Evolution of C4 Phosphoenolpyruvate Carboxylase inFlaveria, a Conserved Serine Residue in the Carboxyl-terminal Part of the Enzyme Is a Major Determinant for C4-specific Characteristics

Oliver E Bläsing,Peter Westhoff,Per Svensson

doi:10.1074/jbc.m909832199

Oliver E Bläsing, Peter Westhoff + Show 1 more

Open Access

https://doi.org/10.1074/jbc.m909832199

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Abstract

C4 phosphoenolpyruvate carboxylases have evolved from ancestral C3 isoforms during the evolution of angiosperms and gained distinct kinetic and regulatory properties compared with the C3 isozymes. To identify amino acid residues and/or domains responsible for these C4-specific properties the C4 phosphoenolpyruvate carboxylase of Flaveria trinervia (C4) was compared with its orthologue in the closely related C3 plant Flaveria pringlei. Reciprocal enzyme chimera were constructed and the kinetic constants, K(0.5) and k(cat), as well as the Hill coefficient, h, were determined for the substrate phosphoenolpyruvate both in the presence and absence of the activator glucose 6-phosphate. By this approach two regions were identified which determined most of the kinetic differences of the C4 and C3 ppcA phosphoenolpyruvate carboxylases with respect to the substrate PEP. In addition, the experiments suggest that the two regions do not act additively but interact with each other. The region between amino acids 296 and 437 is essential for activation by glucose 6-phosphate. The carboxyl-terminal segment between amino acids 645 and 966 contains a C4 conserved serine or a C3 invariant alanine at position 774 in the respective enzyme isoform. Site-directed mutagenesis shows that this position is a key determinant for the kinetic properties of the two isozymes.

Highlights

C4 phosphoenolpyruvate carboxylases have evolved from ancestral C3 isoforms during the evolution of angiosperms and gained distinct kinetic and regulatory properties compared with the C3 isozymes
Both ppcA PEPCs are 966 amino acids in size and share 96% identical residues. The comparison of these two orthologous ppcA PEPCs was selected as the paradigm for studying the evolution of the ancestral C3 isoform toward the current C4 enzyme [10, 11]
Kinetic Properties of the ppcA PEPCs of F. trinervia (FT966) and F. pringlei (FP966)—The basis for the study was the large difference in K0.5-PEP observed between the C3 (FP966) and C4 (FT966) isoenzyme, respectively

Summary

Fragment III

AocI-PstI(Ft966) AocI-PstI(Fp966) SalI-SacI(Ft966*) SalI-SacI(Fp966*) SacI-BclI(Ft966*) SacI-BclI(Fp966*) ApaI-SacI(Ft966*) ApaI-SacI(Fp966*) BclI-BspHI(Ft966) BclI-BspHI(Fp966) AocI-ApaI(Fp966) AocI-ApaI(Ft966). PstI-AocI(Fp966) PstI-AocI(Ft966) SacI-SalI(Fp966*) SacI-SalI(Ft966*) BclI-BspHI(Fp966) BclI-BspHI(Ft966) SacI-NarI(Ft966*) SacI-NarI(Fp966*) BspHI-SacI(Ft966-S774A) BspHI-SacI(Fp966-A774S) ApaI-AgeI(Ft966-S774A) ApaI-AgeI(Fp966-A774S). BspHI-SacI(Ft966*) BspHI-SacI(Fp966*) NarI-ApaI(Fp966) NarI-ApaI(Ft966) SacI-BclI(Ft966*) SacI-BclI(Ft966*) AgeI-AocI(Fp966) AgeI-AocI(Ft966). Dicot origin possesses a serine in the carboxyl-terminal region, which in Flaveria is equivalent to amino acid 774. In all C3 and CAM PEPC isoforms this serine is replaced by an alanine. This strict correlative behavior of the serine/alanine position suggested a functional importance of this amino acid residue [11] and its role was investigated by site-directed mutagenesis

EXPERIMENTAL PROCEDURES

RESULTS

Hill coefficient h

DISCUSSION