Your search keyword '"Samuel C. Zeeman"' showing total 4 results

1. 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

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

Subjects

Phytoglycogen, Starch, Mutant, Wild type, Cell Biology, Plant Science, Biology, Isoamylase activity, Glycogen debranching enzyme, chemistry.chemical_compound, chemistry, Biochemistry, Amylopectin, Genetics, Isoamylase

Abstract

Summary 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

2. A cytosolic glucosyltransferase is required for conversion of starch to sucrose inArabidopsisleaves at night

Author

Tansy Chia, Andrew Chapple, Gaëlle Messerli, David Thorneycroft, Alison M. Smith, Steven M. Smith, Samuel C. Zeeman, and Jychian Chen

Subjects

Sucrose, Starch, Arabidopsis, Plant Science, Genes, Plant, Models, Biological, chemistry.chemical_compound, Cytosol, Genetics, Maltose, Hexoses, biology, food and beverages, Glycogen Debranching Enzyme System, Fructose, Cell Biology, Darkness, