Functional interactions between starch synthase III and isoamylase-type starch-debranching enzyme in maize endosperm

This study characterized genetic interactions between the maize (Zea mays) genes dull1 (du1), encoding starch synthase III (SSIII), and isa2, encoding a noncatalytic subunit of heteromeric isoamylase-type starch-debranching enzyme (ISA1/ISA2 heteromer). Mutants lacking ISA2 still possess the ISA1 homomeric enzyme. Eight du1(-) mutations were characterized, and structural changes in amylopectin resulting from each were measured. In every instance, the same complex pattern of alterations in discontinuous spans of chain lengths was observed, which cannot be explained solely by a discrete range of substrates preferred by SSIII. Homozygous double mutants were constructed containing the null mutation isa2-339 and either du1-Ref, encoding a truncated SSIII protein lacking the catalytic domain, or the null allele du1-R4059. In contrast to the single mutant parents, double mutant endosperms affected in both SSIII and ISA2 were starch deficient and accumulated phytoglycogen. This phenotype was previously observed only in maize sugary1 mutants impaired for the catalytic subunit ISA1. ISA1 homomeric enzyme complexes assembled in both double mutants and were enzymatically active in vitro. Thus, SSIII is required for normal starch crystallization and the prevention of phytoglycogen accumulation when the only isoamylase-type debranching activity present is ISA1 homomer, but not in the wild-type condition, when both ISA1 homomer and ISA1/ISA2 heteromer are present. Previous genetic and biochemical analyses showed that SSIII also is required for normal glucan accumulation when the only isoamylase-type debranching enzyme activity present is ISA1/ISA heteromer. These data indicate that isoamylase-type debranching enzyme and SSIII work in a coordinated fashion to repress phytoglycogen accumulation.     

Mutational analysis of the pullulanase-type debranching enzyme of maize indicates multiple functions in starch metabolism

Plants contain two types of alpha(1-->6) glucan hydrolase (starch-debranching enzyme [DBE]). Mutations that affect the pullulanase-type DBE have not been described, although defects in isoamylase-type DBE, known in many plant species, indicate a function in starch biosynthesis. We describe a null mutation of a pullulanase-type DBE gene, a Mutator insertion in maize Zpu1. Plants homozygous for the zpu1-204 mutation are impaired in transient and storage starch degradation. Thus, hydrolytic activity of pullulanase-type DBE contributes to starch catabolism. Developing zpu1-204 endosperm accumulates branched maltooligosaccharides not found in the wild type and is deficient in linear maltooligosaccharides, indicating that the pullulanase-type DBE functions in glucan hydrolysis during kernel starch formation. Furthermore, in a background deficient in isoamylase-type DBE, zpu1-204 conditions a significant accumulation of phytoglycogen in the kernel that is not seen in the wild type. Therefore, pullulanase-type DBE partially compensates for the defect in isoamylase-type DBE, suggesting a function during starch synthesis as well as degradation.     

Determining the role of Tie-dyed1 in starch metabolism: epistasis analysis with a maize ADP-glucose pyrophosphorylase mutant lacking leaf starch

In regions of their leaves, tdy1-R mutants hyperaccumulate starch. We propose 2 alternative hypotheses to account for the data, that Tdy1 functions in starch catabolism or that Tdy1 promotes sucrose export from leaves. To determine whether Tdy1 might function in starch breakdown, we exposed plants to extended darkness. We found that the tdy1-R mutant leaves retain large amounts of starch on prolonged dark treatment, consistent with a defect in starch catabolism. To further test this hypothesis, we identified a mutant allele of the leaf expressed small subunit of ADP-glucose pyrophosphorylase (agps-m1), an enzyme required for starch synthesis. We determined that the agps-m1 mutant allele is a molecular null and that plants homozygous for the mutation lack transitory leaf starch. Epistasis analysis of tdy1-R; agps-m1 double mutants demonstrates that Tdy1 function is independent of starch metabolism. These data suggest that Tdy1 may function in sucrose export from leaves.     

