Your search keyword '"Samuel C. Zeeman"' showing total 142 results

101. The control of amylose synthesis

Author

Alison M. Smith, Samuel C. Zeeman, Philip E. Johnson, and Kay Denyer

Subjects

Gene isoform, biology, Physiology, Starch, food and beverages, Plant Science, Isozyme, carbohydrates (lipids), chemistry.chemical_compound, chemistry, Biosynthesis, Biochemistry, Amylose, Amylopectin, Glycosyltransferase, biology.protein, Starch synthase, Agronomy and Crop Science

Abstract

Summary Starch granules are composed of two types of glucose polymer, amylose and amylopectin, that differ in size and structure. One of the most intriguing challenges in understanding starch synthesis is to explain the apparently simultaneous synthesis of two such different polymers. One isoform of starch synthase, GBSSI, is responsible for amylose synthesis but can also contribute to amylopectin synthesis. The factors which determine the partitioning of GBSSI activity between these two processes are largely unknown. Understanding the properties of GBSSI and how these differ from the properties of the amylopectin-synthesising isoforms of starch synthase are important to the understanding of the control of amylose synthesis. In this review, we will describe how the synthesis of amylose and amylopectin are integrated and what factors may determine the relative amounts of these two polymers.

Published

2001

102. Changes in carbohydrate metabolism and assimilate export in starch‐excess mutants of Arabidopsis

Author

T. ap Rees and Samuel C. Zeeman

Subjects

Sucrose, Physiology, Starch, Mutant, Wild type, food and beverages, Plant Science, Biology, Carbohydrate metabolism, Photosynthesis, biology.organism_classification, Chloroplast, chemistry.chemical_compound, chemistry, Biochemistry, Arabidopsis thaliana

Abstract

The aim of this work was to investigate the effects on carbohydrate metabolism of a reduction in tbe capacity to degrade leaf starch in Arabidopsis. The major roles of leaf starch are to provide carbon for sucrose synthesis, respiration and, in developing leaves, for biosynthesis and growth. Wild-type plants were compared with plants of a starch-excess mutant line (sex4) deficient in a chloroplastic isoform of endoamylase. This mutant has a reduced capacity for starch degradation, leading to an imbalance between starch synthesis and degradation and the gradual accretion of starch as the leaves age. During the night the conversion of starch into sucrose in the mutant is impaired; the leaves of the mutant contained less sucrose than those of the wild type and there was less movement of 14 C-label from starch to sucrose in radio-labelling experiments. Furthermore, the rate of assimilate export to tbe roots during the night was reduced in the mutant compared with the wild type. During the day however, photosynthetic partitioning was altered in the mutant, with less photosynthate partitioned into starch and more into sugars. Although the sucrose content of the leaves of the mutant was similar to the wild type during the day, the rate of export of sucrose to the roots was increased more than two-fold. The changes in carbohydrate metabolism in the mutant leaves during the day compensate partly for its reduced capacity to synthesize sucrose from starch during the night.

Published

1999

103. A starch‐accumulating mutant of Arabidopsis thaliana deficient in a chloroplastic starch‐hydrolysing enzyme

Author

Alison M. Smith, Samuel C. Zeeman, Fred D. Northrop, and Tom ap Rees

Subjects

Chloroplasts, Starch phosphorylase, Pullulanase, biology, Starch, Hydrolysis, Mutant, Arabidopsis, food and beverages, Cell Biology, Plant Science, biology.organism_classification, Circadian Rhythm, Chloroplast, chemistry.chemical_compound, chemistry, Biochemistry, Amylopectin, Amylases, Mutation, Genetics, Arabidopsis thaliana, Electrophoresis, Polyacrylamide Gel, Maltase

Abstract

The aim of this work was to identify enzymes that participate in the degradation of transitory starch in Arabidopsis. A mutant line was isolated by screening leaves at the end of the night for the presence of starch. The mutant had a higher starch content than the wild-type throughout the diurnal cycle. This accumulation was due to a reduction in starch breakdown, leading to an imbalance between the rates of synthesis and degradation. No reduction in the activity of endo-amylase (alpha-amylase), beta-amylase, starch phosphorylase, maltase, pullulanase or D-enzyme could be detected in crude extracts of leaves of the mutant. However, native PAGE in gels containing amylopectin revealed that a starch-hydrolysing activity, putatively identified as an endo-amylase and present in wild-type chloroplasts, was absent or appreciably reduced in the mutant. This is the first time that a specific enzyme required for starch degradation has been identified in leaves.

Published

1998

104. Starch synthase 4 is essential for coordination of starch granule formation with chloroplast division during Arabidopsis leaf expansion

Author

Matilda Crumpton-Taylor, Alison M. Smith, Christopher M. Hylton, Marilyn J. Pike, Regina Feil, Kuan-Jen Lu, John E. Lunn, Simona Eicke, and Samuel C. Zeeman

Subjects

0106 biological sciences, Heterozygote, Chloroplasts, Arabidopsis thaliana, Physiology, Starch, leaf expansion, Mutant, Arabidopsis, Agrobacterium, Plant Science, 01 natural sciences, Isozyme, starch synthase, Adenosine Diphosphate Glucose, 03 medical and health sciences, chemistry.chemical_compound, chloroplast, Glycogen synthase, Glucans, starch synthesis, 030304 developmental biology, 0303 health sciences, biology, Arabidopsis Proteins, Research, Granule (cell biology), food and beverages, ADPglucose, Chloroplast, Leaf expansion, Starch granule, Starch synthase, Starch synthesis, biology.organism_classification, Isoenzymes, Plant Leaves, Glycogen Synthase, Biochemistry, chemistry, Solubility, Mutation, Organelle Size, biology.protein, Metabolome, RNA Interference, starch granule, 010606 plant biology & botany

Abstract

Arabidopsis thaliana mutants lacking the SS4 isoform of starch synthase have strongly reduced numbers of starch granules per chloroplast, suggesting that SS4 is necessary for the normal generation of starch granules. To establish whether it plays a direct role in this process, we investigated the circumstances in which granules are formed in ss4 mutants. Starch granule numbers and distribution and the accumulation of starch synthase substrates and products were investigated during ss4 leaf development, and in ss4 mutants carrying mutations or transgenes that affect starch turnover or chloroplast volume. We found that immature ss4 leaves have no starch granules, but accumulate high concentrations of the starch synthase substrate ADPglucose. Granule numbers are partially restored by elevating the capacity for glucan synthesis (via expression of bacterial glycogen synthase) or by increasing the volumes of individual chloroplasts (via introduction of arc mutations). However, these granules are abnormal in distribution, size and shape. SS4 is an essential component of a mechanism that coordinates granule formation with chloroplast division during leaf expansion and determines the abundance and the flattened, discoid shape of leaf starch granules., New Phytologist, 200 (4), ISSN:0028-646X, ISSN:1469-8137

Published

2013

105. Nighttime Sugar Starvation Orchestrates Gibberellin Biosynthesis and Plant Growth in Arabidopsis

Author

Pierdomenico Perata, Giacomo Novi, Joost T. van Dongen, Nello Ceccarelli, Lorenzo Mariotti, Silvia Gonzali, Katharina Kölling, Sandro Parlanti, Eleonora Paparelli, and Samuel C. Zeeman

Subjects

Photoperiod, Arabidopsis, Plant Science, Biology, Carbohydrate metabolism, Photosynthetic efficiency, Photosynthesis, Plant Growth Regulators, Botany, Arabidopsis thaliana, Sugar, Research Articles, Alkyl and Aryl Transferases, Arabidopsis Proteins, fungi, food and beverages, Starch, Cell Biology, Darkness, Plants, Genetically Modified, biology.organism_classification, Gibberellins, Gene Knockdown Techniques, Carbohydrate Metabolism, Gibberellin, Plant hormone

Abstract

A plant's eventual size depends on the integration of its genetic program with environmental cues, which vary on a daily basis. Both efficient carbon metabolism and the plant hormone gibberellin are required to guarantee optimal plant growth. Yet, little is known about the interplay between carbon metabolism and gibberellins that modulates plant growth. Here, we show that sugar starvation in Arabidopsis thaliana arising from inefficient starch metabolism at night strongly reduces the expression of ent-kaurene synthase, a key regulatory enzyme for gibberellin synthesis, the following day. Our results demonstrate that plants integrate the efficiency of photosynthesis over a period of days, which is transduced into a daily rate of gibberellin biosynthesis. This enables a plant to grow to a size that is compatible with its environment.

Published

2013

106. Discovery, characterization, and structural analyses of glucan phosphatases from plants to humans

Author

Diana Santelia, Oliver Kötting, Samuel C. Zeeman, Adam Taylor, Matthew S. Gentry, David A. Meekins, and Craig W. Vander Kooi

Subjects

chemistry.chemical_classification, Biochemistry, Chemistry, Phosphatase, Genetics, Molecular Biology, Biotechnology, Glucan

Published

2012

107. Mutagenesis of cysteine 81 prevents dimerization of the APS1 subunit of ADP-glucose pyrophosphorylase and alters diurnal starch turnover in Arabidopsis thaliana leaves

Author

Regina Feil, John E. Lunn, Oliver Kötting, Nadja Hädrich, Mark Stitt, Janneke H.M. Hendriks, Waltraud X. Schulze, Samuel C. Zeeman, Yves Gibon, Stéphanie Arrivault, Max Planck Institute of Molecular Plant Physiology (MPI-MP), Max-Planck-Gesellschaft, Department of Biology, Biologie du fruit et pathologie (BFP), and Université Sciences et Technologies - Bordeaux 1-Université Bordeaux Segalen - Bordeaux 2-Institut National de la Recherche Agronomique (INRA)

Subjects

0106 biological sciences, Arabidopsis thaliana, Starch, Protein subunit, Photoperiod, Immunoblotting, Molecular Sequence Data, Arabidopsis, Plant Science, Glucose-1-Phosphate Adenylyltransferase, Biology, 01 natural sciences, Serine, Adenosine Diphosphate Glucose, 03 medical and health sciences, chemistry.chemical_compound, ADP-glucose pyrophosphorylase, Genetics, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Site-directed mutagenesis, Maltose, cysteine, 030304 developmental biology, 0303 health sciences, Base Sequence, Arabidopsis Proteins, starch, food and beverages, Cell Biology, thioredoxin, biology.organism_classification, Circadian Rhythm, Plant Leaves, Protein Subunits, Biochemistry, chemistry, Mutation, Mutagenesis, Site-Directed, Thioredoxin, Protein Multimerization, site-directed mutagenesis, Oxidation-Reduction, 010606 plant biology & botany, Cysteine

Abstract

International audience; Many plants, including Arabidopsis thaliana, retain a substantial portion of their photosynthate in leaves in the form of starch, which is remobilized to support metabolism and growth at night. ADP-glucose pyrophosphorylase (AGPase) catalyses the first committed step in the pathway of starch synthesis, the production of ADP-glucose. The enzyme is redox-activated in the light and in response to sucrose accumulation, via reversible breakage of an intermolecular cysteine bridge between the two small (APS1) subunits. The biological function of this regulatory mechanism was investigated by complementing an aps1 null mutant (adg1) with a series of constructs containing a full-length APS1 gene encoding either the wild-type APS1 protein or mutated forms in which one of the five cysteine residues was replaced by serine. Substitution of Cys81 by serine prevented APS1 dimerization, whereas mutation of the other cysteines had no effect. Thus, Cys81 is both necessary and sufficient for dimerization of APS1. Compared to control plants, the adg1/APS1C81S lines had higher levels of ADP-glucose and maltose, and either increased rates of starch synthesis or a starch-excess phenotype, depending on the daylength. APS1 protein levels were five- to tenfold lower in adg1/APS1C81S lines than in control plants. These results show that redox modulation of AGPase contributes to the diurnal regulation of starch turnover, with inappropriate regulation of the enzyme having an unexpected impact on starch breakdown, and that Cys81 may play an important role in the regulation of AGPase turnover.

Published

2012

108. Analysis of starch metabolism in chloroplasts

Author

Carmen, Hostettler, Katharina, Kölling, Diana, Santelia, Sebastian, Streb, Oliver, Kötting, and Samuel C, Zeeman

Subjects

Plant Leaves, Chloroplasts, Staining and Labeling, Amylopectin, Arabidopsis, Starch, Amylose, Chemistry Techniques, Analytical, Iodine, Phosphates

Abstract

Starch is a primary product of photosynthesis in the chloroplasts of many higher plants. It plays an important role in the day-to-day carbohydrate metabolism of the leaf, and its biosynthesis and degradation represent major fluxes in plant metabolism. Starch serves as a transient reserve of carbohydrate which is used to support respiration, metabolism, and growth at night when there is no production of energy and reducing power through photosynthesis, and no net assimilation of carbon. The chapter includes techniques to measure starch amount and its rate of biosynthesis, to determine its structure and composition, and to monitor its turnover. These methods can be used to investigate transitory starch metabolism in Arabidopsis, where they can be applied in combination with genetics and systems-level approaches to yield new insight into the control of carbon allocation generally, and starch metabolism specifically. The methods can also be applied to the leaves of other plants with minimal modifications.

Published

2011

109. Starch-binding domains in the CBM45 family--low-affinity domains from glucan, water dikinase and α-amylase involved in plastidial starch metabolism

Author

Mikkel A, Glaring, Martin J, Baumann, Maher, Abou Hachem, Hiroyuki, Nakai, Natsuko, Nakai, Diana, Santelia, Bent W, Sigurskjold, Samuel C, Zeeman, Andreas, Blennow, and Birte, Svensson

Subjects

Recombinant Fusion Proteins, Molecular Sequence Data, Arabidopsis, Receptors, Cell Surface, Starch, Calorimetry, Surface Plasmon Resonance, Protein Structure, Tertiary, Tobacco, Amino Acid Sequence, Plastids, alpha-Amylases, Glucans, Sequence Alignment, Plant Proteins, Protein Binding, Solanum tuberosum

Abstract

Starch-binding domains are noncatalytic carbohydrate-binding modules that mediate binding to granular starch. The starch-binding domains from the carbohydrate-binding module family 45 (CBM45, http://www.cazy.org) are found as N-terminal tandem repeats in a small number of enzymes, primarily from photosynthesizing organisms. Isolated domains from representatives of each of the two classes of enzyme carrying CBM45-type domains, the Solanum tuberosumα-glucan, water dikinase and the Arabidopsis thaliana plastidial α-amylase 3, were expressed as recombinant proteins and characterized. Differential scanning calorimetry was used to verify the conformational integrity of an isolated CBM45 domain, revealing a surprisingly high thermal stability (T(m) of 84.8 °C). The functionality of CBM45 was demonstrated in planta by yellow/green fluorescent protein fusions and transient expression in tobacco leaves. Affinities for starch and soluble cyclodextrin starch mimics were measured by adsorption assays, surface plasmon resonance and isothermal titration calorimetry analyses. The data indicate that CBM45 binds with an affinity of about two orders of magnitude lower than the classical starch-binding domains from extracellular microbial amylolytic enzymes. This suggests that low-affinity starch-binding domains are a recurring feature in plastidial starch metabolism, and supports the hypothesis that reversible binding, effectuated through low-affinity interaction with starch granules, facilitates dynamic regulation of enzyme activities and, hence, of starch metabolism.

Published

2011

110. Analysis of Starch Metabolism in Chloroplasts

Author

Sebastian Streb, Carmen Hostettler, Oliver Kötting, Samuel C. Zeeman, Katharina Kölling, and Diana Santelia

Subjects

biology, Starch, fungi, food and beverages, Assimilation (biology), Metabolism, Carbohydrate metabolism, Carbohydrate, biology.organism_classification, Photosynthesis, Chloroplast, chemistry.chemical_compound, Biochemistry, chemistry, Arabidopsis, Botany

Abstract

Starch is a primary product of photosynthesis in the chloroplasts of many higher plants. It plays an important role in the day-to-day carbohydrate metabolism of the leaf, and its biosynthesis and degradation represent major fluxes in plant metabolism. Starch serves as a transient reserve of carbohydrate which is used to support respiration, metabolism, and growth at night when there is no production of energy and reducing power through photosynthesis, and no net assimilation of carbon. The chapter includes techniques to measure starch amount and its rate of biosynthesis, to determine its structure and composition, and to monitor its turnover. These methods can be used to investigate transitory starch metabolism in Arabidopsis, where they can be applied in combination with genetics and systems-level approaches to yield new insight into the control of carbon allocation generally, and starch metabolism specifically. The methods can also be applied to the leaves of other plants with minimal modifications.

Published

2011

111. Progress in Arabidopsis starch research and potential biotechnological applications

Author

Diana Santelia and Samuel C. Zeeman

Subjects

biology, Starch, business.industry, fungi, Starch metabolism, Biomedical Engineering, Arabidopsis, food and beverages, Bioengineering, Starch degradation, biology.organism_classification, Starch biosynthesis, Biotechnology, chemistry.chemical_compound, chemistry, Gene Expression Regulation, Plant, Botany, business

Abstract

For the past decade, Arabidopsis has been the model higher plant of choice. Research into leaf starch metabolism has demonstrated that Arabidopsis is a useful system in which to make fundamental discoveries about both starch biosynthesis and starch degradation. This review describes recent discoveries in these fields and illustrates how such discoveries might be applied in the green biotechnology sector to improve and diversify our starch crops.

Published

2010

112. Starch: its metabolism, evolution, and biotechnological modification in plants

Author

Alison M. Smith, Jens Kossmann, and Samuel C. Zeeman

Subjects

Glycogen, Physiology, Starch, Amylopectin, food and beverages, Cell Biology, Plant Science, Carbohydrate metabolism, Biology, Carbohydrate, Plants, Biological Evolution, Endosperm, Biosynthetic Pathways, Plant Leaves, chemistry.chemical_compound, chemistry, Biochemistry, Energy source, Molecular Biology, Renewable resource, Biotechnology

Abstract

Starch is the most widespread and abundant storage carbohydrate in plants. We depend upon starch for our nutrition, exploit its unique properties in industry, and use it as a feedstock for bioethanol production. Here, we review recent advances in research in three key areas. First, we assess progress in identifying the enzymatic machinery required for the synthesis of amylopectin, the glucose polymer responsible for the insoluble nature of starch. Second, we discuss the pathways of starch degradation, focusing on the emerging role of transient glucan phosphorylation in plastids as a mechanism for solubilizing the surface of the starch granule. We contrast this pathway in leaves with the degradation of starch in the endosperm of germinated cereal seeds. Third, we consider the evolution of starch biosynthesis in plants from the ancestral ability to make glycogen. Finally, we discuss how this basic knowledge has been utilized to improve and diversify starch crops.

