymatically oxidize soluble Mn(II) to insoluble Mn(IV) oxides were isolated from coastal marine sediments. The highly charged and reactive surfaces of biogenic metal oxides dramatically influence the oxidation and sorption of both trace metals and organics in the environment. Prior to this study, the only known Mn(II)-oxidizing sporeformer was the marine Bacillus sp. strain SG-1, an extensively studied bacterium in which Mn(II) oxidation is believed to be catalyzed by a multicopper oxidase, MnxG. Phylogenetic analysis based on 16S rRNA and mnxG sequences obtained from 15 different Mn(II)-oxidizing sporeformers (including SG-1) revealed extensive diversity within the genus Bacillus, with organisms falling into several distinct clusters and lineages. In addition, active Mn(II)-oxidizing proteins of various sizes, as observed in sodium dodecyl sulfate-polyacrylamide electrophoresis gels, were recovered from the outer layers of purified dormant spores of the isolates. These are the first active Mn(II)-oxidizing enzymes identified in spores or gram-positive bacteria. Although extremely resistant to denaturation, the activities of these enzymes were inhibited by azide and o-phenanthroline, consistent with the involvement of multicopper oxidases. Overall, these studies suggest that the commonly held view that bacterial spores are merely inactive structures in the environment should be revised.     

Isolation and Characterization of Superdormant Spores of Bacillus Species

Superdormant spores of Bacillus subtilis and Bacillus megaterium were isolated in 4 to 12% yields following germination with high nutrient levels that activated one or two germinant receptors. These superdormant spores did not germinate with the initial nutrients or those that stimulated other germinant receptors, and the superdormant spores'' defect was not genetic. The superdormant spores did, however, germinate with Ca²⁺-dipicolinic acid or dodecylamine. Although these superdormant spores did not germinate with high levels of nutrients that activated one or two nutrient germinant receptors, they germinated with nutrient mixtures that activated more receptors, and using high levels of nutrient mixtures activating more germinant receptors decreased superdormant spore yields. The use of moderate nutrient levels to isolate superdormant spores increased their yields; the resultant spores germinated poorly with the initial moderate nutrient concentrations, but they germinated well with high nutrient concentrations. These findings suggest that the levels of superdormant spores in populations depend on the germination conditions used, with fewer superdormant spores isolated when better germination conditions are used. These findings further suggest that superdormant spores require an increased signal for triggering spore germination compared to most spores in populations. One factor determining whether a spore is superdormant is its level of germinant receptors, since spore populations with higher levels of germinant receptors yielded lower levels of superdormant spores. A second important factor may be heat activation of spore populations, since yields of superdormant spores from non-heat-activated spore populations were higher than those from optimally activated spores.Spores of various Bacillus species are formed in sporulation and are metabolically dormant and very resistant to environmental stress factors (21, 37). While such spores can remain in this dormant, resistant state for long periods, they can return to life rapidly through the process of germination, during which the spore''s dormancy and extreme resistance are lost (36). Spore germination has long been of intrinsic interest, and continues to attract applied interest, because (i) spores of a number of Bacillus species are major agents of food spoilage and food-borne disease and (ii) spores of Bacillus anthracis are a major bioterrorism agent. Since spores are much easier to kill after they have germinated, it would be advantageous to trigger germination of spores in foods or the environment and then readily inactivate the much less resistant germinated spores. However, this simple strategy has been largely nullified because germination of spore populations is heterogeneous, with some spores, often called superdormant spores, germinating extremely slowly and potentially coming back to life long after treatments are applied to inactivate germinated spores (8, 9, 16). The concern over superdormant spores in populations also affects decisions such as how long individuals exposed to B. anthracis spores should continue to take antibiotics, since spores could remain dormant in an individual for long periods and then germinate and cause disease (3, 11).In many species, spore germination can be increased by a prior activation step, generally a sublethal heat treatment, although the changes taking place during heat activation are not known (16). Spore germination in Bacillus species is normally triggered by nutrients such as glucose, amino acids, or purine ribosides (27, 36). These agents bind to germinant receptors located in the spore''s inner membrane that are specific for particular nutrients. In Bacillus subtilis, the GerA receptor responds to l-alanine or l-valine, while the GerB and GerK receptors act cooperatively to respond to a mixture of l-asparagine (or l-alanine), d-glucose, d-fructose and K⁺ ions (AGFK [or Ala-GFK]) (1, 27, 36). There are even more functional germinant receptors in Bacillus megaterium spores, and these respond to d-glucose, l-proline, l-leucine, l-valine, or even salts, such as KBr (6). Glucose appears to trigger germination of B. megaterium spores through either of two germinant receptors, GerU or GerVB, while l-proline triggers germination through only the GerVB receptor, and KBr germination is greatly decreased by the loss of either GerU or GerVB (6). Nutrient binding to the germinant receptors triggers the release of small molecules from the spore core, most notably the huge depot (∼10% of spore dry weight) of pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]) present in spores predominantly as a 1:1 diluted chelate with Ca²⁺ (Ca-DPA) (35, 36). Ca-DPA release then triggers the activation of one of two redundant cortex lytic enzymes (CLEs) that degrade the spore''s peptidoglycan cortex, and cortex degradation completes spore germination and allows progression into outgrowth and then vegetative growth (27, 33, 36).Spore germination can also be triggered by nonnutrient agents, including Ca-DPA and cationic surfactants (27, 33, 36). With B. subtilis spores, Ca-DPA triggers germination by activating one particular CLE, termed CwlJ, and bypasses the spore''s germinant receptors. Germination by the cationic surfactant dodecylamine also bypasses the germinant receptors, and this agent appears to release small molecules including Ca-DPA from the spore core either by opening a normal channel in the spore''s inner membrane for Ca-DPA and other small molecules or by creating such a channel (31, 38, 39).Almost all work on the specifics of the germination of spores of Bacillus species has focused on the majority of spores in populations, and little detailed attention has been paid to that minority of spores that either fail to germinate or germinate extremely slowly. However, it is these latter spores that are most important in unraveling the cause of superdormancy and perhaps suggesting a means to germinate and thus easily inactivate such superdormant spores. Consequently, we have undertaken the task of isolating superdormant spores from spore populations, using buoyant density centrifugation to separate dormant spores from germinated spores. The properties of these purified superdormant spores were then studied, and this information has suggested some reason(s) for spore superdormancy.     

Levels of Germination Proteins in Bacillus subtilis Dormant,Superdormant, and Germinating Spores

Bacterial endospores exhibit extreme resistance to most conditions that rapidly kill other life forms, remaining viable in this dormant state for centuries or longer. While the majority of Bacillus subtilis dormant spores germinate rapidly in response to nutrient germinants, a small subpopulation termed superdormant spores are resistant to germination, potentially evading antibiotic and/or decontamination strategies. In an effort to better understand the underlying mechanisms of superdormancy, membrane-associated proteins were isolated from populations of B. subtilis dormant, superdormant, and germinated spores, and the relative abundance of 11 germination-related proteins was determined using multiple-reaction-monitoring liquid chromatography-mass spectrometry assays. GerAC, GerKC, and GerD were significantly less abundant in the membrane fractions obtained from superdormant spores than those derived from dormant spores. The amounts of YpeB, GerD, PrkC, GerAC, and GerKC recovered in membrane fractions decreased significantly during germination. Lipoproteins, as a protein class, decreased during spore germination, while YpeB appeared to be specifically degraded. Some protein abundance differences between membrane fractions of dormant and superdormant spores resemble protein changes that take place during germination, suggesting that the superdormant spore isolation procedure may have resulted in early, non-committal germination-associated changes. In addition to low levels of germinant receptor proteins, a deficiency in the GerD lipoprotein may contribute to heterogeneity of spore germination rates. Understanding the reasons for superdormancy may allow for better spore decontamination procedures.     

Oxidation of Manganese and Formation of Mn(3)O(4) (Hausmannite) by Spore Coats of a Marine Bacillus sp

Isolated spore coats of a marine Bacillus species were incubated in 25 mM MnCl(2) at pH 7.5. Manganese precipitates, formed on the coat surfaces, were analyzed by transmission electron microscopy, electron diffraction, and energy-dispersive X-ray spectroscopy. Initially, an amorphous manganese oxide was observed on the coats which recrystallized to hausmannite after prolonged incubation in the MnCl(2) solution. The spore coats catalyze the oxidation of Mn(II) and have no structural influence on the final mineral phase precipitated.     

Bacteriology of Manganese Nodules: II. Manganese Oxidation by Cell-free Extract from a Manganese Nodule Bacterium

A cell-free extract from Arthrobacter 37, isolated from a manganese nodule from the Atlantic Ocean, exhibited enzymatic activity which accelerated manganese accretion to synthetic Mn-Fe oxide as well as to crushed manganese nodule. The reaction required oxygen and was inhibited by HgCl₂ and p-chloromercuribenzoate but not by Atebrine dihydrochloride. The rate of enzymatic action depended on the concentration of cell-free extract used. The enzymatic activity had a temperature optimum around 17.5 C and was destroyed by heating at 100 C. The amount of heat required for inactivation depended on the amount of nucleic acid in the preparation. In the cell-free extract, unlike the whole-cell preparation, peptone could not substitute for NaHCO₃ in the reaction mixture. An enzyme-containing protein fraction and a nucleic acid fraction could be separated from cell extract by gel filtration, when prepared in 3% NaCl but not in seawater. The nucleic acid fraction was not required for enzymatic activity.     

