1 / 24

“In the course of a proteomic analysis designed to discover

“In the course of a proteomic analysis designed to discover spore coat proteins, we identified several previously described exosporium proteins.”. Rationale. Anthrax: infection by B. anthracis spores Understanding of disease Prevention of or response to deliberate release as a bioweapon.

imelda
Télécharger la présentation

“In the course of a proteomic analysis designed to discover

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. “In the course of a proteomic analysis designed to discover spore coat proteins, we identified several previously described exosporium proteins.”

  2. Rationale • Anthrax: infection by B. anthracis spores • Understanding of disease • Prevention of or response to deliberate release as a bioweapon

  3. Exosporium background • Present in some Bacillus species • Significant variation in structure • Means of attachment to spore unknown • Functions little understood • Attachment to host cells • Resistance to oxidative burst • Reduces innate immune response • Mediates phagocytosis • Regulates stickiness • Affects germination • May contain enzymes

  4. Exosporium proteins • 20 proteins and glycoproteins • Lipids, carbohydrates • Orthologs of B. subtilis coat proteins • CotE (attachment?) • CotO (assembly?) • CotY, ExsY • Unique B. anthracis proteins • BclA – major protein component • ExsFA – basal layer, BclA assembly and projections = BxpB • ExsFB – paralog of ExsFA • BclB – stability • ExsFA-BclA-ExsY complex

  5. Hypothesis • No overall hypothesis • Objective: characterize the role of ExsFA in exosporium

  6. Mutant construction • B. anthracis “Ames strain,” virulent • exsFA mutant is RG124 • B. anthracis “Sterne strain,” attenuated • exsFA mutant is Ames-JAB-5 TcR pMR6 exsFA 5′ flanking sequence exsFA 3′ flanking sequence KmR chromosome chromosome exsFA KmR

  7. Results: Electron microscopy • Growth and sporulation unaffected • TEM: “nap” missing from spores of both strains • Same finding as Steichen et al. • Sylvestre et al. reported fewer projections Steichen et al. Sylvestre et al. DexsFA wt

  8. Results: Atomic force microscopy (AFM) • Mechanical imaging of untreated spores DexsFA wt

  9. Results: Atomic force microscopy (AFM) – Fig. 1 • Loss of ridges on mutant spore coat wt Sterne mutant

  10. Results: Immunofluorescence microscopy (IFM) – Fig. 2 • BclA normally located around forespore by 7h 1 cell bright field + Hoechst dye: binds DNA, blue fluorescence forespore mother cell chromosome mouse anti-BclA mAb fluorescent goat anti-mouse Ab

  11. Results: Immunofluorescence microscopy (IFM) – Fig. 2 free spores

  12. Results: Immunofluorescence microscopy (IFM) – Fig. 2 • Some BclA in mother cell at 7h • BclA around forespore at 8h and in free spores but polar • Associated with “cap” portion of exosporium? free spores 7h 8h

  13. Results: Germination – Fig. 3 • Syto-9 dye taken up by germinating spore during rehydration (early) • Increased green fluorescence = germination • Mutant shows reduced germination, especially in Ames strain

  14. Results: Germination – Fig. 3 • Reduced germination by loss of OD in Sterne strain with RPMI-BHI medium

  15. Results: Germination – Fig. 3 • Late events monitored by tetrazolium overlay • No defect in mutants sporulate colonies on plate, heat to 80 °C overlay agar with TTC

  16. Results: Virulence – Fig. 4 • Infected guinea pigs by i.m. and inhalation routes • No difference in virulence between wild-type and mutant intramuscular inhalation

  17. gfp Fusion construction PCR from chromosome PCR from pKL147 exsFA 3′ end gfp pRG25 chromosome exsFA chromosome exsFA gfp

  18. Results: Localization of ExsFA and ExsFB – Fig. 5 WT exsFA-gfp fusion DNA stain vegetative DNA stain 3 hrs DNA stain 6 hrs GFP DNA stain spores GFP

  19. Results: Localization of ExsFA and ExsFB – Fig. 5 exsFA-gfp fusion exsFA-gfp fusion iunH-gfp fusion 6 hrs GFP spores GFP more spores

  20. Results: Localization of ExsFA and ExsFB – Fig. 5 • IFM with anti-GFP antibody

  21. Results: Localization of ExsFA and ExsFB – Fig. 5 • IFM with anti-GFP antibody in cotE and bclA mutants

  22. What is the importance of this paper? • ExsFA (perhaps C terminus) required for exosporium “nap” • ExsFA plays a role in germination (contrary to others’ results) • ExsFA is not involved in virulence • ExsFA appears to be localized to the basal layer of the exosporium • ExsFB and IunH appear to be localized to the interspace

  23. What is the importance of this paper? • Nap is dispensable for virulence: targeting the exosporium is a bad idea • Interesting but challenging to identify function of nap • Unusual paralogs (3rd in B. cereus) – adaptive role? • First step toward separating interspace and exosporium proteins/assembly

More Related