Subcellular localization of ADPglucose pyrophosphorylase in developing wheat endosperm and analysis of the properties of a plastidial isoform

The intracellular location of ADPglucose pyrophosphorylase (AGPase) in wheat during endosperm development was investigated by analysis of the recovery of marker enzymes from amyloplast preparations. Amyloplast preparations contained 20-28% of the total endosperm activity of two plastidial marker enzymes and less than 0.8% of the total endosperm activity of two cytosolic marker enzymes. Amylo plasts prepared at various stages of development, from 8-30 d post anthesis, contained between 2% and 10% of the total AGPase activity; this implies that between 7% and 40% of the AGPase in wheat endosperm is plastidial during this period of development. Two proteins were recognized by antibodies to both the large and small subunits of wheat AGPase. The larger of the two AGPases was the major form of the enzyme in whole cell extracts, and the smaller, less abundant, form of AGPase was enriched in plastid preparations. The results are consistent with data from other graminaceous endosperms, suggesting that there are distinct plastidial and cytosolic isoforms of AGPase composed of different subunits. The plastidial isoform of AGPase from wheat endosperm is relatively insensitive to the allosteric regulators 3-phosphoglycerate and inorganic orthophos phate compared with plastidial AGPase from other species. Amyloplast AGPase showed no sensitivity to physiological concentrations of inorganic orthophosphate. 15 mM 3-phosphoglycerate caused no stimulation of the pyrophosphorolytic reaction, and only 2-fold stimulation of the ADPglucose synthesizing reaction.     

Nucleotides and Nucleotide Sugars in Developing Maize Endosperms (Synthesis of ADP-Glucose in brittle-1)

As part of an in vivo study of carbohydrate metabolism during development of Zea mays L. kernels, quantities of nucleotides and nucleotide sugars were measured in endosperm extracts from normal, the single-mutant genotypes shrunken-1 (sh1), shrunken-2 (sh2), and brittle-1 (btl}, and the multiple-mutant genotypes sh1bt1, sh2bt1, and sh1sh2bt1. Results showed that bt1 kernels accumulated more than 13 times as much adenosine 5[prime] diphospho-glucose (ADP-Glc) as normal kernels. Activity of starch synthase in bt1 endosperm was equal to that in endosperm extracts from normal kernels. Thus the ADP-Glc accumulation in bt1 endosperm cells was not due to a deficiency in starch synthase. ADP-Glc content in extracts of sh1bt1 endosperms was similar to that in bt1, but in extracts of the sh2bt1 mutant kernels ADP-Glc content was much reduced compared to bt1 (about 3 times higher than that in normal). Endosperm extracts from sh1sh2bt1, kernels that are deficient in both ADP-Glc pyrophosphorylase (AGPase) and sucrose synthase, had quantities of ADP-Glc much lower than in normal kernels. These results clearly indicate that AGPase is the predominant enzyme responsible for the in vivo synthesis of ADP-Glc in bt1 mutant kernels, but Suc synthase may also contribute to the synthesis of ADP-Glc in kernels deficient in AGPase.     

Characterization of ADP-glucose transport across the cereal endosperm amyloplast envelope

Most of the carbon used for starch biosynthesis in cereal endosperms is derived from ADP-glucose (ADP-Glc) synthesized by extra-plastidial AGPase activity, and imported directly across the amyloplast envelope. The properties of the wheat endosperm amyloplast ADP-Glc transporter were analysed with respect to substrate kinetics and specificities using reconstituted amyloplast envelope proteins in a proteoliposome-based assay system, as well as with isolated intact organelles. Experiments with liposomes showed that ADP-Glc transport was dependent on counter-exchange with other adenylates. Rates of ADP-Glc transport were highest with ADP and AMP as counter-exchange substrates, and kinetic analysis revealed that the transport system has a similar affinity for ADP and AMP. Measurement of ADP and AMP efflux from intact amyloplasts showed that, under conditions of ADP-Glc-dependent starch biosynthesis, ADP is exported from the plastid at a rate equal to that of ADP-Glc utilization by starch synthases. Photo-affinity labelling of amyloplast membranes with the substrate analogue 8-azido-[alpha-32P]ADP-Glc showed that the polypeptide involved in substrate binding is an integral membrane protein of 38 kDa. This study shows that the ADP-Glc transporter in cereal endosperm amyloplasts imports ADP-Glc in exchange for ADP which is produced as a by-product of the starch synthase reaction inside the plastid.     

Distinct isoforms of ADPglucose pyrophosphorylase occur inside and outside the amyloplasts in barley endosperm

This paper addresses the controversial idea that ADPglucose pyrophosphorylase may be located in the cytosol in some non-photosynthetic plant organs. The intracellular location of the enzyme in developing barley endosperm has been investigated by isolation of intact amyloplasts. Amyloplast preparations contained 13–17% of the total endosperm activity of two plastidial marker enzymes, and less than 0.5% of the total endosperm activity of two cytosolic marker enzymes. Amyloplast preparations contained about 2.5% of the ADPglucose pyrophosphorylase activity, indicating that approximately 15% of the ADPglucose pyrophosphorylase activity in young endosperms is plastidial. Immunoblotting of gels of endosperm and amyloplast extracts also indicated that the enzyme is both inside and outside the amyloplast. Antibodies to the small subunits of the enzyme from barley and maize revealed two bands of protein of different sizes, one of which was located inside and the other outside the amyloplast. The plastidial protein was of the same size as a protein in the chloroplasts of barley leaves which was also recognized by these antibodies. It is suggested that the barley plant contains two distinct isoforms of ADPglucose pyrophosphorylase: one located in plastids (chloroplasts and amyloplasts) and the other in the cytosol of the endosperm. The role of the cytosolic ADPglucose pyrophosphorylase is unknown. Although it may contribute ADPglucose to starch synthesis, the total activity of ADPglucose pyrophosphorylase in the endosperm is far in excess of the rate of starch synthesis and the plastidial isoform is probably capable of catalysing the entire flux of carbon to starch.     

The major form of ADP-glucose pyrophosphorylase in maize endosperm is extra-plastidial.

Preparations enriched in plastids were used to investigate the location of ADP-glucose pyrophosphorylase (AGPase) in the developing endosperm of maize (Zea mays L.). These preparations contained more than 25% of the total activity of the plastid marker enzymes alkaline pyrophosphatase and soluble starch synthase, less than 2% of the cytosolic marker enzymes alcohol dehydrogenase and pyrophosphate, fructose 6-phosphate 1-phosphotransferase, and approximately 3% of the AGPase activity. Comparison with the marker enzyme distribution suggests that more than 95% of the activity of AGPase in maize endosperm is extra-plastidial. Two proteins were recognized by antibodies to the small subunit of AGPase from maize endosperm Brittle-2 (Bt2). The larger of the two proteins was the major small subunit in homogenates of maize endosperm, and the smaller, less abundant of the two proteins was enriched in preparations containing plastids. These results suggest that there are distinct plastidial and cytosolic forms of AGPase, which are composed of different subunits. Consistent with this was the finding that the bt2 mutation specifically eliminated the extraplastidial AGPase activity and the larger of the two proteins recognized by the antibody to the Bt2 subunit.     

Purification and properties of the adenosine diphosphate-glucose and uridine diphosphate-glucose pyrophosphorylases of Mycobacterium smegmatis: inhibition and activation of the adenosine diphosphate-glucose pyrophosphorylase

Crude extracts of Mycobacterium smegmatis catalyzed the synthesis of adenosine diphosphate-glucose (ADP-Glc), cytidine diphosphate-glucose, guanosine diphosphate-glucose (GDP-Glc), thymidine diphosphate-glucose (TDP-Glc), and uridine diphosphate-glucose (UDP-Glc). In these crude enzyme fractions, high concentrations of trehalose-P inhibited the ADP-Glc and GDP-Glc pyrophosphorylases but did not effect the UDP-Glc or TDP-Glc pyrophosphorylases. Both the ADP-Glc pyrophosphorylase and the UDP-Glc pyrophosphorylase were partially purified (about 140-fold and 60-fold, respectively), and their properties were compared. For the ADP-Glc pyrophosphorylase, the K(m) for adenosine triphosphate was 6 x 10(-4)m, whereas that for glucose-1-P was 8 x 10(-4)m. The optimal concentration of Mg(2+) was 1 x 10(-3)m, and the pH optimum was 8.5. For the UDP-Glc pyrophosphorylase, the K(m) for uridine triphosphate was 1 x 10(-3)m and for glucose-1-P was 2 x 10(-3)m. The optimal Mg(2+) concentration was 1 x 10(-3)m, and the pH optimum was about 8.0. The purified ADP-Glc pyrophosphorylase was inhibited by fructose-6-P, fructose-1, 6-diphosphate, glucose-6-P, and phosphoenolpyruvate. On the other hand, trehalose, trehalose diphosphate, sodium pyruvate, and ribose-5-P did not effect the ADP-Glc pyrophosphorylase. None of these compounds, including trehalose-P, had any effect on the UDP-Glc pyrophosphorylase.     

A low-starch barley mutant,risø 16, lacking the cytosolic small subunit of ADP-glucose pyrophosphorylase,reveals the importance of the cytosolic isoform and the identity of the plastidial small subunit

To provide information on the roles of the different forms of ADP-glucose pyrophosphorylase (AGPase) in barley (Hordeum vulgare) endosperm and the nature of the genes encoding their subunits, a mutant of barley, Ris? 16, lacking cytosolic AGPase activity in the endosperm was identified. The mutation specifically abolishes the small subunit of the cytosolic AGPase and is attributable to a large deletion within the coding region of a previously characterized small subunit gene that we have called Hv.AGP.S.1. The plastidial AGPase activity in the mutant is unaffected. This shows that the cytosolic and plastidial small subunits of AGPase are encoded by separate genes. We purified the plastidial AGPase protein and, using amino acid sequence information, we identified the novel small subunit gene that encodes this protein. Studies of the Ris? 16 mutant revealed the following. First, the reduced starch content of the mutant showed that a cytosolic AGPase is required to achieve the normal rate of starch synthesis. Second, the mutant makes both A- and B-type starch granules, showing that the cytosolic AGPase is not necessary for the synthesis of these two granule types. Third, analysis of the phylogenetic relationships between the various small subunit proteins both within and between species, suggest that the cytosolic AGPase single small subunit gene probably evolved from a leaf single small subunit gene.     

Both subunits of ADP-glucose pyrophosphorylase are regulatory

The allosteric enzyme ADP-Glc pyrophosphorylase (AGPase) catalyzes the synthesis of ADP-Glc, a rate-limiting step in starch synthesis. Plant AGPases are heterotetramers, most of which are activated by 3-phosphoglyceric acid (3-PGA) and inhibited by phosphate. The objectives of these studies were to test a hypothesis concerning the relative roles of the two subunits and to identify regions in the subunits important in allosteric regulation. We exploited an Escherichia coli expression system and mosaic AGPases composed of potato (Solanum tuberosum) tuber and maize (Zea mays) endosperm subunit fragments to pursue this objective. Whereas potato and maize subunits have long been separated by speciation and evolution, they are sufficiently similar to form active mosaic enzymes. Potato tuber and maize endosperm AGPases exhibit radically different allosteric properties. Hence, comparing the kinetic properties of the mosaics to those of the maize endosperm and potato tuber AGPases has enabled us to identify regions important in regulation. The data herein conclusively show that both subunits are involved in the allosteric regulation of AGPase. Alterations in the small subunit condition drastically different allosteric properties. In addition, extent of 3-PGA activation and extent of 3-PGA affinity were found to be separate entities, mapping to different regions in both subunits.     

Isolation of a heat-stable maize endosperm ADP-glucose pyrophosphorylase variant

Heat stress reduces maize yield and several lines of evidence suggest that the heat lability of maize endosperm ADP-glucose pyrophosphorylase (AGPase) contributes to this yield loss. AGPase catalyzes a rate-limiting step in starch synthesis. Herein, we present a novel maize endosperm AGPase small subunit variant, termed BT2-TI that harbors a single amino acid change of residue 462 from threonine to isoleucine. The mutant was isolated by random mutagenesis and heterologous expression in a bacterial system. BT2-TI exhibits enhanced heat stability compared to wildtype maize endosperm AGPase.The TI mutation was placed into another heat-stable small subunit variant, MP. MP is composed of sequences from the maize endosperm and the potato tuber small subunit. The MP-TI small subunit variant exhibited greater heat stability than did MP. Characterization of heat stability as well as kinetic and allosteric properties suggests that MP-TI may lead to increased starch yield when expressed in monocot endosperms.     