Mutants of Arabidopsis lacking a chloroplastic isoamylase accumulate phytoglycogen and an abnormal form of amylopectin

Mutant lines defective for each of the four starch debranching enzyme (DBE) genes (AtISA1, AtISA2, AtISA3, and AtPU1) detected in the nuclear genome of Arabidopsis (Arabidopsis thaliana) were produced and analyzed. Our results indicate that both AtISA1 and AtISA2 are required for the production of a functional isoamylase-type of DBE named Iso1, the major isoamylase activity found in leaves. The absence of Iso1 leads to an 80% decrease in the starch content in both lines and to the accumulation of water-soluble polysaccharides whose structure is similar to glycogen. In addition, the residual amylopectin structure in the corresponding mutant lines displays a strong modification when compared to the wild type, suggesting a direct, rather than an indirect, function of Iso1 during the synthesis of amylopectin. Mutant lines carrying a defect in AtISA3 display a strong starch-excess phenotype at the end of both the light and the dark phases accompanied by a small modification of the amylopectin structure. This result suggests that this isoamylase-type of DBE plays a major role during starch mobilization. The analysis of the Atpu1 single-mutant lines did not lead to a distinctive phenotype. However, Atisa2/Atpu1 double-mutant lines display a 92% decrease in starch content. This suggests that the function of pullulanase partly overlaps that of Iso1, although its implication remains negligible when Iso1 is present within the cell.     

Characterization of SU1 Isoamylase, a Determinant of Storage Starch Structure in Maize