Published

2010

113. The Laforin-like dual-specificity phosphatase SEX4 from Arabidopsis hydrolyzes both C6- and C3-phosphate esters introduced by starch-related dikinases and thereby affects phase transition of alpha-glucans

Author

Oliver Kötting, Joerg Fettke, Samuel C. Zeeman, Martin Steup, and Mahdi Hejazi

Subjects

Physiology, Starch, Phosphatase, Arabidopsis, Plant Science, Dephosphorylation, chemistry.chemical_compound, Dual-specificity phosphatase, Genetics, Phosphorylation, Glucans, Institut für Biochemie und Biologie, Glucan, chemistry.chemical_classification, biology, Arabidopsis Proteins, food and beverages, Phosphate, chemistry, Biochemistry, biology.protein, Dual-Specificity Phosphatases, Laforin, Research Article

Abstract

The biochemical function of the Laforin-like dual-specific phosphatase AtSEX4 (EC 3.1.3.48) has been studied. Crystalline maltodextrins representing the A- or the B-type allomorph were prephosphorylated using recombinant glucan, water dikinase (StGWD) or the successive action of both plastidial dikinases (StGWD and AtPWD). AtSEX4 hydrolyzed carbon 6-phosphate esters from both the prephosphorylated A- and B-type allomorphs and the kinetic constants are similar. The phosphatase also acted on prelabeled carbon-3 esters from both crystalline maltodextrins. Similarly, native starch granules prelabeled in either the carbon-6 or carbon-3 position were also dephosphorylated by AtSEX4. The phosphatase did also hydrolyze phosphate esters of both prephosphorylated maltodextrins when the (phospho)glucans had been solubilized by heat treatment. Submillimolar concentrations of nonphosphorylated maltodextrins inhibited AtSEX4 provided they possessed a minimum of length and had been solubilized. As opposed to the soluble phosphomaltodextrins, the AtSEX4-mediated dephosphorylation of the insoluble substrates was incomplete and at least 50% of the phosphate esters were retained in the pelletable (phospho)glucans. The partial dephosphorylation of the insoluble glucans also strongly reduced the release of nonphosphorylated chains into solution. Presumably, this effect reflects fast structural changes that following dephosphorylation occur near the surface of the maltodextrin particles. A model is proposed defining distinct stages within the phosphorylation/dephosphorylation-dependent transition of α-glucans from the insoluble to the soluble state.

Published

2009

114. Drought tolerance of two black poplar (Populus nigra L.) clones: contribution of carbohydrates and oxidative stress defence

Author

Marcus Schaub, Paolo Cherubini, Claudia Cocozza, Sebastian Streb, Samuel C. Zeeman, Nicole Regier, and Beat Frey

Subjects

Genotype, Physiology, Drought tolerance, Plant Science, Carbohydrate metabolism, Photosynthesis, Black poplar, Plant Roots, Salicaceae, Gene Expression Regulation, Plant, Botany, biology, Superoxide Dismutase, fungi, food and beverages, Plant physiology, Water, biology.organism_classification, Droughts, Oxidative Stress, Phenotype, Populus, RNA, Plant, Shoot, Plant Stomata, Carbohydrate Metabolism, Reactive Oxygen Species, Plant Shoots, Woody plant

Abstract

Drought is expected to become an increasingly important factor limiting tree growth caused by climate change. Two divergent clones of Populus nigra (58-861 and Poli) originating from contrasting environments were subjected to water limitation (WL) to elucidate whether they differ in tolerance to drought, which mechanisms to avoid stress they exhibit and whether drought has an impact on the interactions between roots and shoots. Limiting water availability caused photosynthetic rate and total non-structural carbohydrate (TNC) levels to decrease in 58-861. However, starch-degrading enzyme activity and gene expression were induced in roots, and soluble sugar levels were higher than in well-watered (WW) plants. These data suggest that assimilation and partitioning of carbon to the roots are decreased, resulting in mobilization of stored starch. In contrast, the photosynthetic rate of Poli was reduced only late in the treatment, and carbohydrate levels in WL plants were higher than in WW plants. Superoxide dismutase (SOD) activity and gene expression were higher in Poli than in 58-861, even in WW plants, leading to a higher capacity to defend against oxidative stress.

Published

2009

115. Starch granule biosynthesis in Arabidopsis is abolished by removal of all debranching enzymes but restored by the subsequent removal of an endoamylase

Author

Didier Reinhardt, Samuel C. Zeeman, Martine Schorderet, Simona Eicke, Thierry Delatte, Sebastian Streb, and Martin Umhang

Subjects

Glycoside Hydrolases, Amylopectin, Mutant, Arabidopsis, Oligosaccharides, Plant Science, chemistry.chemical_compound, Biosynthesis, Spectroscopy, Fourier Transform Infrared, Arabidopsis thaliana, Maltose, Research Articles, chemistry.chemical_classification, biology, Phytoglycogen, Cryoelectron Microscopy, food and beverages, Starch, Cell Biology, Plants, Genetically Modified, biology.organism_classification, carbohydrates (lipids), Enzyme, chemistry, Biochemistry, alpha-Amylases, Isoamylase

Abstract

Several studies have suggested that debranching enzymes (DBEs) are involved in the biosynthesis of amylopectin, the major constituent of starch granules. Our systematic analysis of all DBE mutants of Arabidopsis thaliana demonstrates that when any DBE activity remains, starch granules are still synthesized, albeit with altered amylopectin structure. Quadruple mutants lacking all four DBE proteins (Isoamylase1 [ISA1], ISA2, and ISA3, and Limit-Dextrinase) are devoid of starch granules and instead accumulate highly branched glucans, distinct from amylopectin and from previously described phytoglycogen. A fraction of these glucans are present as discrete, insoluble, nanometer-scale particles, but the structure and properties of this material are radically altered compared with wild-type amylopectin. Superficially, these data support the hypothesis that debranching is required for amylopectin synthesis. However, our analyses show that soluble glucans in the quadruple DBE mutant are degraded by α- and β-amylases during periods of net accumulation, giving rise to maltose and branched malto-oligosaccharides. The additional loss of the chloroplastic α-amylase AMY3 partially reverts the phenotype of the quadruple DBE mutant, restoring starch granule biosynthesis. We propose that DBEs function in normal amylopectin synthesis by promoting amylopectin crystallization but conclude that they are not mandatory for starch granule synthesis.

Published

2009

116. STARCH-EXCESS4 is a laforin-like phosphoglucan phosphatase required for starch degradation in Arabidopsis thaliana

Author

Oliver Kötting, Samuel C. Zeeman, Jychian Chen, Simona Eicke, Martin Steup, Tina Marthaler, Matthew S. Gentry, Alison M. Smith, Diana Santelia, Sylviane Comparot-Moss, Christoph Edner, and Gerhard Ritte

Subjects

DNA, Bacterial, Starch, Phosphatase, Arabidopsis, Plant Science, macromolecular substances, Dephosphorylation, chemistry.chemical_compound, Isoamylase, Phosphorylation, Glucans, Research Articles, Institut für Biochemie und Biologie, Glucan, chemistry.chemical_classification, biology, Arabidopsis Proteins, food and beverages, Cell Biology, Carbohydrate, Recombinant Proteins, Mutagenesis, Insertional, Biochemistry, chemistry, biology.protein, Carbohydrate Metabolism, Protein Tyrosine Phosphatases, Alpha-amylase, Laforin

Abstract

Starch is the major storage carbohydrate in plants. It is comprised of glucans that form semicrystalline granules. Glucan phosphorylation is a prerequisite for normal starch breakdown, but phosphoglucan metabolism is not understood. A putative protein phosphatase encoded at the Starch Excess 4 (SEX4) locus of Arabidopsis thaliana was recently shown to be required for normal starch breakdown. Here, we show that SEX4 is a phosphoglucan phosphatase in vivo and define its role within the starch degradation pathway. SEX4 dephosphorylates both the starch granule surface and soluble phosphoglucans in vitro, and sex4 null mutants accumulate phosphorylated intermediates of starch breakdown. These compounds are linear α-1,4-glucans esterified with one or two phosphate groups. They are released from starch granules by the glucan hydrolases α-amylase and isoamylase. In vitro experiments show that the rate of starch granule degradation is increased upon simultaneous phosphorylation and dephosphorylation of starch. We propose that glucan phosphorylating enzymes and phosphoglucan phosphatases work in synergy with glucan hydrolases to mediate efficient starch catabolism.

