Electron paramagnetic resonance of manganese(II) and copper(II) in spores

ULTRASTRUCTURAL LOCALIZATION OF MINERAL MATTER IN BACTERIAL SPORES BY MICRONINCINERATION

The fine localization of mineral matter in spores of Bacillus megaterium and Bacillus cereus was studied by the technique of microincineration adapted for use with the electron microscope. The specimens, which included intact and thin-sectioned spores as well as shed spore coats, were burned either in the conventional way at high temperature or by a new technique using electrically excited oxygen at nearly room temperature. The ash residues were examined by bright field, dark field, and diffraction in the electron microscope and also with the phase contrast microscope. In some cases, the specimen was previewed in both microscopes before incineration. The results do not support a previous report that the mineral elements of the spore are confined to a peripheral layer, but rather indicate that the spore core as well as the coat are mineral-rich. The cortex may be deficient in minerals, but the possibility of artifact prevents a clear decision on this point. Incinerated B. megaterium spores show a highly ordered fine structure displaying 100 A periodicity in the ash of the middle layer of the coat. The nature of this structure is discussed, as is the technique which demonstrated it. The fine definition of the ash patterns, particularly those obtained with the low-temperature, excited-oxygen technique, suggests that microincineration may be generally useful in the study of fine structure.

ULTRAVIOLET-ABSORPTION SPECTRA OF DRY BACTERIAL SPORES

Bailey, Glen F. (Western Regional Research Laboratory, Albany, Calif.), Saima Karp, and L. E. Sacks. Ultraviolet-absorption spectra of dry bacterial spores. J. Bacteriol. 89:984-987. 1965.-The possibility of obtaining reasonably satisfactory ultraviolet-absorption spectra of dry spores embedded in KBr has been demonstrated. Such spectra show the three peaks characteristic of calcium dipicolinate. The dipicolinate spectra are more distinct when reference pellets containing appropriate amounts of the analogous spore coats are employed. These spectra are considered evidence that some type of calcium-dipicolinic acid chelate accounts for at least part of the calcium and dipicolinic acid content of the spore.

FREE RADICAL FORMATION AND SURVIVAL OF LYOPHILIZED MICROORGANISMS

Heckly, Robert J. (University of California, Berkeley), R. L. Dimmick, and J. J. Windle. Free radical formation and survival of lyophilized microorganisms. J. Bacteriol. 85:961-966. 1963.-A correlation between death and spontaneous free radical production, measured by an increase in the relative electron paramagnetic resonance (EPR) signal, was shown to exist for several species of microorganisms stored in the freezedried state, but the relationship between the free radical concentration and number of dead cells was not a simple proportion. Lactose added to Sarcina lutea reduced radical production and increased stability when dry preparations were stored in air. Death and free radical formation were more extensive when lyophilized Streptococcus lactis cultures were stored in air than in vacuum. Free radicals were also produced by dry yeast. Few, if any, free radicals were produced by bacteria or yeast stored in vacuum. It was shown that the observed free radical production was not caused by exposure to light. The EPR signal produced by dry Serratia marcescens decreased rapidly when cells were exposed to a humid atmosphere but the EPR signal slowly increased after cells were redried and exposed to oxygen.

TRACE METAL REQUIREMENTS FOR SPORULATION OF BACILLUS MEGATERIUM

Kolodziej, Bruno J. (Northwestern University, Evanston, Ill.), and Ralph A. Slepecky. Trace metal requirements for sporulation of Bacillus megaterium. J. Bacteriol. 88:821-830. 1964.-A sucrose-mineral salts medium was purified for the purpose of definitively re-examining the trace metal cations associated with the sporulation of Bacillus megaterium. Two heretofore unknown requirements for copper (0.013 mug/ml of cupric ion) and molybdenum (27.2 mug/ml of molybdate ion) were uncovered. In the purified copper-supplemented medium, sporulation levels of other metals were determined as follows: iron, 0.5 mug/ml of ferrous ion; zinc, 1.1 mug/ml of zinc ion; manganese, 0.037 mug/ml of manganous ion; and calcium, 0.9 mug/ml of calcium ion. The approximate time during which the various metals were required was determined with iron, zinc, calcium, and manganese. A molybdenum substitution for copper, iron, or zinc was noted. The copper requirement was shown for the sporulation of B. cereus var. mycoides and var. albolactis, suggesting that this may be a general requirement for sporulation. The specific functions of metal ions in sporulation are not known, but they probably act as activators of the various enzyme systems necessary for sporulation.

High-resolution solid-state 13C nuclear magnetic resonance of bacterial spores: identification of the alpha-carbon signal of dipicolinic acid

Natural-abundance solid-state 13C nuclear magnetic resonance spectra were obtained for bacterial spores for the first time by using the technique of cross-polarization magic-angle-spinning nuclear magnetic resonance spectroscopy. A resonance at about 150 ppm, detectable in spore samples having a Mn content of less than 0.05%, was consistent with an identification as the alpha-carbon signal of calcium dipicolinate; this signal was missing from a spore sample treated with acid to release dipicolinate and from a spore coat preparation. Carbohydrate peaks were particularly intense in spores and coat preparations of Bacillus macerans. Signals ascribable to beta-hydroxybutyrate were prominent in a B. cereus sample.

Manganese: its acquisition by and function in the lactic acid bacteria

The transition metal manganese is considered to be a minor micronutrient in both pro- and eukaryotes, usually being required from the environment at subnanomolar levels. Until recently, Mn was only known to function in cells as a cofactor for a few enzymatic reactions. A notable exception has been reported in many lactic acid bacterial species which require micromolar medium Mn levels for growth and contain up to 35 mM Mn. These high Mn concentrations are accompanied by the near or complete absence of intracellular iron and superoxide dismutase (SOD). Lacking hemes, Lactobacillus plantarum and related species contain a unique Mn-cofactored catalase as well as millimolar Mn(II) in a nonenzymic complex performing the function of the micromolar superoxide dismutase found in most other aerotolerant cells. The high Mn(II) levels are accumulated via an efficient active transport system and are stored intracellularly in a high molecular weight complex. Study of Lactobacillus plantarum has provided an interesting example of the substitution of Mn for Fe in several of the biological roles of Fe, an alternative mechanism of aerotolerance, and a better understanding of the unique biochemistry of the lactic acid bacteria.

An investigation of membrane fluidity changes during sporulation and germination of Bacillus megaterium K.M. measured by electron spin and nuclear magnetic resonance spectroscopy

Changes in membrane and macromolecular fluidity which may accompany the differentiation processes of sporulation and germination in Bacillus megaterium K.M. are examined by electron spin and nuclear magnetic resonance spectroscopy. No change in membrane lipid fluidity is observed in isolated forespores up to stage VI. Between stage VI and release of mature spores, the ESR spectrum of doxylstearic acid spin labels becomes polycrystalline. This change in spectral fluidity is completely reversed during germination and is paralleled by the rapid release of Ca2+ from the spore. NMR studies also show that the mature spore has reduced macromolecular mobility and an increased nonexchangeable water pool compared with vegetative cells.

Location of elements in ashed spores of Bacillus megaterium

The structure of the skeleton of spores of Bacillus megaterium was examined after ashing in a plasma asher and the elemental composition of the ashed whole spores was determined with an analytical electron microscope. All spores were ashed in situ although they shrank by about 15%. Even P and S, in addition to metals, were recovered well from ashed samples. Ash was rich in the core and the coat, and poor in the cortex. Ca, P, S, and Mg were detected in the core and coat of the spore of B. megaterium QM B1551. Ca in the core was markedly decreased by germination or autoclaving. In the spore of B. megaterium ATCC 19213, almost all of the ash was detected in the core and its elemental composition was similar to that of the core of the strain QM B1551 spore. These reuslts suggest strongly that the core is the site of Ca associated with dipicolinic acid.

Regulation of phosphoglycerate phosphomutase in developing forespores and dormant and germinated spores of Bacillus megaterium by the level of free manganous ions

The large depot of phosphoglyceric acid (PGA) which is accumulated within spores of Bacillus megaterium is greater than 99% 3-phosphoglyceric acid (3-PGA). The 3-PGA depot is stable in forespores and dormant spores, but is utilized rapidly during spore germination. When spores were germinated in KBr plus NaF, the PGA depot was not utilized, but 13% of the 3-PGA was converted to 2-PGA. These data suggest phosphoglycerate phosphomutase as the enzyme which is regulated to allow 3-PGA accumulation during sporulation. Young isolated forespores, in which 3-PGA was normally stable, utilized their 3-PGA rapidly when incubated with Mn2+ plus the divalent cation ionophore X-537A; Mn2+ or ionophore alone or Mg2+ or Ca2+ plus ionophore was without effect. Young forespores contained significant amounts of Mn2+. However, forespore Mn2+ exchanged slowly with exogenous Mn2+ and was removed poorly by toluene treatment. This suggests that much of the forespore Mn2+ is tightly bound to some forespore component. Since phosphoglycerate phosphomutase from B. megaterium has an absolute and specific requirement for Mn2+, these data suggest that the activity of this enzyme in vivo may be regulated to a large degree by the level of free Mn2+. Indeed, the activity of this enzyme in forespore or dormant spore extracts was stimulated greater than 25-fold by Mn2+, whereas comparable extracts from cells or germinated spores were stimulated only two- to fourfold.

Regulation of manganese accumulation and exchange in Bacillus subtilis W23

An overnight culture of Bacillus subtilis W23 in low-manganese tryptone broth is unable to sporulate and becomes hyperactive with regard to the manganese active transport system during stationary phase. When manganese is added to cells in spent or fresh medium, the cells immediately accumulate a high proportion of the manganese available in the medium. When the hyperactive cells are diluted into broth containing 10 muM Mn(2+), high intracellular manganese levels are reached, and inhibition of ribonucleic acid and protein synthesis occurs. This inhibition is relieved when the intracellular manganese concentration declines to the nontoxic levels characteristic of cells growing in 10 muM Mn(2+). The release of the accumulated manganese is achieved by a reduction in the uptake rate for manganese while the efflux rate remains essentially constant. Inhibitors of ribonucleic acid and protein synthesis prevent the reduction of the high rate of manganese uptake and, therefore, high net concentrations of manganese are maintained in the presence of these inhibitors. The hyperactive manganese uptake system is temperature dependent and inhibited by cyanide and m-chlorophenyl carbonylcyanide hydrazone.