Brittle-1, an Adenylate Translocator, Facilitates Transfer of Extraplastidial Synthesized ADP-Glucose into Amyloplasts of Maize Endosperms

Amyloplasts of starchy tissues such as those of maize (Zea mays L.) function in the synthesis and accumulation of starch during kernel development. ADP-glucose pyrophosphorylase (AGPase) is known to be located in chloroplasts, and for many years it was generally accepted that AGPase was also localized in amyloplasts of starchy tissues. Recent aqueous fractionation of young maize endosperm led to the conclusion that 95% of the cellular AGPase was extraplastidial, but immunolocalization studies at the electron- and light-microscopic levels supported the conclusion that maize endosperm AGPase was localized in the amyloplasts. We report the results of two nonaqueous procedures that provide evidence that in maize endosperms in the linear phase of starch accumulation, 90% or more of the cellular AGPase is extraplastidial. We also provide evidence that the brittle-1 protein (BT1), an adenylate translocator with a KTGGL motif common to the ADP-glucose-binding site of starch synthases and bacterial glycogen synthases, functions in the transfer of ADP-glucose into the amyloplast stroma. The importance of the BT1 translocator in starch accumulation in maize endosperms is demonstrated by the severely reduced starch content in bt1 mutant kernels.     

Subcellular analysis of starch metabolism in developing barley seeds using a non-aqueous fractionation method

Compartmentation of metabolism in developing seeds is poorly understood due to the lack of data on metabolite distributions at the subcellular level. In this report, a non-aqueous fractionation method is described that allows subcellular concentrations of metabolites in developing barley endosperm to be calculated. (i) Analysis of subcellular volumes in developing endosperm using micrographs shows that plastids and cytosol occupy 50.5% and 49.9% of the total cell volume, respectively, while vacuoles and mitochondria can be neglected. (ii) By using non-aqueous fractionation, subcellular distribution between the cytosol and plastid of the levels of metabolites involved in sucrose degradation, starch synthesis, and respiration were determined. With the exception of ADP and AMP which were mainly located in the plastid, most other metabolites of carbon and energy metabolism were mainly located outside the plastid in the cytosolic compartment. (iii) In developing barley endosperm, the ultimate precursor of starch, ADPglucose (ADPGlc), was mainly located in the cytosol (80-90%), which was opposite to the situation in growing potato tubers where ADPGlc was almost exclusively located in the plastid (98%). This reflects the different subcellular distribution of ADPGlc pyrophosphorylase (AGPase) in these tissues. (iv) Cytosolic concentrations of ADPGlc were found to be close to the published K(m) values of AGPase and the ADPGlc/ADP transporter at the plastid envelope. Also the concentrations of the reaction partners glucose-1-phosphate, ATP, and inorganic pyrophosphate were close to the respective K(m) values of AGPase. (v) Knock-out of cytosolic AGPase in Riso16 mutants led to a strong decrease in ADPGlc level, in both the cytosol and plastid, whereas knock-down of the ADPGlc/ADP transporter led to a large shift in the intracellular distribution of ADPGlc. (v) The thermodynamic structure of the pathway of sucrose to starch was determined by calculating the mass-action ratios of all the steps in the pathway. The data show that AGPase is close to equilibrium, in both the cytosol and plastid, whereas the ADPGlc/ADP transporter is strongly displaced from equilibrium in vivo. This is in contrast to most other tissues, including leaves and potato tubers. (vi) Results indicate transport rather than synthesis of ADPGlc to be the major regulatory site of starch synthesis in barley endosperm. The reversibility of AGPase in the plastid has important implications for the regulation of carbon partitioning between different biosynthetic pathways.     

The lys5 mutations of barley reveal the nature and importance of plastidial ADP-Glc transporters for starch synthesis in cereal endosperm

Much of the ADP-Glc required for starch synthesis in the plastids of cereal endosperm is synthesized in the cytosol and transported across the plastid envelope. To provide information on the nature and role of the plastidial ADP-Glc transporter in barley (Hordeum vulgare), we screened a collection of low-starch mutants for lines with abnormally high levels of ADP-Glc in the developing endosperm. Three independent mutants were discovered, all of which carried mutations at the lys5 locus. Plastids isolated from the lys5 mutants were able to synthesize starch at normal rates from Glc-1-P but not from ADP-Glc, suggesting a specific lesion in the transport of ADP-Glc across the plastid envelope. The major plastidial envelope protein was purified, and its sequence showed it to be homologous to the maize (Zea mays) ADP-Glc transporter BRITTLE1. The gene encoding this protein in barley, Hv.Nst1, was cloned, sequenced, and mapped. Like lys5, Hv.Nst1 lies on chromosome 6(6H), and all three of the lys5 alleles that were examined were shown to carry lesions in Hv.Nst1. Two of the identified mutations in Hv.Nst1 lead to amino acid substitutions in a domain that is conserved in all members of the family of carrier proteins to which Hv.NST1 belongs. This strongly suggests that Hv.Nst1 lies at the Lys5 locus and encodes a plastidial ADP-Glc transporter. The low-starch phenotype of the lys5 mutants shows that the ADP-Glc transporter is required for normal rates of starch synthesis. This work on Hv.NST1, together with the earlier work on BRITTLE1, suggests that homologous transporters are probably present in the endosperm of all cereals.     

