Genetic evidence that the two isozymes of sucrose synthase present in developing maize endosperm are critical, one for cell wall integrity and the other for starch biosynthesis

In maize, two paralogous genes, Sh1 and Sus1, encode two biochemically similar isozymes of sucrose synthase, SS1 and SS2, respectively. Previous studies have attributed the mild starch deficiency of the shrunken1 (sh1) endosperm to the loss of the SS1 isozyme in the mutant. Here we describe the first mutation in the sucrose synthase1 (Sus1) gene, sus1-1, and the isolation of a double recessive genotype, sh1 sus1-1. Combined data from diverse studies, including Northern and Western analyses, RT-PCR and genomic PCR, cloning and sequencing data for the 3′ region, show that the mutant sus1-1 gene has a complex pattern of expression, albeit at much reduced levels as compared to the Sus1 gene. Endosperm sucrose synthase activity in sh1 sus1-1 was barely 0.5% of the total activity in the Sh1 Sus1 genotype. Significantly, comparative analyses of Sh1 Sus1, sh1 Sus1 and sh1 sus1-1 genotypes have, for the first time, allowed us to dissect the relative contributions of each isozyme to endosperm development. Starch contents in endosperm of the three related genotypes were 100, 78 and 53%, respectively. Anatomical analyses, which confirmed the previously described early cell degeneration phenotype unique to the sh1 Sus1 endosperm, revealed no detectable difference between the two sh1 genotypes. We conclude that the SS1 isozyme plays the dominant role in providing the substrate for cellulose biosynthesis, whereas the SS2 protein is needed mainly for generating precursors for starch biosynthesis.     

Sucrose Synthase in Developing Maize Leaves: Regulation of Activity by Protein Level during the Import to Export Transition

The maize (Zea mays) leaf is a valuable system to study the sucrose import to sucrose export transition at the cellular level. Rapidly growing and fully heterotrophic cells in the basal part of the young leaf showed a high sucrose synthase (SS) activity. Leaf SS has been purified to homogeneity. By comparison with purified kernel SS isozymes, the leaf SS has been identified as SS₂. SS₁ protein and SS₂ protein were clearly separated by electrophoresis and the two monomers differed in size by 6 kilodaltons. Nevertheless, kinetic parameters of both enzymes were very similar. Immunodetection of SS protein showed that in young heterotrophic tissues SS₂ was a major protein accounting for 3% of the total protein. Concurrent with greening, SS activity decreased and the change of activity was explained by regulation of the protein level. In mature green tissues, which are synthetizing sucrose as evidenced by the presence of sucrose phosphate synthase activity, SS activity was almost completely absent. Results suggested that down regulation of SS₂ enzyme protein level was an early event in the transition from import to export status of the leaf.     

Genetic evidence that the two isozymes of sucrose synthase present in developing maize endosperm are critical, one for cell wall integrity and the other for starch biosynthesis

In maize, two paralogous genes, Sh1 and Sus1, encode two biochemically similar isozymes of sucrose synthase, SS1 and SS2, respectively. Previous studies have attributed the mild starch deficiency of the shrunken1 (sh1) endosperm to the loss of the SS1 isozyme in the mutant. Here we describe the first mutation in the sucrose synthase1 (Sus1) gene, sus1-1, and the isolation of a double recessive genotype, sh1 sus1-1. Combined data from diverse studies, including Northern and Western analyses, RT-PCR and genomic PCR, cloning and sequencing data for the 3′ region, show that the mutant sus1-1 gene has a complex pattern of expression, albeit at much reduced levels as compared to the Sus1 gene. Endosperm sucrose synthase activity in sh1 sus1-1 was barely 0.5% of the total activity in the Sh1 Sus1 genotype. Significantly, comparative analyses of Sh1 Sus1, sh1 Sus1 and sh1 sus1-1 genotypes have, for the first time, allowed us to dissect the relative contributions of each isozyme to endosperm development. Starch contents in endosperm of the three related genotypes were 100, 78 and 53%, respectively. Anatomical analyses, which confirmed the previously described early cell degeneration phenotype unique to the sh1 Sus1 endosperm, revealed no detectable difference between the two sh1 genotypes. We conclude that the SS1 isozyme plays the dominant role in providing the substrate for cellulose biosynthesis, whereas the SS2 protein is needed mainly for generating precursors for starch biosynthesis. Received: 22 January 1998 / Accepted: 30 March 1998     

Gene expression studies on developing kernels of maize sucrose synthase (SuSy) mutants show evidence for a third SuSy gene

Previous studies have identified two tissue- and cell-specific, yet functionally redundant, sucrose synthase (SuSy) genes, Sh1 and Sus1, which encode biochemically similar isozymes, SH1 and SUS1 (previously referred to as SS1 and SS2, respectively). Here we report evidence for a third SuSy gene in maize, Sus3, which is more similar to dicot than to monocot SuSys. RNA and/or protein blot analyses on developing kernels and other tissues show evidence of expression of Sus3, although at the lowest steady-state levels of the three SuSy gene products and without a unique pattern of tissue specificity. Immunoblots of sh1sus1-1 embryos that are either lacking or deficient for the embryo-specific SUS1 protein have shown a protein band which we attribute to the Sus3 gene, and may contribute to the residual enzyme activity seen in embryos of the double mutant. We also studied developing seeds of the double mutant sh1sus1-1, which is missing 99.5% of SuSy enzyme activity, for evidence of co-regulation of several genes of sugar metabolism. We found a significant reduction in the steady-state levels of Miniature-1 encoded cell wall invertase2, and Sucrose transporter (Sut) mRNAs in the double mutant, relative to the lineage-related sh1Sus1 and sh1Sus1 kernels. Down-regulation of the Mn1 gene was also reflected in significant reductions in cell wall invertase activity. Co-regulatory changes were not seen in the expression of Sucrose phosphate synthase, UDP-glucose pyrophosphorylase, and ADP-glucose pyrophosphorylase.     

Altered tissue specificity of the revertant shrunken allele upon Dissociation (Ds) excision is associated with loss of expression and molecular rearrangement at the corresponding non-allelic isozyme locus in maize

Summary Transposable element Activator (Ac) induced wild-type stable revertants, derived from McClintock's Dissociation (Ds) insertion shrunken (sh) mutant sh-m5933, have been examined for sucrose synthases, SS1 and SS2, encoded by the revertant (Sh) locus and the non-allelic gene Sus (previously designated as Ss2), respectively. A structurally normal Sh locus has been previously described in these revertants. Immuno-blot (Western) and Southern hybridization analyses reported here identify one of the nine alleles, Sh-r5, as unique for several features. It showed altered tissue specificity, as the SS1 protein encoded by the Sh-r5 allele was readily detectable in the immature embryo which is otherwise characterized by the Sus expression only. The level of Sh-r5 expression at the protein and enzyme level was marked by endosperm specific SS1 abundance and a significant down-regulation in the embryo similar to the standard Sh and Sus loci in endosperm and embryo, respectively. We infer that tissue specific levels of gene expression among maize Ss genes is significantly determined by trans-regulatory factors present in these two tissues. The Sh-r5 strain also exhibited a complete loss of the Sus expression in all tissues tested in the plant. Lack of any detectable phenotypic abnormality in the Sh-r5 strain due to the loss of SS2 protein indicated that either the SS2 protein is nonessential or that the two SS isozymes are functionally compensatory. Genomic filter hybridizations with the Sus cDNA clone indicated that the Sus locus in the Sh-r5 strain was not deleted and was, in fact, unique among these revertants. Together, these data provide an unusual insight into the regulation and function of the two SS isozymes in the maize plant.     

Evidence for plasma membrane-associated forms of sucrose synthase in maize

Plasma membrane fractions were isolated from maize (Zea mays L.) endosperms and etiolated kernels to investigate the possible membrane location of the sucrose synthase (SS) protein. Endosperms from seedlings at both 12 and 21 days after pollination (DAP), representing early and mid-developmental stages, were used, in addition to etiolated leaf and elongation zones from seedlings. Plasma membrane fractions were isolated from this material using differential centrifugation and aqueous two-phase partitioning. The plasma membrane-enriched fraction obtained was then analyzed for the presence of sucrose synthase using protein blots and activity measurements. Both isozymes SS1 and SS2, encoded by the lociSh1 andSus1, respectively, were detected in the plasma membrane-enriched fraction using polyclonal and monoclonal antisera to SS1 and SS2 isozymes. In addition, measurements of sucrose synthase activity in plasma membrane fractions of endosperm revealed high levels of specific activity. The sucrose synthase enzyme is tightly associated with the membrane, as shown by Triton X-100 treatment of the plasma membrane-enriched fraction. It is noteworthy that the gene products of bothSh1 andSus1 were detectable as both soluble and plasma membrane-associated forms.     

