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Plant Cell, Vol. 10, 1723-1732, October 1998, Copyright © 1998, American Society of Plant Physiologists
Identification of Residues in a Hydrophilic Loop of the Papaver rhoeas S Protein That Play a Crucial Role in Recognition of Incompatible Pollen
Katsuyuki Kakedaa,
Nicholas D. Jordana,
Alex Connera,
Jon P. Ridea,
Vernonica E. Franklin-Tonga, and
F. Christopher H. Franklina
a Wolfson Laboratory for Plant Molecular Biology, School of Biological Sciences, University of Birmingham, Edgbaston, Birmingham B15 2T T, United Kingdom
Correspondence to:
F. Christopher H. Franklin, F.C.H.Franklin{at}bham.ac.uk (E-mail), 44-121-414-5925 (fax).
The self-incompatibility response involves S allele–specific recognition between stigmatic S proteins and incompatible pollen. This response results in pollen inhibition. Defining the amino acid residues within the stigmatic S proteins that participate in S allele–specific inhibition of incompatible pollen is essential for the elucidation of the molecular basis of the self-incompatibility response. We have constructed mutant derivatives of the S1 protein from Papaver rhoeas by using site-directed mutagenesis and have tested their biological activity. This has enabled us to identify amino acid residues in the stigmatic S proteins of P. rhoeas that are required for S-specific inhibition of incompatible pollen. We report here the identification of several amino acid residues in the predicted hydrophilic loop 6 of the P. rhoeas stigmatic S1 protein that are involved in the inhibition of S1 pollen. Mutation of the only hypervariable amino acid, which is situated in this loop, resulted in the complete loss of ability of the S protein to inhibit S1 pollen. This clearly demonstrates that this residue plays a crucial role in pollen recognition and may also participate in defining allelic specificity. We have also established the importance of highly conserved amino acids adjacent to this hypervariable site. Our studies demonstrate that both variable and conserved amino acids in the region of the S protein corresponding to surface loop 6 are key elements that play a role in the recognition and inhibition of incompatible pollen in the pollen–pistil self-incompatibility reaction.
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