Engineering of the protein environment around the redox-active TyrZ in photosystem II - the role of F186 and P162 in the D1 protein of Synechocystis 6803
R. Wiklund et al., Engineering of the protein environment around the redox-active TyrZ in photosystem II - the role of F186 and P162 in the D1 protein of Synechocystis 6803, EUR J BIOCH, 268(20), 2001, pp. 5356-5364
The photosystem II reaction centre protein D1 is encoded by the psbA gene.
By activation of the silent and divergent psbA1 gene in the cyanobacterium
Synechocystis 6803, a novel D1 protein, D1', was produced [Salih, G. & Jans
son, C. (1997) Plant Cell 9, 869-878]. The D1' protein was found to be full
y operational although it deviates from the normal D1 protein in 54 out of
360 amino acids. Two notable amino-acid substitutions in D1' are the replac
ements of F186 by a leucine and P162 by a serine. The F186 and P162 positio
ns are located in the vicinity of the reaction centre chlorophyll dimer P68
0 and the redox-active Y161 (TyrZ), and F186 has been implicated in the ele
ctron transfer between Y161 and P680. The importance of F186 was addressed
by construction of engineered D1 proteins in Synechocystis 6803. F186 was r
eplaced by leucine, serine, alanine, tyrosine or tryptophan. Only the leuci
ne replacement yielded a functional D1 protein. Other substitutions did not
support photoautotrophic growth and the corresponding mutants showed no or
very poor oxygen evolving activity. In the F186Y and F186W mutants, the D1
protein failed to accumulate to appreciable levels in the thylakoid membra
ne. The F186S mutation severely increased the light sensitivity of the D1 p
rotein, as indicated by the presence of a 16-kDa proteolytic degradation pr
oduct. We conclude that the hydrophobicity and van der Waals volume are the
most important features of the residue at position 186. Exchanging P162 fo
r a serine yielded no observable phenotype.