Published

2009

117. Beta-AMYLASE4, a noncatalytic protein required for starch breakdown, acts upstream of three active beta-amylases in Arabidopsis chloroplasts

Author

Samuel C. Zeeman, Jing Li, Michaela Stettler, Gary Dorken, Manuel Gil, Daniel C. Fulton, Karen J. Halliday, Alison M. Smith, Cara K. Vaughan, Gaëlle Messerli, Tabea Mettler, Heike Reinhold, Steven M. Smith, Perigio Francisco, and Simona Eicke

Subjects

Chloroplasts, Starch, Molecular Sequence Data, Mutant, Arabidopsis, beta-Amylase, Plant Science, Catalysis, chemistry.chemical_compound, Escherichia coli, Arabidopsis thaliana, Amino Acid Sequence, Amylase, Research Articles, DNA Primers, Base Sequence, Sequence Homology, Amino Acid, biology, Wild type, food and beverages, Cell Biology, Maltose, biology.organism_classification, Recombinant Proteins, Chloroplast, Microscopy, Fluorescence, Biochemistry, chemistry, biology.protein, Alpha-amylase

Abstract

This work investigated the roles of β-amylases in the breakdown of leaf starch. Of the nine β-amylase (BAM)–like proteins encoded in the Arabidopsis thaliana genome, at least four (BAM1, -2, -3, and -4) are chloroplastic. When expressed as recombinant proteins in Escherichia coli, BAM1, BAM2, and BAM3 had measurable β-amylase activity but BAM4 did not. BAM4 has multiple amino acid substitutions relative to characterized β-amylases, including one of the two catalytic residues. Modeling predicts major differences between the glucan binding site of BAM4 and those of active β-amylases. Thus, BAM4 probably lost its catalytic capacity during evolution. Total β-amylase activity was reduced in leaves of bam1 and bam3 mutants but not in bam2 and bam4 mutants. The bam3 mutant had elevated starch levels and lower nighttime maltose levels than the wild type, whereas bam1 did not. However, the bam1 bam3 double mutant had a more severe phenotype than bam3, suggesting functional overlap between the two proteins. Surprisingly, bam4 mutants had elevated starch levels. Introduction of the bam4 mutation into the bam3 and bam1 bam3 backgrounds further elevated the starch levels in both cases. These data suggest that BAM4 facilitates or regulates starch breakdown and operates independently of BAM1 and BAM3. Together, our findings are consistent with the proposal that β-amylase is a major enzyme of starch breakdown in leaves, but they reveal unexpected complexity in terms of the specialization of protein function.

Published

2008

118. The synthesis of amylose

Author

Kay Denyer, Alison M. Smith, T. L. Barsby, P. J. Frazier, Samuel C. Zeeman, and Athene M. Donald

Subjects

chemistry.chemical_compound, chemistry, Starch, Amylose, Amylopectin, Food science

Published

2007

119. The synthesis and degradation of starch in Arabidopsis leaves: The role of disproportionating enzyme

Author

Steven M. Smith, Athene M. Donald, Samuel C. Zeeman, Takeshi Takaha, Alison M. Smith, Joanna Critchley, P. J. Frazier, and T. L. Barsby

Subjects

chemistry.chemical_classification, biology, Starch, Metabolism, biology.organism_classification, Enzyme assay, chemistry.chemical_compound, Enzyme, Biochemistry, chemistry, Amylose, Arabidopsis, Amylopectin, biology.protein, Arabidopsis thaliana

Published

2007

120. Similar protein phosphatases control starch metabolism in plants and glycogen metabolism in mammals

Author

Totte Niittylä, Steven M. Smith, Samuel C. Zeeman, John A. Gatehouse, Michael D.J. Seymour, Sylviane Comparot-Moss, Jychian Chen, Alison M. Smith, Gaëlle Messerli, Dorthe Villadsen, Martine Trevisan, and Wei-Ling Lue

Subjects

Chloroplasts, Starch, Phosphatase, Arabidopsis, Biology, Biochemistry, Lafora disease, chemistry.chemical_compound, medicine, Phosphoprotein Phosphatases, Animals, Humans, Protein phosphorylation, Phosphorylation, Molecular Biology, Glucans, Mammals, Glycogen, Arabidopsis Proteins, food and beverages, Cell Biology, Metabolism, medicine.disease, Plant Leaves, chemistry, Laforin

Abstract

We report that protein phosphorylation is involved in the control of starch metabolism in Arabidopsis leaves at night. sex4 (starch excess 4) mutants, which have strongly reduced rates of starch metabolism, lack a protein predicted to be a dual specificity protein phosphatase. We have shown that this protein is chloroplastic and can bind to glucans and have presented evidence that it acts to regulate the initial steps of starch degradation at the granule surface. Remarkably, the most closely related protein to SEX4 outside the plant kingdom is laforin, a glucan-binding protein phosphatase required for the metabolism of the mammalian storage carbohydrate glycogen and implicated in a severe form of epilepsy (Lafora disease) in humans.

Published

2006

121. Evidence for distinct mechanisms of starch granule breakdown in plants

Author

Martin Umhang, Steven M. Smith, Thierry Delatte, David Thorneycroft, Martine Trevisan, Simona Eicke, and Samuel C. Zeeman

Subjects

Chloroplasts, Glycoside Hydrolases, Starch, Mutant, Amylopectin, Arabidopsis, Biology, Biochemistry, Endosperm, Glycogen debranching enzyme, chemistry.chemical_compound, Dextrins, Isoamylase, Limit dextrinase, Molecular Biology, Glucans, food and beverages, Cell Biology, Chloroplast, Plant Leaves, Phenotype, chemistry, Mutation

Abstract

The aim of this work was to understand the initial steps of starch breakdown inside chloroplasts. In the non-living endosperm of germinating cereal grains, starch breakdown is initiated by alpha-amylase secreted from surrounding cells. However, loss of alpha-amylase from Arabidopsis does not prevent chloroplastic starch breakdown (Yu, T.-S., Zeeman, S. C., Thorneycroft, D., Fulton, D. C., Dunstan, H., Lue, W.-L., Hegemann, B., Tung, S.-Y., Umemoto, T., Chapple, A., Tsai, D.-L., Wang, S.-M, Smith, A. M., Chen, J., and Smith, S. M. (2005) J. Biol. Chem. 280, 9773-9779), implying that other enzymes must attack the starch granule. Here, we present evidence that the debranching enzyme isoamylase 3 (ISA3) acts at the surface of the starch granule. Atisa3 mutants have more leaf starch and a slower rate of starch breakdown than wild-type plants. The amylopectin of Atisa3 contains many very short branches and ISA3-GFP localizes to granule-like structures inside chloroplasts. We suggest that ISA3 removes short branches from the granule surface. To understand how some starch is still degraded in Atisa3 mutants we eliminated a second debranching enzyme, limit dextrinase (pullulanase-type). Atlda mutants are indistinguishable from the wild type. However, the Atisa3/Atlda double mutant has a more severe starch-excess phenotype and a slower rate of starch breakdown than Atisa3 single mutants. The double mutant accumulates soluble branched oligosaccharides (limit dextrins) that are undetectable in the wild-type and the single mutants. Together these results suggest that glucan debranching occurs primarily at the granule surface via ISA3, but in its absence soluble branched glucans are debranched in the stroma via limit dextrinase. Consistent with this model, chloroplastic alpha-amylase AtAMY3, which could release soluble branched glucans, is induced in Atisa3 and in the Atisa3/Atlda double mutant.

Published

2006

122. Arabidopsis mutants Atisa1 and Atisa2 have identical phenotypes and lack the same multimeric isoamylase, which influences the branch point distribution of amylopectin during starch synthesis

Author

Thierry, Delatte, Martine, Trevisan, Mary L, Parker, and Samuel C, Zeeman

Subjects

Phenotype, Amylopectin, Mutation, Arabidopsis, Starch, Isoamylase

Abstract

The aim of this work was to evaluate the function of isoamylase in starch granule biosynthesis in Arabidopsis leaves. A reverse-genetic approach was used to knockout AtISA1, one of three genes in Arabidopsis encoding isoamylase-type debranching enzymes. The mutant (Atisa1-1) lacks functional AtISA1 transcript and the major isoamylase activity (detected by native gels) in crude extracts of leaves. The same activity is abolished by mutation at the DBE1 locus, which encodes a second isoamylase-type protein, AtISA2. This is consistent with the idea that ISA1 and ISA2 proteins are subunits of the same enzyme in vivo. Atisa1-1, Atisa2-1 (dbe1), and the Atisa1-1/Atisa2-1 double mutant all have identical phenotypes. Starch content is reduced compared with the wild type but substantial quantities of the soluble glucan phytoglycogen are produced. The amylopectin of the remaining starch and the phytoglycogen in the mutants are structurally related to each other and differ from wild-type amylopectin. Electron micrographs reveal that the phytoglycogen-accumulating phenotype is highly tissue-specific. Phytoglycogen accumulates primarily in the plastids of the palisade and spongy mesophyll cells. Remarkably, other cell types appear to accumulate only starch, which is normal in appearance but is altered in structure. As phytoglycogen accumulates during the day, its rate of accumulation decreases, its structure changes and intermediates of glucan breakdown accumulate, suggesting that degradation occurs simultaneously with synthesis. We conclude that the AtISA1/AtISA2 isoamylase influences glucan branching pattern, but that this may not be the primary determinant of partitioning between crystalline starch and soluble phytoglycogen.