Function of the maize (Zea mays) gene sugary1 (su1) is required for normal starch biosynthesis in endosperm. Homozygous su1- mutant endosperms accumulate a highly branched polysaccharide, phytoglycogen, at the expense of the normal branched component of starch, amylopectin. These data suggest that both branched polysaccharides share a common precursor, and that the product of the su1 gene, designated SU1, participates in kernel starch biosynthesis. SU1 is similar in sequence to α-(1→6) glucan hydrolases (starch-debranching enzymes [DBEs]). Specific antibodies were produced and used to demonstrate that SU1 is a 79-kD protein that accumulates in endosperm coincident with the time of starch biosynthesis. Nearly full-length SU1 was expressed in Escherichia coli and purified to apparent homogeneity. Two biochemical assays confirmed that SU1 hydrolyzes α-(1→6) linkages in branched polysaccharides. Determination of the specific activity of SU1 toward various substrates enabled its classification as an isoamylase. Previous studies had shown, however, that su1- mutant endosperms are deficient in a different type of DBE, a pullulanase (or R enzyme). Immunoblot analyses revealed that both SU1 and a protein detected by antibodies specific for the rice (Oryza sativa) R enzyme are missing from su1- mutant kernels. These data support the hypothesis that DBEs are directly involved in starch biosynthesis.Starch is a reserve carbohydrate that accumulates in the storage organs of many higher plants. This storage compound consists of a mixture of two Glc homopolymers, amylopectin and amylose, in which linear chains are formed via α-(1→4) glucosyl linkages and branches are introduced by α-(1→6) glucosyl linkages. Starch synthesis in maize (Zea mays) occurs within the amyloplasts of endosperm cells during kernel development via the concerted actions of ADP-Glc pyrophosphorylase, starch synthases, and starch-branching enzymes (for reviews, see Preiss, 1991; Hannah et al., 1993; Martin and Smith, 1995; Nelson and Pan, 1995; Preiss and Sivak, 1996; Smith et al., 1996). In addition, selective removal of branch linkages by DBEs is proposed to play an essential role in the final determination of amylopectin structure (Ball et al., 1996).Physical and chemical analyses of granular starch have led to a widely accepted model for amylopectin structure called the “cluster model,” in which amorphous and crystalline regions alternate with a defined periodicity (for reviews, see French, 1984; Manners, 1989; Jenkins et al., 1993). Within amylopectin the crystalline component is composed of parallel arrays of linear chains packed tightly in double helices. Branch linkages, which account for approximately 5% of the glucosyl linkages in amylopectin, are located at the root of each cluster in the amorphous region. This periodic clustering of branches allows for the alignment of the intervening linear chains and their dense packing into crystalline regions, thus providing an efficient mechanism for nutrient storage. Undoubtedly, the enzymatic processes required to achieve this ordered spatial positioning of branch linkages and extension of linear glucans must be highly regulated and coordinated.Mutations that alter or eliminate the cluster organization within amylopectin can provide clues to the molecular mechanisms that give rise to its structure. Such is the case with mutations of the maize su1 gene. Phytoglycogen, which accumulates in su1- mutant kernels, has twice the frequency of branch linkages as amylopectin, a shorter average chain length (average degree of polymerization is approximately 10 versus an average of 20–25 for amylopectin), and a significantly different chain-length distribution (Yun and Matheson, 1993). Thus, phytoglycogen is multiply branched and lacks the packed crystalline helices of amylopectin (Gunja-Smith et al., 1970; Alonso et al., 1995). These structural alterations cause the molecule to be water soluble, whereas amylopectin in endosperm cells is insoluble. Biochemical analysis has revealed that su1- mutants are deficient in the activity of a specific DBE (Pan and Nelson, 1984). This fact, correlated with the accumulation of phytoglycogen in su1- mutant kernels, suggests that the DBE participates in the organization of regularly spaced clusters within amylopectin. Similar evidence is available from sugary mutants of rice (Oryza sativa) and the STA-7 and STA-8 mutants of Chlamydomonas reinhardtii, all of which accumulate phytoglycogen and also are deficient in the activity of a DBE (Mouille et al., 1996a, 1996b; Nakamura et al., 1996a, 1996b).The two types of DBEs that have been identified in plants are classified as pullulanases (also referred to as R enzymes or limit dextrinases) and isoamylases (Lee and Whelan, 1971; Manners, 1971; Doehlert and Knutson, 1991). Both types of enzyme directly hydrolyze α-(1→6) branch linkages, but differ in their activities toward specific polysaccharides. Plant pullulanases hydrolyze both pullulan, a polymer of α-(1→6)-linked maltotriosyl units, and α-limit dextrins at much higher rates than amylopectin, but they have little or no hydrolytic activity toward glycogen. In contrast, isoamylases readily hydrolyze the α-(1→6) branch linkages of amylopectin and glycogen, but do not act on pullulan. The DBE shown to be missing in su1- mutants of maize and rice is of the pullulanase class (Nakamura et al., 1996b; Pan and Nelson, 1984).Both isoamylases and pullulanases are present in developing maize endosperm during the time of starch biosynthesis (Doehlert and Knutson, 1991), consistent with the genetic evidence indicating DBE involvement in the determination of amylopectin structure. The participation of a specific pullulanase or isoamylase in the biogenesis of kernel starch, however, has yet to be demonstrated directly. In addition to having potential biosynthetic functions, both types of DBE are believed to be involved in the degradation of endosperm starch after seed germination (Manners and Rowe, 1969; Toguri, 1991).Molecular cloning of the maize gene su1 and the Su1 cDNA revealed that its polypeptide product, SU1, is similar in amino acid sequence to members of the α-amylase family of starch-hydrolytic enzymes (Jesperson et al., 1993; James et al., 1995; Beatty et al., 1997). SU1 is significantly similar to Ps. isoamylase, with 32% identical residues among 695 aligned amino acids, although its relation to known plant or bacterial pullulanases is significantly less (James et al., 1995). This result is an apparent discrepancy with the finding that the particular DBE deficient in su1- mutant endosperm is of the pullulanase type (Pan and Nelson, 1984).To resolve this discrepancy and gain a better understanding of the role Su1 plays in starch biogenesis, this study made use of two recombinant forms of the SU1 protein. Antibodies specific for SU1 were produced and used to characterize its native size, aspects of its subcellular location, and its expression pattern in developing endosperm. In addition, a nearly native-size recombinant form of SU1 was expressed in Escherichia coli, purified, and characterized in terms of its enzymatic properties. The results clearly demonstrate that SU1 is an enzyme of the isoamylase class and indicate that at least two distinct DBEs are deficient in su1- mutants as a result of a primary deficiency of SU1 isoamylase. Furthermore, SU1 is expressed in maize kernels during the period of starch production, consistent with the proposed biosynthetic role for this DBE.     

