Stoichiometry,
Absolute Abundance, and Localization
of Proteins in the Bacillus cereus Spore Coat Insoluble
Fraction Determined Using a QconCAT Approach
posted on 2017-12-20, 00:00authored bySacha K. Stelder, Celia Benito de Moya, Huub C. J. Hoefsloot, Leo J. de Koning, Stanley Brul, Chris G. de Koster
Spores
of Bacillus cereus pose a threat to food
safety due to their high resistance to the heat or acid treatments
commonly used to make food microbiologically safe. Spores may survive
these treatments and later resume growth either on foodstuffs or,
after ingestion, upon entering the gut they are capable of producing
toxins, which cause either vomiting or diarrhea. The outer layers
of the spore, the spore coat and exosporium, consist primarily of
proteins that may serve as potential biomarkers for detection. The
major morphogenetic protein CotE is important for correct assembly
and attachment of the outermost layer, the exosporium, and by extension
retention of many proteins. However, characterization of the proteins
affected by deletion of CotE has been limited to electrophoretic patterns.
Here we report the effect of CotE deletion on the insoluble fraction
of the spore proteome through liquid chromatography–Fourier
transform tandem mass spectrometry (LC–FTMS/MS) analysis. A total of 560 proteins have been identified in both mutant
and wild-type spore coat isolates. A further 163 proteins were identified
exclusively in wild-type spore isolates indicating that they are dependent
on CotE for their association with the spore. Several of these are
newly confirmed as associated with the exosporium, namely BC_2569
(BclF), BC_3345, BC_2427, BC_2878, BC_0666, BC_2984, BC_3481, and
BC_2570. A total of 153 proteins were only identified in ΔCotE
spore isolates. This was observed for proteins that are known or likely
to be interacting with or are encased by CotE. Crucial spore proteins
were quantified using a QconCAT reference standard, the first time
this was used in a biochemically heterogeneous system. This allowed
us to determine the absolute abundance of 21 proteins, which spanned
across three orders of magnitude and together covered 5.66% ±
0.51 of the total spore weight. Applying the QconCAT methodology to
the ΔCotE mutant allowed us to quantify 4.13% ± 0.14 of
the spore total weight and revealed a reduction in abundance for most
known exosporium associated proteins upon CotE deletion. In contrast,
several proteins, either known or likely to be interacting with or
encased by CotE (i.e., GerQ), were more abundant. The results obtained
provide deeper insight into the layered spore structure such as which
proteins are exposed on the outside of the spore. This information
is important for developing detection methods for targeting spores
in a food safety setting. Furthermore, protein stoichiometry and determination
of the abundance of germination mediating enzymes provides useful
information for germination and outgrowth model development.