TY - JOUR
T1 - Proteins accessible to immune surveillance show significant T-cell epitope depletion
T2 - implications for vaccine design
AU - Halling-Brown, Mark
AU - Shaban, Raheel
AU - Frampton, Dan
AU - Sansom, Clare E.
AU - Davies, Matthew
AU - Flower, Darren
AU - Duffield, Melanie
AU - Titball, Richard W.
AU - Brusic, Vladimir
AU - Moss, David S.
PY - 2009/8
Y1 - 2009/8
N2 - T cell activation is the final step in a complex pathway through which pathogen-derived peptide fragments can elicit an immune response. For it to occur, peptides must form stable complexes with Major Histocompatibility Complex (MHC) molecules and be presented on the cell surface. Computational predictors of MHC binding are often used within in silico vaccine design pathways. We have previously shown that, paradoxically, most bacterial proteins known experimentally to elicit an immune response in disease models are depleted in peptides predicted to bind to human MHC alleles. The results presented here, derived using software proven through benchmarking to be the most accurate currently available, show that vaccine antigens contain fewer predicted MHC-binding peptides than control bacterial proteins from almost all subcellular locations with the exception of cell wall and some cytoplasmic proteins. This effect is too large to be explained from the undoubted lack of precision of the software or from the amino acid composition of the antigens. Instead, we propose that pathogens have evolved under the influence of the host immune system so that surface proteins are depleted in potential MHC-binding peptides, and suggest that identification of a protein likely to contain a single immuno-dominant epitope is likely to be a productive strategy for vaccine design.
AB - T cell activation is the final step in a complex pathway through which pathogen-derived peptide fragments can elicit an immune response. For it to occur, peptides must form stable complexes with Major Histocompatibility Complex (MHC) molecules and be presented on the cell surface. Computational predictors of MHC binding are often used within in silico vaccine design pathways. We have previously shown that, paradoxically, most bacterial proteins known experimentally to elicit an immune response in disease models are depleted in peptides predicted to bind to human MHC alleles. The results presented here, derived using software proven through benchmarking to be the most accurate currently available, show that vaccine antigens contain fewer predicted MHC-binding peptides than control bacterial proteins from almost all subcellular locations with the exception of cell wall and some cytoplasmic proteins. This effect is too large to be explained from the undoubted lack of precision of the software or from the amino acid composition of the antigens. Instead, we propose that pathogens have evolved under the influence of the host immune system so that surface proteins are depleted in potential MHC-binding peptides, and suggest that identification of a protein likely to contain a single immuno-dominant epitope is likely to be a productive strategy for vaccine design.
KW - MHC binding
KW - T-cell response
KW - subcellular location
KW - immune escape
KW - in silico vaccine design
UR - http://www.scopus.com/inward/record.url?scp=67650494289&partnerID=8YFLogxK
U2 - 10.1016/j.molimm.2009.05.027
DO - 10.1016/j.molimm.2009.05.027
M3 - Article
C2 - 19560824
SN - 1872-9142
VL - 46
SP - 2699
EP - 2705
JO - Molecular Immunology
JF - Molecular Immunology
IS - 13
ER -