Published

2005

123. Starch degradation

Author

Alison M. Smith, Samuel C. Zeeman, and Steven M. Smith

Subjects

Plant Leaves, Biodegradation, Environmental, Species Specificity, Physiology, Arabidopsis, food and beverages, Starch, beta-Amylase, Cell Biology, Plant Science, 580 Plants (Botany), Molecular Biology

Abstract

Recent research reveals that starch degradation in Arabidopsis leaves at night is significantly different from the “textbook” version of this process. Although parts of the pathway are now understood, other parts remain to be discovered. Glucans derived from starch granules are hydrolyzed via β-amylase to maltose, which is exported from the chloroplast. In the cytosol maltose is the substrate for a transglucosylation reaction, producing glucose and a glucosylated acceptor molecule. The enzyme that attacks the starch granule to release glucans is not known, nor is the nature of the cytosolic acceptor molecule. An Arabidopsis-type pathway may operate in leaves of other species, and in nonphotosynthetic organs that accumulate starch transiently. However, in starch-storing organs such as cereal endosperms and legume seeds, the process differs from that in Arabidopsis and may more closely resemble the textbook pathway. We discuss the differences in relation to the biology of each system.

Published

2005

124. α-Amylase is not required for breakdown of transitory starch in Arabidopsis leaves

Author

Jychian Chen, Hannah Dunstan, Tien-Shin Yu, David Thorneycroft, Samuel C. Zeeman, Wei-Ling Lue, Steven M. Smith, Takayuki Umemoto, Andrew Chapple, Der-Long Tsai, Shu-Yun Tung, Daniel C. Fulton, Alison M. Smith, Shue-Mei Wang, and Björn Hegemann

Subjects

DNA, Bacterial, Chloroplasts, DNA, Complementary, Time Factors, Starch, Immunoblotting, Molecular Sequence Data, Mutant, Arabidopsis, Carbohydrates, 580 Plants (Botany), Biochemistry, chemistry.chemical_compound, Transit Peptide, Escherichia coli, Arabidopsis thaliana, Amino Acid Sequence, Amylase, 3' Untranslated Regions, Molecular Biology, Gene Library, Models, Genetic, Sequence Homology, Amino Acid, biology, Wild type, food and beverages, DNA, Cell Biology, biology.organism_classification, Protein Structure, Tertiary, Plant Leaves, Chloroplast, Genetic Techniques, chemistry, Mutation, biology.protein, Electrophoresis, Polyacrylamide Gel, alpha-Amylases, 5' Untranslated Regions, Genome, Plant

Abstract

The Arabidopsis thaliana genome encodes three alpha-amylase-like proteins (AtAMY1, AtAMY2, and AtAMY3). Only AtAMY3 has a predicted N-terminal transit peptide for plastidial localization. AtAMY3 is an unusually large alpha-amylase (93.5 kDa) with the C-terminal half showing similarity to other known alpha-amylases. When expressed in Escherichia coli, both the whole AtAMY3 protein and the C-terminal half alone show alpha-amylase activity. We show that AtAMY3 is localized in chloroplasts. The starch-excess mutant of Arabidopsis sex4, previously shown to have reduced plastidial alpha-amylase activity, is deficient in AtAMY3 protein. Unexpectedly, T-DNA knock-out mutants of AtAMY3 have the same diurnal pattern of transitory starch metabolism as the wild type. These results show that AtAMY3 is not required for transitory starch breakdown and that the starch-excess phenotype of the sex4 mutant is not caused simply by deficiency of AtAMY3 protein. Knock-out mutants in the predicted non-plastidial alpha-amylases AtAMY1 and AtAMY2 were also isolated, and these displayed normal starch breakdown in the dark as expected for extraplastidial amylases. Furthermore, all three AtAMY double knock-out mutant combinations and the triple knock-out degraded their leaf starch normally. We conclude that alpha-amylase is not necessary for transitory starch breakdown in Arabidopsis leaves.

Published

2005

125. A previously unknown maltose transporter essential for starch degradation in leaves

Author

Totte Niittylä, Martine Trevisan, Alison M. Smith, Samuel C. Zeeman, Gaëlle Messerli, and Jychian Chen

Subjects

Sucrose, Chloroplasts, DNA, Complementary, Monosaccharide Transport Proteins, Starch, Recombinant Fusion Proteins, Mutant, Molecular Sequence Data, Arabidopsis, Biology, 580 Plants (Botany), Genes, Plant, chemistry.chemical_compound, Amino Acid Sequence, Cloning, Molecular, Sugar, Maltose, Crosses, Genetic, Carbohydrate export, Multidisciplinary, Arabidopsis Proteins, food and beverages, Transporter, Biological Transport, Chloroplast, Plant Leaves, Glucose, Phenotype, chemistry, Biochemistry, Mutation, Sequence Alignment

Abstract

A previously unknown maltose transporter is essential for the conversion of starch to sucrose in Arabidopsis leaves at night. The transporter was identified by isolating two allelic mutants with high starch levels and very high maltose, an intermediate of starch breakdown. The mutations affect a gene of previously unknown function, MEX1 . We show that MEX1is a maltose transporter that is unrelated to other sugar transporters. The severe mex1 phenotype demonstrates that MEX1is the predominant route of carbohydrate export from chloroplasts at night. Homologous genes in plants including rice and potato indicate that maltose export is of widespread significance.

Published

2004

126. Three isoforms of isoamylase contribute different catalytic properties for the debranching of potato glucans

Author

Cathie Martin, Anne Edwards, Christopher M. Hylton, Hasnain Hussain, Stephen Bornemann, Regla Bustos, Alexandra Mant, Alison M. Smith, Robert Seale, Edward Hinchliffe, and Samuel C. Zeeman

Subjects

Gene isoform, Enzyme complex, Molecular Sequence Data, Plant Science, Biology, Isoamylase activity, Catalysis, Gene Expression Regulation, Enzymologic, chemistry.chemical_compound, Gene Expression Regulation, Plant, Complementary DNA, Isoamylase, Amino Acid Sequence, Glucans, Phylogeny, Glucan, Plant Proteins, Solanum tuberosum, chemistry.chemical_classification, Plant Stems, Sequence Homology, Amino Acid, food and beverages, Starch, Cell Biology, Enzyme Activation, Isoenzymes, Enzyme, Biochemistry, chemistry, Amylopectin, Research Article

Abstract

Isoamylases are debranching enzymes that hydrolyze α-1,6 linkages in α-1,4/α-1,6–linked glucan polymers. In plants, they have been shown to be required for the normal synthesis of amylopectin, although the precise manner in which they influence starch synthesis is still debated. cDNA clones encoding three distinct isoamylase isoforms (Stisa1, Stisa2, and Stisa3) have been identified from potato. The expression patterns of the genes are consistent with the possibility that they all play roles in starch synthesis. Analysis of the predicted sequences of the proteins suggested that only Stisa1 and Stisa3 are likely to have hydrolytic activity and that there probably are differences in substrate specificity between these two isoforms. This was confirmed by the expression of each isoamylase in Escherichia coli and characterization of its activity. Partial purification of isoamylase activity from potato tubers showed that Stisa1 and Stisa2 are associated as a multimeric enzyme but that Stisa3 is not associated with this enzyme complex. Our data suggest that Stisa1 and Stisa2 act together to debranch soluble glucan during starch synthesis. The catalytic specificity of Stisa3 is distinct from that of the multimeric enzyme, indicating that it may play a different role in starch metabolism.

Published

2003

127. Starch mobilization in leaves

Author

Steven M. Smith, Alison M. Smith, David Thorneycroft, and Samuel C. Zeeman

Subjects

Monosaccharide Transport Proteins, Physiology, Starch, Arabidopsis, Plant Science, Biology, Chloroplast, chemistry.chemical_compound, Malto-oligosaccharide, Disproportionating enzyme, Botany, Arabidopsis thaliana, Amylase, Starch degradation, Starch phosphorylase, Starch phosphorylation, Mobilization, Arabidopsis Proteins, food and beverages, Biological Transport, Glycogen Debranching Enzyme System, biology.organism_classification, Plant Leaves, Biochemistry, chemistry, Models, Chemical, biology.protein

Abstract

Journal of Experimental Botany, 54 (382), ISSN:1460-2431, ISSN:0022-0957

Published

2003

128. Starch synthesis in arabidopsis. Granule synthesis, composition, and structure

Author

Axel Tiessen, Athene M. Donald, Alison M. Smith, Samuel C. Zeeman, K. Lisa Kato, and Emma Pilling

Subjects

chemistry.chemical_classification, Physiology, Phytoglycogen, Starch, Granule (cell biology), Starch synthase activity, food and beverages, Plant Science, Biology, 580 Plants (Botany), Polysaccharide, chemistry.chemical_compound, chemistry, Biochemistry, Amylose, Genetics, biology.protein, Starch synthase, Glucan

Abstract

The aim of this work was to characterize starch synthesis, composition, and granule structure in Arabidopsis leaves. First, the potential role of starch-degrading enzymes during starch accumulation was investigated. To discover whether simultaneous synthesis and degradation of starch occurred during net accumulation, starch was labeled by supplying (CO2)-C-14 to intact, photosynthesizing plants. Release of this label from starch was monitored during a chase period in air, using different light intensities to vary the net rate of starch synthesis. No release of label was detected unless there was net degradation of starch during the chase. Similar experiments were performed on a mutant line (dbe1) that accumulates the soluble polysaccharide, phytoglycogen. Label was not released from phytoglycogen during the chase indicating that even when in a soluble form, glucan is not appreciably degraded during accumulation. Second, the effect on starch composition of growth conditions and mutations causing starch accumulation was studied. An increase in starch content correlated with an increased amylose content of the starch and with an increase in the ratio of granule-bound starch synthase to soluble starch synthase activity. Third, the structural organization and morphology of Arabidopsis starch granules was studied. The starch granules were birefringent, indicating a radial organization of the polymers, and x-ray scatter analyses revealed that granules contained alternating crystalline and amorphous lamellae with a periodicity of 9 nm. Granules from the wild type and the high-starch mutant sex1 were flattened and discoid, whereas those of the high-starch mutant sex4 were larger and more rounded. These larger granules contained “growth rings'' with a periodicity of 200 to 300 mu. We conclude that leaf starch is synthesized without appreciable turnover and comprises similar polymers and contains similar levels of molecular organization to storage starches, making Arabidopsis an excellent model system for studying granule biosynthesis.