The Structure and Function of the Spore Outer Membrane in Dormant and Germinating Spores of Bacillus megaterium

Attempts to demonstrate the presence of the spore outer membrane in mature, dormant spores of a strain of Bacillus megaterium are described. The outer, integument, layers of this organism were found to contain one-third of the total spore cytochrome content, several enzymes of the electron transport chain (specifically NADH oxidase, dehydrogenase, cytochrome c reductase and NADPH dehydrogenase) and a large number of polypeptides extractable with sodium dodecylsulphate in the presence of dithiothreitol and protease inhibitors. These all suggest the presence of a membraneous element. Electron microscopic evidence is presented on the structure of the dormant integument enzymes. Changes in the integument enzymes and in the gel electrophoresis profile of the extractable integument polypeptides which occur during spore gemination, are described and compared with those that take place in the spore inner membrane. The heat sensitivity of the integument enzymes is compared with that of the inner membrane enzymes and the implications for theories of spore heat resistance discussed.     

Manganese(II)-oxidizing Bacillus spores in Guaymas Basin hydrothermal sediments and plumes

Microbial oxidation and precipitation of manganese at deep-sea hydrothermal vents are important oceanic biogeochemical processes, yet nothing is known about the types of microorganisms or mechanisms involved. Here we report isolation of a number of diverse spore-forming Mn(II)-oxidizing Bacillus species from Guaymas Basin, a deep-sea hydrothermal vent environment in the Gulf of California, where rapid microbially mediated Mn(II) oxidation was previously observed. mnxG multicopper oxidase genes involved in Mn(II) oxidation were amplified from all Mn(II)-oxidizing Bacillus spores isolated, suggesting that a copper-mediated mechanism of Mn(II) oxidation could be important at deep-sea hydrothermal vents. Phylogenetic analysis of 16S rRNA and mnxG genes revealed that while many of the deep-sea Mn(II)-oxidizing Bacillus species are very closely related to previously recognized isolates from coastal sediments, other organisms represent novel strains and clusters. The growth and Mn(II) oxidation properties of these Bacillus species suggest that in hydrothermal sediments they are likely present as spores that are active in oxidizing Mn(II) as it emerges from the seafloor.     

Oxidation of Manganese and Formation of Mn3O4 (Hausmannite) by Spore Coats of a Marine Bacillus sp

Isolated spore coats of a marine Bacillus species were incubated in 25 mM MnCl₂ at pH 7.5. Manganese precipitates, formed on the coat surfaces, were analyzed by transmission electron microscopy, electron diffraction, and energy-dispersive X-ray spectroscopy. Initially, an amorphous manganese oxide was observed on the coats which recrystallized to hausmannite after prolonged incubation in the MnCl₂ solution. The spore coats catalyze the oxidation of Mn(II) and have no structural influence on the final mineral phase precipitated.     

Surface Charge Properties of and Cu(II) Adsorption by Spores of the Marine Bacillus sp. Strain SG-1

Spores of marine Bacillus sp. strain SG-1 are capable of oxidizing Mn(II) and Co(II), which results in the precipitation of Mn(III, IV) and Co(III) oxides and hydroxides on the spore surface. The spores also bind other heavy metals; however, little is known about the mechanism and capacity of this metal binding. In this study the characteristics of the spore surface and Cu(II) adsorption to this surface were investigated. The specific surface area of wet SG-1 spores was 74.7 m² per g of dry weight as measured by the methylene blue adsorption method. This surface area is 11-fold greater than the surface area of dried spores, as determined with an N₂ adsorption surface area analyzer or as calculated from the spore dimensions, suggesting that the spore surface is porous. The surface exchange capacity as measured by the proton exchange method was found to be 30.6 μmol m⁻², which is equal to a surface site density of 18.3 sites nm⁻². The SG-1 spore surface charge characteristics were obtained from acid-base titration data. The surface charge density varied with pH, and the zero point of charge was pH 4.5. The titration curves suggest that the spore surface is dominated by negatively charged sites that are largely carboxylate groups but also phosphate groups. Copper adsorption by SG-1 spores was rapid and complete within minutes. The spores exhibited a high affinity for Cu(II). The amounts of copper adsorbed increased from negligible at pH 3 to maximum levels at pH >6. Their great surface area, site density, and affinity give SG-1 spores a high capability for binding metals on their surfaces, as demonstrated by our experiments with Cu(II).