Kinetics of size changes of individual
            <i>Bacillus thuringiensis</i>
            spores in response to changes in relative humidity

Westphal, A. J.; Price, P. B.; Leighton, Terrance; Wheeler, Katherine E.

doi:10.1073/pnas.232710999

Cited by 153 publications

(140 citation statements)

References 26 publications

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“…Consistent with this view, our data indicate fast water exchange across the coat on the 2 H and 17 O relaxation time scales. Scanning microscope observation of B. thuringiensis spores exposed to variable humidity identified two distinct time scales, 50 and 500 s, for spore swelling, tentatively identified with water influx into the coat ϩ cortex and into the core, respectively (44). These time scales refer to swelling of dried spores and they are much longer than the time scales found here for water exchange within fully hydrated spores.…”

Section: Discussionmentioning

confidence: 58%

The physical state of water in bacterial spores

Sunde

Setlow

Hederstedt

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

150

155

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The bacterial spore, the hardiest known life form, can survive in a metabolically dormant state for many years and can withstand high temperatures, radiation, and toxic chemicals. The molecular basis of spore dormancy and resistance is not understood, but the physical state of water in the different spore compartments is thought to play a key role. To characterize this water in situ, we recorded the water 2 H and 17 O spin relaxation rates in D2O-exchanged Bacillus subtilis spores over a wide frequency range. The data indicate high water mobility throughout the spore, comparable with binary proteinwater systems at similar hydration levels. Even in the dense core, the average water rotational correlation time is only 50 ps. Spore dormancy therefore cannot be explained by glass-like quenching of molecular diffusion but may be linked to dehydration-induced conformational changes in key enzymes. The data demonstrate that most spore proteins are rotationally immobilized, which may contribute to heat resistance by preventing heat-denatured proteins from aggregating irreversibly. We also find that the water permeability of the inner membrane is at least 2 orders of magnitude lower than for model membranes, consistent with the reported high degree of lipid immobilization in this membrane and with its proposed role in spore resistance to chemicals that damage DNA. The quantitative results reported here on water mobility and transport provide important clues about the mechanism of spore dormancy and resistance, with relevance to food preservation, disease prevention, and astrobiology.Bacillus subtilis ͉ hydration ͉ magnetic relaxation dispersion ͉ spore dormancy ͉ spore resistance

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Section: Discussionmentioning

confidence: 58%

The physical state of water in bacterial spores

Sunde

Setlow

Hederstedt

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

150

155

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“…The spore core volume was determined as described above, but substituting 5 M [ 14 C]sorbitol for methylamine. Water has been reported to penetrate the entire spore, whereas sorbitol does not (4)(5)(6)(7). The amount of methylamine in the spore core and the core pH were calculated as described (4, 7).…”

Section: Methodsmentioning

confidence: 99%

“…One factor important in dormant spore resistance to such chemicals appears to be their slow permeation into the spore core or protoplast. A variety of data indicate that it is the spore's inner membrane that is the major permeability barrier restricting the passage of small molecules into the spore core (3)(4)(5)(6)(7), although the lipid composition of the inner membrane exhibits no anomalies that might explain its unusual properties (8)(9)(10)(11)(12). In addition, the dormant spore's inner membrane has the potential to expand significantly, because electron microscopy indicates that the volume this membrane encompasses (the spore core): (i) decreases as much as 2-fold late in sporulation (13); and (ii) increases up to 2-fold in the first minute of spore germination, when the spore's large peptidoglycan cortex is degraded and the germ cell wall expands (13)(14)(15).…”

mentioning

confidence: 99%

Lipids in the inner membrane of dormant spores of Bacillus species are largely immobile

Cowan

Olivastro²,

Koppel³

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

170

185

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Bacterial spores of various Bacillus species are impermeable or exhibit low permeability to many compounds that readily penetrate germinated spores, including methylamine. We now show that a lipid probe in the inner membrane of dormant spores of Bacillus megaterium and Bacillus subtilis is largely immobile, as measured by fluorescence redistribution after photobleaching, but becomes free to diffuse laterally upon spore germination. The lipid immobility in and the slow permeation of methylamine through the inner membrane of dormant spores may be due to a significant (1.3-to 1.6-fold) apparent reduction of the membrane surface area in the dormant spore relative to that in the germinated spore, but is not due to the dormant spore's high levels of dipicolinic acid and divalent cations.D ormant bacterial spores of various Bacillus species are extremely resistant to chemical agents that readily kill germinated spores or growing cells (1, 2). One factor important in dormant spore resistance to such chemicals appears to be their slow permeation into the spore core or protoplast. A variety of data indicate that it is the spore's inner membrane that is the major permeability barrier restricting the passage of small molecules into the spore core (3-7), although the lipid composition of the inner membrane exhibits no anomalies that might explain its unusual properties (8)(9)(10)(11)(12). In addition, the dormant spore's inner membrane has the potential to expand significantly, because electron microscopy indicates that the volume this membrane encompasses (the spore core): (i) decreases as much as 2-fold late in sporulation (13); and (ii) increases up to 2-fold in the first minute of spore germination, when the spore's large peptidoglycan cortex is degraded and the germ cell wall expands (13)(14)(15). This increase in core volume during spore germination takes place without new membrane synthesis, because ATP production is not required, and restores relatively normal permeability to the germinated spore's plasma membrane (4,5,16,17).Whereas dyes that stain growing cells, including fluorescent lipid probes, do not stain dormant spores (B.S. and P.S., unpublished results) as expected (15, 18), lipid probes can be incorporated into the developing spore's membranes during sporulation (19). Given the latter finding, we decided to add fluorescent lipid probes during sporulation to prepare spores with labeled membranes, and then use the technique of fluorescence redistribution after photobleaching (FRAP) to directly analyze the fluidity of the spore's inner membrane, because this technique has been used successfully in analyzing the fluidity and organization of molecules in a number of other systems, including spores of Bacillus species (20-25). MethodsStrains and Spore and Cell Preparation. The iosgenic Bacillus subtilis strains used in this work are derivatives of strain 168 and were: PS832, a prototrophic derivative of strain 168; PS3207, cwlD::cam, in which the cwlD gene responsible for production of muramic acid-␦-lactam in ...

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“…For instance, a socalled honeycomb crystalline layer with a period of about 9 nm and ∼ 5−6 nm holes or pits seems to be present in the coat of many Bacillus species [231,232]. Finally, it became only recently understood that the endospore morphology changes drastically due to an increase or decrease of relative humidity of its environment [68,325].…”

mentioning

confidence: 99%

“…In particular, it was shown by Westphal et al [325] that endospores undergo swelling when exposed to an increase in relative humidity. They could identify two di erent swelling time scales (t 1 < 50 s and t 2 ≈ 8 min), that may be related to di usion times of water into coat & cortex and core, respectively.…”

mentioning

confidence: 99%

Coherent X-ray diffractive imaging on the single-cell-level of microbial samples

Wilke

2015

Göttingen Series in X-Ray Physics

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Kinetics of size changes of individual Bacillus thuringiensis spores in response to changes in relative humidity

Cited by 153 publications

References 26 publications

The physical state of water in bacterial spores

The physical state of water in bacterial spores

Lipids in the inner membrane of dormant spores of Bacillus species are largely immobile

Coherent X-ray diffractive imaging on the single-cell-level of microbial samples

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