Published

2002

129. The Arabidopsis sex1 mutant is defective in the R1 protein, a general regulator of starch degradation in plants, and not in the chloroplast hexose transporter

Author

Wei-Ling Lue, Andreas P.M. Weber, Samuel C. Zeeman, Alison M. Smith, Gerhard Ritte, Diana Hille, Heike Kofler, Tien-Shin Yu, James R. Lloyd, Jens Kossmann, Jychian Chen, Martin Steup, Rainer E. Häusler, and Ulf-Ingo Flügge

Subjects

Chloroplasts, Monosaccharide Transport Proteins, Starch, Mutant, Amino Acid Motifs, Molecular Sequence Data, Arabidopsis, Plant Science, Photosynthesis, Genes, Plant, chemistry.chemical_compound, Amino Acid Sequence, Phosphorylation, DNA Primers, Plant Proteins, Binding Sites, biology, Base Sequence, Sequence Homology, Amino Acid, Arabidopsis Proteins, Hydrolysis, Genetic Complementation Test, food and beverages, Cell Biology, Carbohydrate, biology.organism_classification, Chloroplast, Complementation, chemistry, Biochemistry, Mutation, Research Article

Abstract

Starch is the major storage carbohydrate in higher plants and of considerable importance for the human diet and for numerous technical applications. In addition, starch can be accumulated transiently in chloroplasts as a temporary deposit of carbohydrates during ongoing photosynthesis. This transitory starch has to be mobilized during the subsequent dark period. Mutants defective in starch mobilization are characterized by high starch contents in leaves after prolonged periods of darkness and therefore are termed starch excess (sex) mutants. Here we describe the molecular characterization of the Arabidopsis sex1 mutant that has been proposed to be defective in the export of glucose resulting from hydrolytic starch breakdown. The mutated gene in sex1 was cloned using a map-based cloning approach. By complementation of the mutant, immunological analysis, and analysis of starch phosphorylation, we show that sex1 is defective in the Arabidopsis homolog of the R1 protein and not in the hexose transporter. We propose that the SEX1 protein (R1) functions as an overall regulator of starch mobilization by controlling the phosphate content of starch.

Published

2001

130. The Arabidopsis sex1 mutant is defective in the R1 protein, a general regulator of starch degradation in plants, and not in the chloroplast hexose transporter

Author

Tien-Shin Yu, Heike Kofler, Rainer E. Hausler, Diana Hille, Ulf-Ingo Flugge, Samuel C. Zeeman, Alison M. Smith, Jens Kossmann, James Lloyd, Gerhard Ritte, Martin Steup, Wei-Ling Lue, Jychian Chen, and Andreas Weber

Subjects

Cell Biology, Plant Science, Institut für Biochemie und Biologie

Published

2001

131. Starch breakdown: recent discoveries suggest distinct pathways and novel mechanisms

Author

Tabea Mettler, Oliver Kötting, Gaëlle Messerli, Samuel C. Zeeman, Sebastian Streb, Michaela Stettler, Heike Reinhold, Thierry Delatte, and Martin Umhang

Subjects

biology, Starch, food and beverages, Plant Science, Maltose, Carbohydrate metabolism, biology.organism_classification, Glycogen debranching enzyme, Endosperm, chemistry.chemical_compound, Biochemistry, chemistry, Arabidopsis, biology.protein, Amylase, Alpha-amylase, Agronomy and Crop Science

Abstract

The aim of this article is to provide an overview of current models of starch breakdown in leaves. We summarise the results of our recent work focusing on Arabidopsis, relating them to other work in the field. Early biochemical studies of starch containing tissues identified numerous enzymes capable of participating in starch degradation. In the non-living endosperms of germinated cereal seeds, starch breakdown proceeds by the combined actions of α-amylase, limit dextrinase (debranching enzyme), β-amylase and α-glucosidase. The activities of these enzymes and the regulation of some of the respective genes on germination have been extensively studied. In living plant cells, additional enzymes are present, such as α-glucan phosphorylase and disproportionating enzyme, and the major pathway of starch breakdown appears to differ from that in the cereal endosperm in some important aspects. For example, reverse-genetic studies of Arabidopsis show that α-amylase and limit-dextrinase play minor roles and are dispensable for starch breakdown in leaves. Current data also casts doubt on the involvement of α-glucosidase. In contrast, several lines of evidence point towards a major role for β-amylase in leaves, which functions together with disproportionating enzyme and isoamylase (debranching enzyme) to produce maltose and glucose. Furthermore, the characterisation of Arabidopsis mutants with elevated leaf starch has contributed to the discovery of previously unknown proteins and metabolic steps in the pathway. In particular, it is now apparent that glucan phosphorylation is required for normal rates of starch mobilisation to occur, although a detailed understanding of this step is still lacking. We use this review to give a background to some of the classical genetic mutants that have contributed to our current knowledge.

Published

2007

132. Starch breakdown: recent discoveries suggest distinct pathways and novel mechanisms.

Author

Samuel C. Zeeman, Thierry Delatte, Galle Messerli, Martin Umhang, Michaela Stettler, Tabea Mettler, Sebastian Streb, Heike Reinhold, and Oliver Ktting

Subjects

*STARCH, *CELLULAR signal transduction, *PLANT cells & tissues, *PLANT mechanics, *LEAVES, *MATHEMATICAL models, *ARABIDOPSIS

Abstract

The aim of this article is to provide an overview of current models of starch breakdown in leaves. We summarise the results of our recent work focusing on Arabidopsis, relating them to other work in the field. Early biochemical studies of starch containing tissues identified numerous enzymes capable of participating in starch degradation. In the non-living endosperms of germinated cereal seeds, starch breakdown proceeds by the combined actions of ?-amylase, limit dextrinase (debranching enzyme), ?-amylase and ?-glucosidase. The activities of these enzymes and the regulation of some of the respective genes on germination have been extensively studied. In living plant cells, additional enzymes are present, such as ?-glucan phosphorylase and disproportionating enzyme, and the major pathway of starch breakdown appears to differ from that in the cereal endosperm in some important aspects. For example, reverse-genetic studies of Arabidopsis show that ?-amylase and limit-dextrinase play minor roles and are dispensable for starch breakdown in leaves. Current data also casts doubt on the involvement of ?-glucosidase. In contrast, several lines of evidence point towards a major role for ?-amylase in leaves, which functions together with disproportionating enzyme and isoamylase (debranching enzyme) to produce maltose and glucose. Furthermore, the characterisation of Arabidopsis mutants with elevated leaf starch has contributed to the discovery of previously unknown proteins and metabolic steps in the pathway. In particular, it is now apparent that glucan phosphorylation is required for normal rates of starch mobilisation to occur, although a detailed understanding of this step is still lacking. We use this review to give a background to some of the classical genetic mutants that have contributed to our current knowledge. [ABSTRACT FROM AUTHOR]

Published

2007

133. The diurnal metabolism of leaf starch.

Author

Samuel C. Zeeman, Steven M. Smith, and Alison M. Smith

Subjects

*STARCH, *PHOTOSYNTHESIS, *CHLOROPLASTS, *BIOSYNTHESIS, *GLUCANS, *PLASTIDS

Abstract

Starch is a primary product of photosynthesis in leaves. In most plants, a large fraction of the carbon assimilated during the day is stored transiently in the chloroplast as starch for use during the subsequent night. Photosynthetic partitioning into starch is finely regulated, and the amount of carbohydrate stored is dependent on the environmental conditions, particularly day length. This regulation is applied at several levels to control the flux of carbon from the Calvin cycle into starch biosynthesis. Starch is composed primarily of branched glucans with an architecture that allows the formation of a semi-crystalline insoluble granule. Biosynthesis has been most intensively studied in non-photosynthetic starch-storing organs, such as developing seeds and tubers. Biosynthesis in leaves has received less attention, but recent reverse-genetic studies of Arabidopsis (thale cress) have produced data generally consistent with what is known for storage tissues. The pathway involves starch synthases, which elongate the glucan chains, and branching enzymes. Remarkably, enzymes that partially debranch glucans are also required for normal amylopectin synthesis. In the last decade, our understanding of starch breakdown in leaves has advanced considerably. Starch is hydrolysed to maltose and glucose at night via a pathway that requires recently discovered proteins in addition to well-known enzymes. These sugars are exported from the plastid to support sucrose synthesis, respiration and growth. In the present review we provide an overview of starch biosynthesis, starch structure and starch degradation in the leaves of plants. We focus on recent advances in each area and highlight outstanding questions. [ABSTRACT FROM AUTHOR]

