Architecture and High-Resolution Structure of Bacillus thuringiensis and Bacillus cereus Spore Coat Surfaces

We have utilized atomic force microscopy (AFM) to visualize the native surface topography and ultrastructure of Bacillus thuringiensis and Bacillus cereus spores in water and in air. AFM was able to resolve the nanostructure of the exosporium and three distinctive classes of appendages. Removal of t...

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Veröffentlicht in:	Langmuir 2005-08, Vol.21 (17), p.7892-7898
Hauptverfasser:	PLOMP, Marco, LEIGHTON, Terrance J., WHEELER, Katherine E., MALKIN, Alexander J.
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Sprache:	eng
Schlagworte:	Air Bacillus cereus - chemistry Bacillus cereus - ultrastructure Bacillus thuringiensis - chemistry Bacillus thuringiensis - ultrastructure Chemistry Exact sciences and technology General and physical chemistry Microscopy, Atomic Force - methods Sensitivity and Specificity Spores, Bacterial - chemistry Spores, Bacterial - ultrastructure Water - chemistry
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creator	PLOMP, Marco LEIGHTON, Terrance J. WHEELER, Katherine E. MALKIN, Alexander J.
description	We have utilized atomic force microscopy (AFM) to visualize the native surface topography and ultrastructure of Bacillus thuringiensis and Bacillus cereus spores in water and in air. AFM was able to resolve the nanostructure of the exosporium and three distinctive classes of appendages. Removal of the exosporium exposed either a hexagonal honeycomb layer (B. thuringiensis) or a rodlet outer spore coat layer (B. cereus). Removal of the rodlet structure from B. cereus spores revealed an underlying honeycomb layer similar to that observed with B. thuringiensis spores. The periodicity of the rodlet structure on the outer spore coat of B. cereus was approximately 8 nm, and the length of the rodlets was limited to the cross-patched domain structure of this layer to approximately 200 nm. The lattice constant of the honeycomb structures was approximately 9 nm for both B. cereus and B. thuringiensis spores. Both honeycomb structures were composed of multiple, disoriented domains with distinct boundaries. Our results demonstrate that variations in storage and preparation procedures result in architectural changes in individual spore surfaces, which establish AFM as a useful tool for evaluation of preparation and processing "fingerprints" of bacterial spores. These results establish that high-resolution AFM has the capacity to reveal species-specific assembly and nanometer scale structure of spore surfaces. These species-specific spore surface structural variations are correlated with sequence divergences in a spore core structural protein SspE.
doi_str_mv	10.1021/la050412r
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AFM was able to resolve the nanostructure of the exosporium and three distinctive classes of appendages. Removal of the exosporium exposed either a hexagonal honeycomb layer (B. thuringiensis) or a rodlet outer spore coat layer (B. cereus). Removal of the rodlet structure from B. cereus spores revealed an underlying honeycomb layer similar to that observed with B. thuringiensis spores. The periodicity of the rodlet structure on the outer spore coat of B. cereus was approximately 8 nm, and the length of the rodlets was limited to the cross-patched domain structure of this layer to approximately 200 nm. The lattice constant of the honeycomb structures was approximately 9 nm for both B. cereus and B. thuringiensis spores. Both honeycomb structures were composed of multiple, disoriented domains with distinct boundaries. Our results demonstrate that variations in storage and preparation procedures result in architectural changes in individual spore surfaces, which establish AFM as a useful tool for evaluation of preparation and processing "fingerprints" of bacterial spores. These results establish that high-resolution AFM has the capacity to reveal species-specific assembly and nanometer scale structure of spore surfaces. 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Our results demonstrate that variations in storage and preparation procedures result in architectural changes in individual spore surfaces, which establish AFM as a useful tool for evaluation of preparation and processing "fingerprints" of bacterial spores. These results establish that high-resolution AFM has the capacity to reveal species-specific assembly and nanometer scale structure of spore surfaces. 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Our results demonstrate that variations in storage and preparation procedures result in architectural changes in individual spore surfaces, which establish AFM as a useful tool for evaluation of preparation and processing "fingerprints" of bacterial spores. These results establish that high-resolution AFM has the capacity to reveal species-specific assembly and nanometer scale structure of spore surfaces. These species-specific spore surface structural variations are correlated with sequence divergences in a spore core structural protein SspE.</abstract><cop>Washington, DC</cop><pub>American Chemical Society</pub><pmid>16089397</pmid><doi>10.1021/la050412r</doi><tpages>7</tpages><oa>free_for_read</oa></addata></record>
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subjects	Air Bacillus cereus - chemistry Bacillus cereus - ultrastructure Bacillus thuringiensis - chemistry Bacillus thuringiensis - ultrastructure Chemistry Exact sciences and technology General and physical chemistry Microscopy, Atomic Force - methods Sensitivity and Specificity Spores, Bacterial - chemistry Spores, Bacterial - ultrastructure Water - chemistry
title	Architecture and High-Resolution Structure of Bacillus thuringiensis and Bacillus cereus Spore Coat Surfaces
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