Sucrose-to-Starch Metabolism in Tomato Fruit Undergoing Transient Starch Accumulation

Immature green tomato (Lycopersicon esculentum) fruits undergo a period of transient starch accumulation characterized by developmental changes in the activities of key enzymes in the sucrose (Suc)-to-starch metabolic pathway. Activities of Suc synthase, fructokinase, ADP-glucose (Glc) pyrophosphorylase, and soluble and insoluble starch synthases decline dramatically in parallel to the decrease in starch levels in the developing fruit. Comparison of "maximal" in vitro activities of the enzymes in the Suc-to-starch pathway suggests that these same enzymes are limiting to the rate of starch accumulation. In contrast, activities of invertase, UDP-Glc pyrophosphorylase, nucleoside diphosphate kinase, phosphoglucoisomerase, and phosphoglucomutase do not exhibit dramatic decreases in activity and appear to be in excess of starch accumulation rates. Starch accumulation is spatially localized in the inner and radial pericarp and columella, whereas the outer pericarp and seed locule contain little starch. The seed locule is characterized by lower activities of Suc synthase, UDP-Glc pyrophosphorylase, phosphoglucomutase, ADP-Glc pyrophosphorylase, and soluble and insoluble starch synthases. The outer pericarp exhibits comparatively lower activities of ADP-Glc pyrophosphorylase and insoluble starch synthase only. These data are discussed in terms of the developmental and tissue-specific coordinated control of Suc-to-starch metabolism.     

Heat stability of maize endosperm ADP-glucose pyrophosphorylase is enhanced by insertion of a cysteine in the N terminus of the small subunit

ADP-glucose pyrophosphorylase (AGPase) is a key regulatory enzyme in starch biosynthesis. However, plant AGPases differ in several parameters, including spatial and temporal expression, allosteric regulation, and heat stability. AGPases of cereal endosperms are heat labile, while those in other tissues, such as the potato (Solanum tuberosum) tuber, are heat stable. Sequence comparisons of heat-stable and heat-labile AGPases identified an N-terminal motif unique to heat-stable enzymes. Insertion of this motif into recombinant maize (Zea mays) endosperm AGPase increased the half-life at 58 degrees C more than 70-fold. Km values for physiological substrates were unaffected, although Kcat was doubled. A cysteine within the inserted motif gives rise to small subunit homodimers not found in the wild-type maize enzyme. Placement of this N-terminal motif into a mosaic small subunit containing the N terminus from maize endosperm and the C terminus from potato tuber AGPase increases heat stability more than 300-fold.     

Studies of the Kinetic Mechanism of Maize Endosperm ADP-Glucose Pyrophosphorylase Uncovered Complex Regulatory Properties