Phenotypic consequences and genetic interactions of a null mutation in the Drosophila Posterior Sex Combs gene.

The Posterior Sex Combs (Psc) gene of Drosophila is a member of the Polycomb (Pc) group of transregulatory genes. Previous analyses of the function of this gene in Drosophila embryogenesis have been hampered by the lack of a null mutation. We recently isolated a mutation that deletes the 5' end of the Psc gene. This allele appears to be a null mutation, and we have used it to determine the Psc zygotic null phenotype and to look at the interactions of a null allele of Psc with five other Pc group mutations. We find evidence for transformations along both the anterior-posterior and dorsal-ventral axes in embryos of a variety of genotypes that include a null mutation in Psc. The phenotypes of embryos that are doubly mutant for a null allele of Psc and a mutation in a second Pc group gene show dramatic synergistic effects, but in their specifics they are dependent on the identity of the second Pc group gene. This is different from the relatively uniform phenotypes seen among double mutants that contained the allele Psc1, which has both gain and loss of function properties. The differences in the phenotypes of the doubly mutant embryos allow us to eliminate one class of molecular models to explain the dramatic synergism seen with mutations in this group of genes.     

Enzymatic properties and regulation of ZPU1, the maize pullulanase-type starch debranching enzyme

Starch debranching enzymes (DBE) are required for mobilization of carbohydrate reserves and for the normal structural organization of storage glucan polymers. Two isoforms, the pullulanase-type DBEs and the isoamylase-type DBEs, are both highly conserved in plants. To address DBE functions in starch assembly and breakdown, this study characterized the biochemical activity of ZPU1, a pullulanase-type DBE that is the product of the maize Zpu1 gene. Assays showed directly that recombinant ZPU1 (ZPU1r) expressed in Escherichia coli functions as a pullulanase-type enzyme, and 1H-NMR spectroscopy demonstrated that ZPU1r specifically hydrolyzes alpha(1-->6) branch linkages. Preferred substrates for ZPU1r hydrolytic activity were determined, as were pH, temperature, and thermal stability optima. Kinetic properties of ZPU1r with respect to two substrates, beta-limit dextrin and pullulan, were determined. ZPU1 activity was increased by incubation with thioredoxin h, and native activity was decreased in mutants that accumulate soluble sugars, suggesting potential regulatory mechanisms.     

Isolation of Su(var)3-7 mutations by homologous recombination in Drosophila melanogaster

The Su(var)3-7 gene, a haplo-suppressor and triplo-enhancer of position-effect variegation (PEV), encodes a zinc finger heterochromatin-associated protein. To understand the role of this protein in heterochromatin and genomic silencing, mutations were generated by homologous recombination. The donor fragment contained a yellow(+) gene and 7.6 kb of the Su(var)3-7 gene inserted between two FRTs. The Su(var)3-7 sequence contained three stop codons flanking an I-SceI cut site located in the 5' half of the gene. Using two different screening approaches, we obtained an allelic series composed of three mutant alleles. The three mutations are dominant suppressors of PEV. One behaves as a null mutation and results in a maternal-effect recessive lethal phenotype that can be rescued by a zygotic paternal wild-type gene. A P transposon zygotically expressing a Su(var)3-7 full-length cDNA also rescues the mutant phenotype. One hypomorphic allele is viable and the pleiotropic phenotype showed by adult flies indicates that rapidly and late dividing cells seem the most affected by reduced amounts of Su(var)3-7 protein. All three mutants were characterized at the molecular level. Each expresses a portion of the Su(var)3-7 protein that is unable to enter the nucleus and bind chromatin.     