Effect of carbon source on size and associated properties of Bacillus megaterium spores

The size of the spores produced by Bacillus megaterium ATCC 19213 depended upon the nature of the carbon source present in the defined medium in which they were produced. Homogeneous preparations of small (0.38 mum(3)), nearly spherical spores were produced after batch culture in the presence of 2.8 mm citrate, and large (1.17 mum(3)), oblong spores were produced by replacement culture in the presence of 7.35 mm acetate. Large and small spores had approximately the same deoxyribonucleic acid content, density, and heat resistance. Large spores contained about 2.5 times the dipicolinic acid, glucosamine, ribonucleic acid, Mn(2+), and lipid and about 1.5 times the Mg(2+), Fe(2+), Ca(2+), and dry weight of small spores. Large spores were especially enriched in Zn(2+) (4.5-fold). More protein (1.5-fold) was extracted from small spores with 1 n NaOH than from large spores, possibly indicating a difference in the spore coats, but large spores contained about twice the Kjeldahl nitrogen of small spores. A difference in the coats may account for the fact that, unlike small spores, large spores showed improved germination with increased times and temperature of heat shocking. The possibility of determining the location of some of these substances within the spore by comparing the compositional ratios with estimated volumes of specific spore layers is discussed.

Coordinative binding of divalent cations with ligands related to bacterial spores. Equilibrium studies

It has been repeatedly postulated that the high heat resistance of bacterial spores is due to stabilization of biopolymers in the spore interior by a solid deposit of protective cement consisting of coordination complexes of ligands with divalent metal ions. This report presents data on metal-binding characteristics of some of the ligands related to spores as determined by means of potentiometric equilibrium measurements under conditions of temperature and ionic strength (t = 25.0 degrees C; mu = 1.0 KNO(3)) identical with those reported earlier by the authors in order to facilitate correlation by using comparable data. The spore ligands investigated in this study included 2,6-pyridinedicarboxylic acid (DPA), alpha,epsilon-diaminopimelic acid, D-glutamic acid, and D-alanine in a ratio of 1:1 with metal ions which are known to play a role in heat resistance of spores. Stability constants of the chelates of these spore ligands with metal ions such as Ca(II), Mg(II), Cu(II), Ni(II), Zn(II), Co(II), and Mn(II) have been determined. In general the metal chelates of DPA exhibited the greatest stability. On the basis of a consideration of the stability data together with the known configurations of the ligand and the coordination requirements of the metal ions, possible structures indicating the coordinate binding of the spore ligands with the metal ions are presented. All the metal chelates except those of Ca(II) were found to undergo hydrolysis and separation of solid phase in the pH range 7-8.5. The relatively greater hydrolytic stability of Ca(II) chelates and the high affinity of DPA for metal ions appear to be of biological significance insofar as these two spore components are more widely associated with the heat resistance of bacterial spores.

RESPONSES OF BACILLUS SUBTILIS SPORES TO IONIC ENVIRONMENTS DURING SPORULATION AND GERMINATION

Fleming , H. P. (University of Illinois, Urbana), and Z. John Ordal . Responses of Bacillus subtilis spores to ionic environments during sporulation and germination. J. Bacteriol. 88: 1529–1537. 1964.—The ionic environments of germination and sporulation menstrua had a prominent influence on characteristics of Bacillus subtilis spores. There was a synergistic effect for l -alanine and inorganic ions on spore germination. The maximal rate of germination in solutions of l -alanine was dependent on ionic concentration and species. Germination was negligible in l -alanine at low ionic strength but increased as the ionic strength was increased up to about 10 −1 m with a variety of salts. Phosphate was the most active ion tested, and divalent cations were the least active in supporting germination in l -alanine. Germination progressed slowly at 45 C in sodium chloride or sodium phosphate alone but not in CaCl 2 alone. Germination rates in l -alanine were retarded at high ionic strengths (μ in the range of 0.1 to 1.0). Inhibitory effects of high concentrations of certain divalent cations on germination were related to the binding abilities of these metals. High concentrations of NaCl (10 −1 to 1.0 m ) in the sporulation medium resulted in lowered heat resistance and germination rate of the resulting spores. The addition of calcium (5 × 10 −2 m CaCl 2 ) to the sporulation medium relieved the repression of NaCl on germination and caused the spores to have a greater heat resistance. Calcium and dipicolinic acid (DPA) contents of the spores were unaffected by NaCl in the sporulation medium. The calcium, but not the DPA, content of spores increased as a result of supplementing the sporulation medium with calcium. Possible roles of ions in the germination of spores are discussed.