Published

2007

134. Effective root responses to salinity stress include maintained cell expansion and carbon allocation

Author

Hongfei Li, Kilian Duijts, Carlo Pasini, Joyce E. van Santen, Jasper Lamers, Thijs de Zeeuw, Francel Verstappen, Nan Wang, Samuel C. Zeeman, Diana Santelia, Yanxia Zhang, and Christa Testerink

Subjects

root growth, Physiology, halophytes, Plant Science, carbon partitioning, Laboratorium voor Plantenfysiologie, cell expansion, salt stress, Schrenkiella parvula, EPS, Laboratory of Plant Physiology

Abstract

Acclimation of root growth is vital for plants to survive salt stress. Halophytes are great examples of plants that thrive even under severe salinity, but their salt tolerance mechanisms, especially those mediated by root responses, are still largely unknown.We compared root growth responses of the halophyte Schrenkiella parvula with its glycophytic relative species Arabidopsis thaliana under salt stress and performed transcriptomic analysis of S. parvula roots to identify possible gene regulatory networks underlying their physiological responses.Schrenkiella parvula roots do not avoid salt and experience less growth inhibition under salt stress. Salt-induced abscisic acid levels were higher in S. parvula roots compared with Arabidopsis. Root transcriptomic analysis of S. parvula revealed the induction of sugar transporters and genes regulating cell expansion and suberization under salt stress. C-14-labeled carbon partitioning analyses showed that S. parvula continued allocating carbon to roots from shoots under salt stress while carbon barely allocated to Arabidopsis roots. Further physiological investigation revealed that S. parvula roots maintained root cell expansion and enhanced suberization under severe salt stress.In summary, roots of S. parvula deploy multiple physiological and developmental adjustments under salt stress to maintain growth, providing new avenues to improve salt tolerance of plants using root-specific strategies., New Phytologist, 238 (5), ISSN:0028-646X, ISSN:1469-8137

135. Leaf starch turnover occurs in long days and in falling light at the end of the day

Author

Gavin M. George, Anna Flis, Alison M. Smith, Regina Feil, Stéphanie Arrivault, Dean Sumner, John E. Lunn, Virginie Mengin, Mark Stitt, Olivier Fernandez, Hirofumi Ishihara, Samuel C. Zeeman, John Innes Centre, Max Planck Institute of Molecular Plant Physiology (MPI-MP), Max-Planck-Gesellschaft, Swiss Fed Inst Technol, Plant Biochem, CH-8092 Zurich, Switzerland, Partenaires INRAE, Research School of Biology, Australian National University (ANU), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Université de Lyon (COMUE), European Commission Collaborative Project TiMet [245143], BBSRC Institute Strategic Programme [BB/J004561/1], Max-Planck Society, Germany, ETH (Zurich), and SystemsX (Switzerland) grant

Subjects

0106 biological sciences, 0301 basic medicine, trehalose 6-phosphate, Physiology, Starch, enzyme-activities, [SDV]Life Sciences [q-bio], Circadian clock, Plant Science, Photosynthesis, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Animal science, Botany, Genetics, Arabidopsis thaliana, 2. Zero hunger, photoperiodism, sugar-beet leaves, biology, beta-vulgaris l, fungi, Plant physiology, food and beverages, Maltose, biology.organism_classification, carbohydrate-metabolism, transitory starch, Light intensity, 030104 developmental biology, adp-glucose pyrophosphorylase, diurnal changes, chemistry, carbon allocation, sense organs, arabidopsis circadian clock, 010606 plant biology & botany

Abstract

International audience; We investigated whether starch degradation occurs at the same time as starch synthesis in Arabidopsis (Arabidopsis thaliana) leaves in the light. Starch accumulated in a linear fashion for about 12 h after dawn, then accumulation slowed and content plateaued. Following decreases in light intensity, the rate of accumulation of starch declined in proportion to the decline in photosynthesis if the decrease occurred, 10 h after dawn, but accumulation ceased or loss of starch occurred if the same decrease in light intensity was imposed more than 10 h after dawn. These changes in starch accumulation patterns after prolonged periods in the light occurred at both high and low starch contents and were not related to time-dependent changes in either the rate of photosynthesis or the partitioning of assimilate between starch and Suc, as assessed from metabolite measurements and (CO2)-C-14 pulse experiments. Instead, measurements of incorporation of C-13 from (CO2)-C-13 into starch and of levels of the starch degradation product maltose showed that substantial starch degradation occurred simultaneously with synthesis at time points > 14 h after dawn and in response to decreases in light intensity that occurred > 10 h after dawn. Starch measurements in circadian clock mutants suggested that the clock influences the timing of onset of degradation. We conclude that the propensity for leaf starch to be degraded increases with time after dawn. The importance of this phenomenon for efficient use of carbon for growth in long days and for prevention of starvation during twilight is discussed.

136. Accelerated ex situ breeding of GBSS - and PTST1 -edited cassava for modified starch

Author

Irene Zurkirchen, Hervé Vanderschuren, David Seung, Anton Hochmuth, Christelle Chanez, Simon E. Bull, Wilhelm Gruissem, Samuel C. Zeeman, Joel‑Elias Kuon, Elisabeth Truernit, and Devang Mehta

Subjects

0301 basic medicine, Starch, Locus (genetics), Biology, Modified starch, Crop, 03 medical and health sciences, chemistry.chemical_compound, Amylose, Arabidopsis, AMYLOSE-FREE STARCH, PASTING PROPERTIES, TOOL, Plant breeding, Food science, GENE-EXPRESSION, 2. Zero hunger, Multidisciplinary, Science & Technology, GELATINIZATION, CROP, food and beverages, DNA, biology.organism_classification, ARABIDOPSIS, WAXY, Multidisciplinary Sciences, 030104 developmental biology, chemistry, Amylopectin, Science & Technology - Other Topics, RNA

Abstract

Crop diversification required to meet demands for food security and industrial use is often challenged by breeding time and amenability of varieties to genome modification. Cassava is one such crop. Grown for its large starch-rich storage roots, it serves as a staple food and a commodity in the multibillion-dollar starch industry. Starch is composed of the glucose polymers amylopectin and amylose, with the latter strongly influencing the physicochemical properties of starch during cooking and processing. We demonstrate that CRISPR-Cas9 (clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9)-mediated targeted mutagenesis of two genes involved in amylose biosynthesis, PROTEIN TARGETING TO STARCH (PTST1) or GRANULE BOUND STARCH SYNTHASE (GBSS), can reduce or eliminate amylose content in root starch. Integration of the Arabidopsis FLOWERING LOCUS T gene in the genome-editing cassette allowed us to accelerate flowering-an event seldom seen under glasshouse conditions. Germinated seeds yielded S1, a transgene-free progeny that inherited edited genes. This attractive new plant breeding technique for modified cassava could be extended to other crops to provide a suite of novel varieties with useful traits for food and industrial applications. ispartof: Science Advances vol:4 issue:9 ispartof: location:United States status: published

137. Simultaneous silencing of isoamylases ISA1, ISA2 and ISA3 by multi-target RNAi in potato tubers leads to decreased starch content and an early sprouting phenotype.

Author

Stephanus J Ferreira, Melanie Senning, Michaela Fischer-Stettler, Sebastian Streb, Michelle Ast, H Ekkehard Neuhaus, Samuel C Zeeman, Sophia Sonnewald, and Uwe Sonnewald

Subjects

Medicine, Science

Abstract

Isoamylases hydrolyse (1-6)-alpha-D-glucosidic linkages in starch and are involved in both starch granule formation and starch degradation. In plants, three isoamylase isoforms with distinct functions in starch synthesis (ISA1 and ISA2) and degradation (ISA3) have been described. Here, we created transgenic potato plants with simultaneously decreased expression of all three isoamylases using a chimeric RNAi construct targeting all three isoforms. Constitutive expression of the hairpin RNA using the 35S CaMV promoter resulted in efficient silencing of all three isoforms in leaves, growing tubers, and sprouting tubers. Neither plant growth nor tuber yield was effected in isoamylase-deficient potato lines. Interestingly, starch metabolism was found to be impaired in a tissue-specific manner. While leaf starch content was unaffected, tuber starch was significantly reduced. The reduction in tuber starch content in the transgenic plants was accompanied by a decrease in starch granules size, an increased sucrose content and decreased hexose levels. Despite the effects on granule size, only little changes in chain length composition of soluble and insoluble glucose polymers were detected. The transgenic tubers displayed an early sprouting phenotype that was accompanied by an increased level of sucrose in parenchyma cells below the outgrowing bud. Since high sucrose levels promote sprouting, we propose that the increased number of small starch granules may cause an accelerated turnover of glucan chains and hence a more rapid synthesis of sucrose. This observation links alterations in starch structure/degradation with developmental processes like meristem activation and sprout outgrowth in potato tubers.