Analysis of pyrimidine catabolism in Drosophila melanogaster using epistatic interactions with mutations of pyrimidine biosynthesis and beta-alanine metabolism

The biochemical pathway for pyrimidine catabolism links the pathways for pyrimidine biosynthesis and salvage with beta-alanine metabolism, providing an array of epistatic interactions with which to analyze mutations of these pathways. Loss-of-function mutations have been identified and characterized for each of the enzymes for pyrimidine catabolism: dihydropyrimidine dehydrogenase (DPD), su(r) mutants; dihydropyrimidinase (DHP), CRMP mutants; beta-alanine synthase (betaAS), pyd3 mutants. For all three genes, mutants are viable and fertile and manifest no obvious phenotypes, aside from a variety of epistatic interactions. Mutations of all three genes disrupt suppression by the rudimentary gain-of-function mutation (r(Su(b))) of the dark cuticle phenotype of black mutants in which beta-alanine pools are diminished; these results confirm that pyrimidines are the major source of beta-alanine in cuticle pigmentation. The truncated wing phenotype of rudimentary mutants is suppressed completely by su(r) mutations and partially by CRMP mutations; however, no suppression is exhibited by pyd3 mutations. Similarly, su(r) mutants are hypersensitive to dietary 5-fluorouracil, CRMP mutants are less sensitive, and pyd3 mutants exhibit wild-type sensitivity. These results are discussed in the context of similar consequences of 5-fluoropyrimidine toxicity and pyrimidine catabolism mutations in humans.     

The Drosophila melanogaster Suppressor of deltex gene, a regulator of the Notch receptor signaling pathway, is an E3 class ubiquitin ligase.

During development, the Notch receptor regulates many cell fate decisions by a signaling pathway that has been conserved during evolution. One positive regulator of Notch is Deltex, a cytoplasmic, zinc finger domain protein, which binds to the intracellular domain of Notch. Phenotypes resulting from mutations in deltex resemble loss-of-function Notch phenotypes and are suppressed by the mutation Suppressor of deltex [Su(dx)]. Homozygous Su(dx) mutations result in wing-vein phenotypes and interact genetically with Notch pathway genes. We have previously defined Su(dx) genetically as a negative regulator of Notch signaling. Here we present the molecular identification of the Su(dx) gene product. Su(dx) belongs to a family of E3 ubiquitin ligase proteins containing membrane-targeting C2 domains and WW domains that mediate protein-protein interactions through recognition of proline-rich peptide sequences. We have identified a seven-codon deletion in a Su(dx) mutant allele and we show that expression of Su(dx) cDNA rescues Su(dx) mutant phenotypes. Overexpression of Su(dx) also results in ectopic vein differentiation, wing margin loss, and wing growth phenotypes and enhances the phenotypes of loss-of-function mutations in Notch, evidence that supports the conclusion that Su(dx) has a role in the downregulation of Notch signaling.     

Phenotypic consequences and genetic interactions of a null mutation in the Drosophila posterior Sex Combs gene

The Posterior Sex Combs (Psc) gene of Drosophila is a member of the Polycomb (Pc) group of transregulatory genes. Previous analyses of the function of this gene in Drosophila em-bryogenesis have been hampered by the lack of a null mutation. We recently isolated a mutation that deletes the 5′ end of the Psc gene. This allele appears to be a null mutation, and we have used it to determine the Psc zygotic null phenotype and to look at the interactions of a null allele of Psc with five other Pc group mutations. We find evidence for transformations along both the anterior-posterior and dorsal-ventral axes in embryos of a variety of genotypes that include a null mutation in Psc. The phenotypes of embryos that are doubly mutant for a null allele of Psc and a mutation in a second Pc group gene show dramatic synergistic effects, but in their specifics they are dependent on the identify of the second Pc group gene. This is different from the relatively uniform phenotypes seen among double mutants that contained the allele Psc¹, which has both gain and loss of function properties. The differences in the phenotypes of the doubly mutant embryos allow us to eliminate one class of molecular models to explain the dramatic synergism seen with mutations in this group of genes.     