Shrunken-1 encoded sucrose synthase is not required for sucrose synthesis in the maize endosperm

Kernels of wild-type maize (Zea mays L.) shrunken-1 (sh1), deficient in the predominant form of endosperm sucrose synthase and shrunken-2 (sh2), deficient in 95% of the endosperm ADP-glucose pyrophosphorylase were grown in culture on sucrose, glucose, or fructose as the carbon source. Analysis of the endosperm extracts by gas-liquid chromatography revealed that sucrose was present in the endosperms of all genotypes, regardless of carbon supply, indicating that all three genotypes are capable of synthesizing sucrose from reducing sugars. The finding that sucrose was present in sh1 kernels grown on reducing sugars is evidence that shrunken-1 encoded sucrose synthase is not necessary for sucrose synthesis. Shrunken-1 kernels developed to maturity and produced viable seeds on all carbon sources, but unlike wild-type and sh2 kernels grown in vitro, sucrose was not the superior carbon source. This latter result provides further evidence that the role of sucrose synthase in maize endosperm is primarily that of sucrose degradation.     

Subunit Composition of Glutamine Synthetase Isozymes from Root Nodules of Bean (Phaseolus vulgaris L.)

Glutamine synthetase from bean nodules can be separated into two isoforms, GS_n1 and GS_n2. A purification protocol has been developed. It included protamine sulfate precipitation, ammonium sulfate fractionation, anthranilate-affinity chromatography, Dye-Matrex (Orange A) chromatography, and diethylaminoethyl-cellulose ion-exchange chromatography. GS_n1 and GS_n2 have been purified to homogeneity. Subunit structure analysis using two-dimensional polyacrylamide gel electrophoresis revealed that GS_n1 was composed of two different types of subunit polypeptides. They differed in isoelectric points (6.0 and 6.3) but had the same molecular weights (46,000 Daltons). GS_n2 was composed of only one type of subunit polypeptide. It had an isoelectric point of 6.0 and a molecular weight of 46,000 Daltons. It was apparently identical to one of the polypeptides found in GS_n1. Glutamine synthetase holoenzyme consisted of eight subunits. In the nodule there are two different types of glutamine synthetase subunit polypeptides. Random combinations of the polypeptides should generate nine different isozymes. Our electrophoretic analysis revealed that GS_n2 was but one of the isozymes, and GS_n1 was a composite of the other eight. Hence, nodule glutamine synthetase isozymes were homo-octameric as well as hetero-octameric.     

Glutathione S-transferase isozymes in Aedes aegypti: Purification,characterization, and isozyme-specific regulation

Glutathione S-transferase (GST) isozymes were purified from the GG strain of Aedes aegypti, a strain having ≥4-fold higher total GST activity compared to the wild-type lab strain. Purification involved S-hexyl-glutathione affinity chromatography in high salt buffer, and GST specific elution with S-(p-bromobenzyl)-glutathione. Final purification was accomplished on DEAE-Sepharose. Two isozymes, GST-1b and GST-2 were purified using this procedure, and an additional isozyme, GST-1a, was partially purified. The GST-2 isozyme has one of the highest specific activities reported for a GST, with a specific activity of 739 μmol/min/mg using 1-chloro-2,4-dinitrobenzene (CDNB), and 16.4 μmol/min/mg using 3,4-dichloronitrobenzene (DCNB) as substrates. GST-2, GST-1a, and GST-1b were analyzed for amino acid composition and subjected to N-terminal sequencing. All three GSTs showed amino acid differences, especially among the nonpolar and polar amino acids. The amino acid composition of GST-1b was found to be more similar to GST 1-1 from Drosophila melanogaster than to GST-2 or GST-1a from Aedes aegypti. Only GST-2 gave N-terminal sequence data, raising the possibility that GST-1a and 1b are N-terminally blocked. The A. aegypti GST-2 showed amino acid sequence identity or similarity in all but one residue between residue numbers 31 through 41 compared to the D. melanogaster and Musca domestica GST 1-1 isozymes. The pattern of GST isozyme expression was analyzed in various tissues and stages of development of the GG and wild type strains using isozyme-specific antisera and substrates. GST-1a was constitutively overexpressed in all tissues examined in the GG strain compared to the wild type strain. The expression of GST-1b was similar in both strains for all tissues and developmental stages examined. GST-2 was constitutively overexpressed in head, thorax and abdomen, but was not detected in ovaries of the GG strain. These results suggest that elevated GST activity in the GG strain is due to constitutive overexpression of GST-2 and GST-1a. GST-1a, GST-1b and GST-2 apparently are the products of 3 independently regulated genes and appear to be expressed in a tissue-specific manner.     

Purification and properties of hepatic glutamine synthetases from the ureotelic gulf toadfish, Opsanus beta

The cytoplasmic and mitochondrial forms of glutamine synthetase (GSase) were purified from the liver of the gulf toadfish Opsanus beta by modifications of methods previously applied to dogfish shark to examine their kinetic and structural properties. Both isozymes have subunit molecular weights of approximately 42 kDa (by SDS-PAGE) and native molecular weights of approximately 365 kDa (by gel filtration chromatography), suggesting an octomeric arrangement of the native enzymes. Identity of the purified proteins as GSase was further confirmed by western blot analysis using rabbit anti-chicken GSase antibodies. The requirement for MgCl₂ and several kinetic properties (e.g.,K_ms for glutamate, ATP and ammonia) of the two isozymes were very similar. Also notable was that both isozymes had K_ms for ammonia in the micromolar range (like the dogfish enzyme). These results suggest that the enzymes are probably easily saturated with ammonia under physiological conditions. The two GSase isozymes differed substantially in terms of inhibition by methionine sulfoximine, pH optima, specific activity and ratios of transferase to biosynthetic activities. Given the similarities in size, these results suggest that the molecular model of a single gene coding for both isozymes as has been demonstrated in the dogfish shark may not apply to the toadfish GSases.     

Purification and properties of neutral β-galactosidases from human liver

Two neutral β-galactosidase isozymes were purified from human liver. The initial step of purification was removal of the acidic β-galactosidases by adsorption on concanavalin A-Sepharose 4B conjugate. Subsequent purification steps included ammonium sulfate precipitation, diethylaminoethyl cellulose column chromatography, Sephadex G-100 gel filtration, and preparative polyacrylamide-gel isoelectric focusing. The final step of purification was affinity chromatography of the separated isoelectric forms on ?-aminocaproyl-β-d-galactosylamine-Sepharose 4B conjugate. The purified β-galactosidase isozymes had activity toward both β-d-galactoside and β-d-glucoside derivatives of 4-methylumbelliferone and p-nitrophenol with a pH optimum around 6.2. These enzyme forms were also found to possess lactosylceramidase II activity with a pH optimum in the range of 5.4 to 5.6, but not lactosylceramidase I activity and no activity toward galactosylceramide or GM₁-ganglioside. The molecular weight was found to be in the range of 37,500–39,500 for the two neutral isozymes and they had similar K_m and V values; the more acidic form (designated β-galactosidase N₁) was more heat stable than the other form (designated β-galactosidase N₂). Antibodies evoked against the N₁ and N₂ β-galactosidases gave identical precipitin lines retaining enzymatic activity. No cross-reactivity was observed between the neutral and the acidic isozymes when examined with the respective antisera.     

The Biosynthesis of Sucrose and Nucleoside Diphosphate Glucoses in Phaseolus aureus

Sucrose-phosphate synthetase is detectable only in intact chloroplast preparations of Phaseolus aureus. In contrast, sucrose synthetase and uridine diphosphate glucose (UDP-glucose) pyrophosphorylase activities are low in extracts of photosynthetic tissues of P. aureus but are high in extracts of nonphotosynthetic tissues. Activities for ADP-, dTDP-, CDP-, and GDP-glucose pyrophosphorylases are generally higher in extracts of photosynthetic tissues of P. aureus than in extracts of nonphotosynthetic tissues. The high levels of sucrose synthetase and of UDP-glucose pyrophosphorylase found in dark-grown hypocotyls begin to decline about 4 hours after exposure to light at a rate of 50% every 3 hours.     

Wheat Alcohol Dehydrogenase Isozymes: PURIFICATION, CHARACTERIZATION, AND GENE EXPRESSION

Evidence in support of the hypothesis of gene expression and subunit association suggested earlier for Triticum alcohol dehydrogenase has been obtained through purification and partial characterization of the enzyme from tetraploid wheat. Three isozymes of alcohol dehydrogenase were separated and purified to apparent homogeneity using streptomycin sulfate precipitation, gel filtration chromatography, and anion exchange chromatography. The isozymes are dimers with the same molecular weight (116,000 ± 2,000), but significantly different isoelectric pH values. The Michaelis constants for NAD⁺ and ethanol are 0.1 millimolar and 12 millimolar, respectively. The substrate specificity of the three alcohol dehydrogenase isozymes was investigated.     

Isozymes of beta-N-Acetylhexosaminidase from Pea Seeds (Pisum sativum L.)

Four isozymes of β-N-acetylhexosaminidase (β-NAHA) from pea seeds (Pisum sativum L.) have been separated, with one, designated β-NAHA-II, purified to apparent homogeneity by means of an affinity column constructed by ligating p-aminophenyl-N-acetyl-β-d-thioglucosaminide to Affi-Gel 202. The other three isozymes have been separated and purified 500- to 1750-fold by chromatography on Concanavalin A-Sepharose, Zn²⁺ charged immobilized metal affinity chromatography, hydrophobic chromatography, and ion exchange chromatography on CM-Sephadex. All four isozymes are located in the protein bodies of the cotyledons. The molecular weight of each isozyme is 210,000. β-NAHA-II is composed of two heterogenous subunits. The subunits are not held together by disulfide bonds, but sulfhydryl groups are important for catalysis. All four isozymes release p-nitrophenol from both p-nitrophenyl-N-acetyl-β-d-glucosaminide and p-nitrophenyl-N-acetyl-β-d-galactosaminide. The ratio of activity for hydrolysis of the two substrates is pH dependent. The K_m value for the two substrates and pH optima of the isozymes are comparable to β-NAHAs from other plant sources.     

Purification and Partial Characterization of Potato (Solanum tuberosum) Invertase and Its Endogenous Proteinaceous Inhibitor

Invertase plays an important role in the hydrolysis of sucrose in higher plants, especially in the storage organs. In potato (Solanum tuberosum) tubers, and in some other plant tissues, the enzyme seems to be controlled by interaction with an endogenous proteinaceous inhibitor. An acid invertase from potato tubers (variety russet) was purified 1560-fold to electrophoretic homogeneity by consecutive use of concanvalin A-Sepharose 4B affinity chromatography, DEAE-Sephadex A-50-120 chromatography, Sephadex G-150 chromatography, and DEAE-Sephadex A-50-120 chromatography. The enzyme contained 10.9% carbohydrate, had an apparent molecular weight of 60,000 by gel filtration, and was composed of two identical molecular weight subunits (M_r 30,000). The enzyme had a K_m for sucrose of 16 millimolar at pH 4.70 and was most stable and had maximum activity around pH 5. The endogenous inhibitor was purified 610-fold to homogeneity by consecutive treatment at pH 1 to 1.5 at 37°C for 1 hour, (NH₄)₂SO₄ fractionation, Sephadex G-100 chromatography, DEAE-Sephadex G-50-120 chromatography, and hydroxylapatite chromatography. The inhibitor appears to be a single polypeptide (M_r 17,000) without glyco groups. The purified inhibitor was stable over the pH range of 2 to 7 when incubated at 37°C for 1 hour.     

Purification and Characterization of Two Forms of Glutamine Synthetase from the Pedicel Region of Maize (Zea mays L.) Kernels

Maize (Zea mays L.) kernel pedicels, including vascular tissues, pedicel parenchyma, placento-chalazal tissue, and the surrounding pericarp, contained two forms of glutamine synthetase (EC 6.3.1.2), separable by anion exchange chromatography under mildly acidic conditions. The earlier-eluting activity (GS_p1), but not the later-eluting activity (GS_p2), was chromatographically distinct from the maize leaf and root glutamine synthetases. The level of GS_p1 activity changed in a developmentally dependent manner while GS_p2 activity was constitutive. GS_p1 and GS_p2 exhibited distinct ratios of transferase to hydroxylamine-dependent synthetase activities (5 and 23, respectively), which did not change with kernel age. Purified pedicel glutamine synthetases had native relative molecular masses of 340,000, while the subunit relative molecular masses differed slightly at 38,900 and 40,500 for GS_p1 and GS_p2, respectively. Both GS forms required free Mg²⁺ with apparent K_ms = 2.0 and 0.19 millimolar for GS_p1 and GS_p2, respectively. GS_p1 had an apparent K_m for glutamate of 35 millimolar and exhibited substrate inhibition at glutamate concentrations greater than 90 millimolar. In contrast, GS_p2 exhibited simple Michaelis-Menten kinetics for glutamate with a K_m value of 3.4 millimolar. Both isozymes exhibited positive cooperativity for ammonia, with S_0.5 values of 100 and 45 micromolar, respectively. GS_p1 appears to be a unique, kernel-specific form of plant glutamine synthetase. Possible functions for the pedicel GS isozymes in kernel nitrogen metabolism are discussed.     

Prunus serotina Amygdalin Hydrolase and Prunasin Hydrolase : Purification, N-Terminal Sequencing, and Antibody Production

In black cherry (Prunus serotina Ehrh.) seed homogenates, amygdalin hydrolase (AH) participates with prunasin hydrolase (PH) and mandelonitrile lyase in the sequential degradation of (R)-amygdalin to HCN, benzaldehyde, and glucose. Four isozymes of AH (designated AH I, I′, II, II′) were purified from mature cherry seeds by concanavalin A-Sepharose 4B chromatography, ion-exchange chromatography, and chromatofocusing. All isozymes were monomeric glycoproteins with native molecular masses of 52 kD. They showed similar kinetic properties (pH optima, K_m, V_max) but differed in their isoelectric points and N-terminal amino acid sequences. Analytical isoelectric focusing revealed the presence of subisozymes of each isozyme. The relative abundance of these isozymes and/or subisozymes varied from seed to seed. Three isozymes of PH (designated PH I, IIa, and IIb) were purified to apparent homogeneity by affinity, ion-exchange, and hydroxyapatite chromatography and by nondenaturing polyacrylamide gel electrophoresis. PH I and PH IIb are 68-kD monomeric glycoproteins, whereas PH IIa is dimeric (140 kD). The N-terminal sequences of all PH and AH isozymes showed considerable similarity. Polyclonal antisera raised in rabbits against deglycosylated AH I or a mixture of the three deglycosylated PH isozymes were not monospecific as judged by immunoblotting analysis, but also cross-reacted with the opposing glucosidase. Monospecific antisera deemed suitable for immunocytochemistry and screening of expression libraries were obtained by affinity chromatography. Each antiserum recognized all known isozymes of the specific glucosidase used as antigen.     

Molecular cloning and biochemical characterization of three phosphoglycerate kinase isoforms from developing sunflower (Helianthus annuus L.) seeds

Three cDNAs encoding different phosphoglycerate kinase (PGK, EC 2.7.2.3) isoforms, two cytosolic (HacPGK1 and HacPGK2) and one plastidic (HapPGK), were cloned and characterized from developing sunflower (Helianthus annuus L.) seeds. The expression profiles of these genes showed differences in heterotrophic tissues, such as developing seeds and roots, where HacPGK1 was predominant, while HapPGK was highly expressed in photosynthetic tissues. The cDNAs were expressed in Escherichia coli, and the corresponding proteins purified to electrophoretic homogeneity, using immobilized metal ion affinity chromatography, and biochemically characterized. Despite the high level of identity between sequences, the HacPGK1 isoform showed strong differences in terms of specific activity, temperature stability and pH sensitivity in comparison to HacPGK2 and HapPGK. A polyclonal immune serum was raised against the purified HacPGK1 isoform, which showed cross-immunoreactivity with the other PGK isoforms. This serum allowed the localization of high expression levels of PGK isozymes in embryo tissues.     

Sucrose synthase in rice plants : growth-associated changes in tissue specific distributions

Different parts of the rice (Oryza sativa L.) plant at different growth stages were analyzed for sucrose synthase (SS) by enzyme activity assay and enzyme-linked immunosorbent assay directly on the extracts or on the eluates from a gel filtration column. On a dry matter basis, the amount of soluble protein and SS activity decreased significantly, but the amount of enzyme protein changed little in growing leaves. In the grain, the SS activity was the highest at the early ripening stage and decreased later, but the amount of SS protein increased with the increase in maturity. In the root, a low activity of SS was detectable only in the tillering but not in other stages. Immunoblotting of SS protein extracted from different parts of rice showed two bands. Elution patterns of crude extracts from a gel filtration column showed the presence of several types of SS protein. Among them, two to three types with larger elution volumes had the SS activity but others with smaller elution volumes (considered as the aggregated forms) had no activity. The SS purified from different parts of the plant showed similar but distinctly different electrophoretic mobilities in a native gel. It has been concluded that different isozymes are expressed in different tissues at different growth stages.