Published

2017

138. Recreating the synthesis of starch granules in yeast

Author

Barbara Pfister, Antoni Sánchez-Ferrer, Ana Diaz, Kuanjen Lu, Caroline Otto, Mirko Holler, Farooque Razvi Shaik, Florence Meier, Raffaele Mezzenga, and Samuel C Zeeman

Subjects

starch biosynthesis, metabolic engineering, amylopectin, Medicine, Science, Biology (General), QH301-705.5

Abstract

Starch, as the major nutritional component of our staple crops and a feedstock for industry, is a vital plant product. It is composed of glucose polymers that form massive semi-crystalline granules. Its precise structure and composition determine its functionality and thus applications; however, there is no versatile model system allowing the relationships between the biosynthetic apparatus, glucan structure and properties to be explored. Here, we expressed the core Arabidopsis starch-biosynthesis pathway in Saccharomyces cerevisiae purged of its endogenous glycogen-metabolic enzymes. Systematic variation of the set of biosynthetic enzymes illustrated how each affects glucan structure and solubility. Expression of the complete set resulted in dense, insoluble granules with a starch-like semi-crystalline organization, demonstrating that this system indeed simulates starch biosynthesis. Thus, the yeast system has the potential to accelerate starch research and help create a holistic understanding of starch granule biosynthesis, providing a basis for the targeted biotechnological improvement of crops.

Published

2016

139. PROTEIN TARGETING TO STARCH is required for localising GRANULE-BOUND STARCH SYNTHASE to starch granules and for normal amylose synthesis in Arabidopsis.

Author

David Seung, Sebastian Soyk, Mario Coiro, Benjamin A Maier, Simona Eicke, and Samuel C Zeeman

Subjects

Biology (General), QH301-705.5

Abstract

The domestication of starch crops underpinned the development of human civilisation, yet we still do not fully understand how plants make starch. Starch is composed of glucose polymers that are branched (amylopectin) or linear (amylose). The amount of amylose strongly influences the physico-chemical behaviour of starchy foods during cooking and of starch mixtures in non-food manufacturing processes. The GRANULE-BOUND STARCH SYNTHASE (GBSS) is the glucosyltransferase specifically responsible for elongating amylose polymers and was the only protein known to be required for its biosynthesis. Here, we demonstrate that PROTEIN TARGETING TO STARCH (PTST) is also specifically required for amylose synthesis in Arabidopsis. PTST is a plastidial protein possessing an N-terminal coiled coil domain and a C-terminal carbohydrate binding module (CBM). We discovered that Arabidopsis ptst mutants synthesise amylose-free starch and are phenotypically similar to mutants lacking GBSS. Analysis of granule-bound proteins showed a dramatic reduction of GBSS protein in ptst mutant starch granules. Pull-down assays with recombinant proteins in vitro, as well as immunoprecipitation assays in planta, revealed that GBSS physically interacts with PTST via a coiled coil. Furthermore, we show that the CBM domain of PTST, which mediates its interaction with starch granules, is also required for correct GBSS localisation. Fluorescently tagged Arabidopsis GBSS, expressed either in tobacco or Arabidopsis leaves, required the presence of Arabidopsis PTST to localise to starch granules. Mutation of the CBM of PTST caused GBSS to remain in the plastid stroma. PTST fulfils a previously unknown function in targeting GBSS to starch. This sheds new light on the importance of targeting biosynthetic enzymes to sub-cellular sites where their action is required. Importantly, PTST represents a promising new gene target for the biotechnological modification of starch composition, as it is exclusively involved in amylose synthesis.

Published

2015

140. Mathematical Modeling of the Dynamics of Shoot-Root Interactions and Resource Partitioning in Plant Growth.

Author

Chrystel Feller, Patrick Favre, Ales Janka, Samuel C Zeeman, Jean-Pierre Gabriel, and Didier Reinhardt

Subjects

Medicine, Science

Abstract

Plants are highly plastic in their potential to adapt to changing environmental conditions. For example, they can selectively promote the relative growth of the root and the shoot in response to limiting supply of mineral nutrients and light, respectively, a phenomenon that is referred to as balanced growth or functional equilibrium. To gain insight into the regulatory network that controls this phenomenon, we took a systems biology approach that combines experimental work with mathematical modeling. We developed a mathematical model representing the activities of the root (nutrient and water uptake) and the shoot (photosynthesis), and their interactions through the exchange of the substrates sugar and phosphate (Pi). The model has been calibrated and validated with two independent experimental data sets obtained with Petunia hybrida. It involves a realistic environment with a day-and-night cycle, which necessitated the introduction of a transitory carbohydrate storage pool and an endogenous clock for coordination of metabolism with the environment. Our main goal was to grasp the dynamic adaptation of shoot:root ratio as a result of changes in light and Pi supply. The results of our study are in agreement with balanced growth hypothesis, suggesting that plants maintain a functional equilibrium between shoot and root activity based on differential growth of these two compartments. Furthermore, our results indicate that resource partitioning can be understood as the emergent property of many local physiological processes in the shoot and the root without explicit partitioning functions. Based on its encouraging predictive power, the model will be further developed as a tool to analyze resource partitioning in shoot and root crops.

Published

2015

141. Replacement of the endogenous starch debranching enzymes ISA1 and ISA2 of Arabidopsis with the rice orthologs reveals a degree of functional conservation during starch synthesis.

Author

Sebastian Streb and Samuel C Zeeman

Subjects

Medicine, Science

Abstract

This study tested the interchangeability of enzymes in starch metabolism between dicotyledonous and monocotyledonous plant species. Amylopectin--a branched glucose polymer--is the major component of starch and is responsible for its semi-crystalline property. Plants synthesize starch with distinct amylopectin structures, varying between species and tissues. The structure determines starch properties, an important characteristic for cooking and nutrition, and for the industrial uses of starch. Amylopectin synthesis involves at least three enzyme classes: starch synthases, branching enzymes and debranching enzymes. For all three classes, several enzyme isoforms have been identified. However, it is not clear which enzyme(s) are responsible for the large diversity of amylopectin structures. Here, we tested whether the specificities of the debranching enzymes (ISA1 and ISA2) are major determinants of species-dependent differences in amylopectin structure by replacing the dicotyledonous Arabidopsis isoamylases (AtISA1 and AtISA2) with the monocotyledonous rice (Oryza sativa) isoforms. We demonstrate that the ISA1 and ISA2 are sufficiently well conserved between these species to form heteromultimeric chimeric Arabidopsis/rice isoamylase enzymes. Furthermore, we were able to reconstitute the endosperm-specific rice OsISA1 homomultimeric complex in Arabidopsis isa1isa2 mutants. This homomultimer was able to facilitate normal rates of starch synthesis. The resulting amylopectin structure had small but significant differences in comparison to wild-type Arabidopsis amylopectin. This suggests that ISA1 and ISA2 have a conserved function between plant species with a major role in facilitating the crystallization of pre-amylopectin synthesized by starch synthases and branching enzymes, but also influencing the final structure of amylopectin.

Published

2014

142. The heteromultimeric debranching enzyme involved in starch synthesis in Arabidopsis requires both isoamylase1 and isoamylase2 subunits for complex stability and activity.

Author

Maria Sundberg, Barbara Pfister, Daniel Fulton, Sylvain Bischof, Thierry Delatte, Simona Eicke, Michaela Stettler, Steven M Smith, Sebastian Streb, and Samuel C Zeeman

Subjects

Medicine, Science

Abstract

Isoamylase-type debranching enzymes (ISAs) play an important role in determining starch structure. Amylopectin - a branched polymer of glucose - is the major component of starch granules and its architecture underlies the semi-crystalline nature of starch. Mutants of several species lacking the ISA1-subclass of isoamylase are impaired in amylopectin synthesis. Consequently, starch levels are decreased and an aberrant soluble glucan (phytoglycogen) with altered branch lengths and branching pattern accumulates. Here we use TAP (tandem affinity purification) tagging to provide direct evidence in Arabidopsis that ISA1 interacts with its homolog ISA2. No evidence for interaction with other starch biosynthetic enzymes was found. Analysis of the single mutants shows that each protein is destabilised in the absence of the other. Co-expression of both ISA1 and ISA2 Escherichia coli allowed the formation of the active recombinant enzyme and we show using site-directed mutagenesis that ISA1 is the catalytic subunit. The presence of the active isoamylase alters glycogen biosynthesis in E. coli, resulting in colonies that stain more starch-like with iodine. However, analysis of the glucans reveals that rather than producing an amylopectin like substance, cells expressing the active isoamylase still accumulate small amounts of glycogen together with a population of linear oligosaccharides that stain strongly with iodine. We conclude that for isoamylase to promote amylopectin synthesis it needs to act on a specific precursor (pre-amylopectin) generated by the combined actions of plant starch synthase and branching enzyme isoforms and when presented with an unsuitable substrate (i.e. E. coli glycogen) it simply degrades it.

Published

2013