A genetic screen for maternal-effect suppressors of decapentaplegic identifies the eukaryotic translation initiation factor 4A in Drosophila

The Dpp signaling pathway is essential for many developmental processes in Drosophila and its activity is tightly regulated. To identify additional regulators of Dpp signaling, we conducted a genetic screen for maternal-effect suppressors of dpp haplo-insufficiency. We screened approximately 7000 EMS-mutagenized genomes and isolated and mapped seven independent dominant suppressors of dpp, Su(dpp), which were recovered as second-site mutations that resulted in viable flies in trans-heterozygous with dpp(H46), a dpp null allele. Most of the Su(dpp) mutants exhibited increased cell numbers of the amnioserosa, a cell type specified by the Dpp pathway, suggesting that these mutations may augment Dpp signaling activity. Here we report the unexpected identification of one of the Su(dpp) mutations as an allele of the eukaryotic translation initiation factor 4A (eIF4A). We show that Su(dpp)(YE9) maps to eIF4A and that this allele is associated with a substitution, arginine 321 to histidine, at a well-conserved amino acid and behaves genetically as a dominant-negative mutation. This result provides an intriguing link between a component of the translation machinery and Dpp signaling.     

Central role of Drosophila SU(VAR)3-9 in histone H3-K9 methylation and heterochromatic gene silencing

Su(var)3-9 is a dominant modifier of heterochromatin-induced gene silencing. Like its mammalian and Schizosaccharomyces pombe homologues, Su(var) 3-9 encodes a histone methyltransferase (HMTase), which selectively methylates histone H3 at lysine 9 (H3-K9). In Su(var)3-9 null mutants, H3-K9 methylation at chromocentre heterochromatin is strongly reduced, indicating that SU(VAR)3-9 is the major heterochromatin-specific HMTase in Drosophila. SU (VAR)3-9 interacts with the heterochromatin-associated HP1 protein and with another silencing factor, SU(VAR)3-7. Notably, SU(VAR)3-9-HP1 interaction is interdependent and governs distinct localization patterns of both proteins. In Su(var)3-9 null mutants, concentration of HP1 at the chromocentre is nearly lost without affecting HP1 accumulation at the fourth chromosome. By contrast, in HP1 null mutants SU(VAR)3-9 is no longer restricted at heterochromatin but broadly dispersed across the chromosomes. Despite this interdependence, Su(var)3-9 dominates the PEV modifier effects of HP1 and Su(var)3-7 and is also epistatic to the Y chromosome effect on PEV. Finally, the human SUV39H1 gene is able to partially rescue Su(var)3-9 silencing defects. Together, these data indicate a central role for the SU(VAR)3-9 HMTase in heterochromatin-induced gene silencing in Drosophila.     

Molecular and Genetic Organization of the Suppressor of Sable and Minute(1)1b Region in Drosophila Melanogaster

Recessive mutations at the suppressor of sable [su(s)] locus in Drosophila melanogaster result in suppression of second site mutations caused by insertions of the mobile element 412. In order to determine whether su(s) mutations might have other phenotypes, a saturation mapping of the su(s) region was carried out. The screen yielded 76 mutations that comprise ten genetic complementation groups ordered distal to proximal as follows: l(1)1Bh, l(1)1Bi, M(1)1B, su(s), l(1)1Bk, l(1)1Ca, mul, tw, l(1)lDa and brc. Twenty-three of the mutations are su(s) alleles, and all are suppressors of the 412-insertion-caused v1 allele. Although the screen could have detected su(s) mutations causing sex-specific dominant lethality or sterility as well as all types of recessive lethality or sterility, the only other phenotype observed was male sterility that is enhanced by cold temperature. This type of sterility is exhibited only by alleles induced by base-substitution-causing mutagens. Genetic functions of the poly(A+) messages transcribed from the su(s) microregion were identified by the reintroduction of cloned sequences into embryos by P element transformation. su(s) function has been attributed to a 5-kb message. The segment of DNA encoding only this 5-kb message rescues both the suppression and cold-sensitive male sterility phenotypes of su(s). Minute (1) 1B has been provisionally identified as encoding a 3.5-kb message; lethal (1)1Bi encodes a 1-kb message; and lethal (1)1Bk encodes a 4-kb message. The possible functions of su(s) and M(1)1B are discussed.