Phylogenetic Analysis of ADP-Glucose Pyrophosphorylase Subunits Reveals a Role of Subunit Interfaces in the Allosteric Properties of the Enzyme

ADP-glucose pyrophosphorylase (AGPase) catalyzes a rate-limiting step in glycogen and starch synthesis in bacteria and plants, respectively. Plant AGPase consists of two large and two small subunits that were derived by gene duplication. AGPase large subunits have functionally diverged, leading to different kinetic and allosteric properties. Amino acid changes that could account for these differences were identified previously by evolutionary analysis. In this study, these large subunit residues were mapped onto a modeled structure of the maize (Zea mays) endosperm enzyme. Surprisingly, of 29 amino acids identified via evolutionary considerations, 17 were located at subunit interfaces. Fourteen of the 29 amino acids were mutagenized in the maize endosperm large subunit (SHRUNKEN-2 [SH2]), and resulting variants were expressed in Escherichia coli with the maize endosperm small subunit (BT2). Comparisons of the amount of glycogen produced in E. coli, and the kinetic and allosteric properties of the variants with wild-type SH2/BT2, indicate that 11 variants differ from the wild type in enzyme properties or in vivo glycogen level. More interestingly, six of nine residues located at subunit interfaces exhibit altered allosteric properties. These results indicate that the interfaces between the large and small subunits are important for the allosteric properties of AGPase, and changes at these interfaces contribute to AGPase functional specialization. Our results also demonstrate that evolutionary analysis can greatly facilitate enzyme structure-function analyses.ADP-glucose pyrophosphorylase (AGPase) catalyzes the conversion of Glc-1-P (G-1-P) and ATP to ADP-Glc and pyrophosphate. This reaction represents a rate-limiting step in starch synthesis (Hannah, 2005). AGPase is an allosteric enzyme whose activity is regulated by small effector molecules. In plants, AGPase is activated by 3-phosphoglyceraldehyde (3-PGA) and deactivated by inorganic phosphate (Pi).Plant AGPase is a heterotetramer consisting of two identical large and two identical small subunits. The large and small subunits of AGPase were generated by a gene duplication. Subsequent sequence divergence has given rise to complementary rather than interchangeable subunits. Indeed, both subunits are needed for AGPase activity (Hannah and Nelson, 1976, Burger et al., 2003). Biochemical studies have indicated that both subunits are important for catalytic and allosteric properties (Hannah and Nelson, 1976; Greene et al., 1996a, 1996b; Ballicora et al., 1998; Laughlin et al., 1998; Frueauf et al., 2001; Kavakli et al., 2001a, 2001b; Cross et al., 2004, 2005; Hwang et al., 2005, 2006, 2007; Kim et al., 2007; Ventriglia et al., 2008). Surprisingly, Georgelis et al. (2007, 2008) showed that, in angiosperms, the small subunit is under greater evolutionary pressure compared with the large subunit. Detailed analyses have shown that the greater constraint on the small subunit is due to its broader tissue expression patterns compared with the large subunit and the fact that the small subunit must interact with multiple large subunits.Large subunits have undergone more duplication events than have small subunits (Georgelis et al., 2008). This has led to the creation of five groups of large subunits that differ in their patterns of tissue of expression (Akihiro et al., 2005; Crevillen et al., 2005; Ohdan et al., 2005). Crevillen et al. (2003) studied the biochemical properties of four Arabidopsis (Arabidopsis thaliana) AGPases consisting of the four different large subunits and the only functional small subunit in Arabidopsis. The different AGPases had different kinetic and allosteric properties. More specifically, the AGPases differed in their affinity for the allosteric regulator 3-PGA and the substrates G-1-P and ATP. This possibly reflects the different 3-PGA, G-1-P, and ATP levels in the various tissues. This evidence indicates that not only did the different large subunit groups subfunctionalize in terms of expression, but also these groups may have specialized in terms of protein function. While the study of Crevillen et al. (2003) pointed to functional specialization of the large subunit, the identity of the amino acid sites in the large subunit that account for these kinetic and allosteric differences was not pursued.Georgelis et al. (2008) presented supporting evidence for AGPase large subunit specialization by identifying positively selected amino acid sites in the phylogenetic branches following gene duplication events. We also identified amino acid residues that were conserved in one large subunit group but not conserved in another large subunit group (type I functional divergence; Gu, 1999) and amino acid residues that are conserved within large subunit groups but are variable among large subunit groups (type II functional divergence; Gu, 2006). Positively selected type I and type II sites could have contributed to specialization of the different large subunit groups. Indeed, positively selected type II sites in several proteins have been proven via site-directed mutagenesis (Bishop, 2005; Norrgård et al., 2006; Cavatorta et al., 2008; Courville et al., 2008) to be important for protein function and functional specialization. Additionally, several positively selected type I and type II amino acid sites in the large AGPase subunit identified in our previous evolutionary analysis (Georgelis et al., 2008) have been implicated in the kinetic and allosteric properties and heat stability of AGPase. The role of these sites was demonstrated by site-directed mutagenesis experiments of large subunits from Arabidopsis, maize endosperm, and potato (Solanum tuberosum) tuber (Ballicora et al., 1998, 2005; Kavakli et al., 2001a; Jin et al., 2005; Linebarger et al., 2005; Ventriglia et al., 2008). These analyses indicate that the rest of the amino acid sites identified as positive type I and type II sites in our previous evolutionary analysis (Georgelis et al., 2008) represent promising candidate targets for mutagenesis.To identify large subunit amino acids that are possibly important in controlling enzyme properties and that may have contributed to large subunit specialization, we conducted site-directed mutagenesis of the maize endosperm large subunit encoded by Shrunken-2 (Sh2). We specifically identified amino acids of SH2 that correspond to amino acid sites that were detected as positive type I and type II sites during the large subunit evolution (Georgelis et al., 2008). We then replaced the SH2 residues with amino acids of a group different from the SH2 family. Several amino acid sites important for the kinetic and allosteric properties and heat stability of AGPase were identified. Our results indicate that the subunit interfaces between the large and small subunits are important for the allosteric properties of AGPase. They also indicate that amino acid changes at subunit interfaces have been important for AGPase specialization in terms of allosteric properties. These experiments also support the idea that the majority of positively selected sites as detected by codon substitution models (Nielsen and Yang, 1998; Yang et al., 2000) and type II sites are not false positives. Site-directed mutagenesis of such sites can greatly facilitate enzyme structure-function analyses.