ADP-glucose pyrophosphorylase catalyzes the synthesis of ADP-glucose (ADP-Glc) from Glc-1-phosphate (G-1-P) and ATP. Kinetic studies were performed to define the nature of the reaction, both in the presence and absence of allosteric effector molecules. When 3-phosphoglycerate (3-PGA), the putative physiological activator, was present at a saturating level, initial velocity studies were consistent with a Theorell-Chance BiBi mechanism and product inhibition data supported sequential binding of ATP and G-1-P, followed by ordered release of pyrophosphate and ADP-Glc. A sequential mechanism was also followed when 3-PGA was absent, but product inhibition patterns changed dramatically. In the presence of 3-PGA, ADP-Glc is a competitive inhibitor with respect to ATP. In the absence of 3-PGA—with or without 5.0 mm inorganic phosphate—ADP-Glc actually stimulated catalytic activity, acting as a feedback product activator. By contrast, the other product, pyrophosphate, is a potent inhibitor in the absence of 3-PGA. In the presence of subsaturating levels of allosteric effectors, G-1-P serves not only as a substrate but also as an activator. Finally, in the absence of 3-PGA, inorganic phosphate, a classic inhibitor or antiactivator of the enzyme, stimulates enzyme activity at low substrate by lowering the K_M values for both substrates.Plant ADP-Glc pyrophosphorylase (AGPase) catalyzes an important, rate-limiting step in starch biosynthesis: the reversible formation of ADP-Glc from ATP and Glc-1-P (G-1-P). Most AGPases are regulated by effector molecules derived from the prevalent carbon metabolism pathway, with inorganic phosphate (P_i) and 3-phosphoglycerate (3-PGA) being the most studied effectors of higher plants. Interestingly, the barley (Hordeum vulgare) endosperm form of AGPase is unique among higher plant homologs in its insensitivity to both 3-PGA and P_i (Kleczkowski et al., 1993a). Heat lability (as often found for endosperm AGPases) and reductive activation (for those AGPases harboring an N-terminal Cys residue in the small subunit) are also important mechanisms by which AGPases are regulated (Fu et al., 1998; Tiessen et al., 2002).Transgenic plant studies emphasize the importance of allosteric effectors in controlling enzyme activity and, in turn, starch yield. For example, expressing an allosterically enhanced Escherichia coli AGPase resulted in a 35% increase in potato (Solanum tuberosum) tuber starch (Stark et al., 1992) and a 22% to 25% increase in maize (Zea mays) seed starch (Wang et al., 2007). Rice (Oryza sativa) seed weight was increased up to 11% by expression of a second E. coli-derived AGPase mutant with altered allosteric properties (Sakulsingharoj et al., 2004). In another example, expressing a maize AGPase variant with less sensitivity to P_i and enhanced heat stability led to a 38% increase in wheat (Triticum aestivum) yield (Smidansky et al., 2002), a 23% increase in rice yield (Smidansky et al., 2003), and up to a 68% increase in maize yield (L.C. Hannah, unpublished data). Increases in these cases were due to enhanced seed number. Finally, transgenic expression of an allosterically altered potato tuber AGPase enhanced Arabidopsis (Arabidopsis thaliana) leaf transitory starch turnover and improved growth characteristics (Obana et al., 2006) and enhanced the fresh weight of aerial parts of lettuce (Lactuca sativa) plants (Lee et al., 2009).In higher plants, AGPase is a heterotetramer, consisting of two large and two small subunits; by contrast, most bacterial AGPases are homotetramers. Crystal structures of a bacterial AGPase and a nonnative, small subunit homotetramer derived from the potato tuber enzyme have been described recently (Jin et al., 2005; Cupp-Vickery et al., 2008). Unfortunately, since both structures were determined in the presence of high sulfate concentrations, both enzymes are in inactive forms.While AGPase allosteric regulation has received a great deal of attention, the kinetic mechanism has been defined completely only for two cases: the homotetrameric form from the bacterium Rhodospirillum rubrum and the plant heterotetrameric enzyme from barley leaf (Paule and Preiss, 1971; Kleczkowski et al., 1993b). The kinetic mechanism is sequential in both cases, with ATP the first substrate bound and ADP-Glc the final product released. Despite this similarity, there are important differences, most notably the existence of an isomerization step following ADP-Glc release, so that this product and ATP bind to different forms of the barley enzyme. This isomerization step is absent from the bacterial enzyme. Interestingly, isoforms of the closely related nucleoside diphospho-Glc family exhibit fundamentally different kinetic mechanisms. Some UDP-Glc pyrophosphorylases catalyze a sequential BiBi mechanism (Elling, 1996), while others, such as dTDP-Glc and CDP-Glc pyrophosphorylases from Salmonella, employ a ping-pong mechanism (Lindqvist et al., 1993, 1994).Because of the mechanistic diversity exhibited by pyrophosphorylases in general and by the two well-characterized AGPases in particular, we investigated the kinetic mechanism of the recombinant maize endosperm AGPase. We were particularly interested in the roles played by allosteric effectors that appear to be critically important in catalytic efficiency and, thus, starch content. Surprisingly, patterns of initial velocity at varying substrate concentrations as well as product inhibition behavior were identical to those observed for the homotetrameric bacterial enzyme (Paule and Preiss, 1971) and differed significantly from the heterotetrameric barley leaf enzyme (Kleczkowski et al., 1993b). Moreover, we found that both G-1-P and ADP-Glc could stimulate AGPase catalytic activity beyond that expected for simple substrate effects. We also found that the classic inhibitor, P_i, actually enhanced AGPase activity at low substrate concentrations but inhibited activity at high substrate levels. A model is presented to account for this observation. Finally, we determined that 3-PGA only stimulates AGPase activity by 2.5-fold if care is taken to saturate with substrates during assays.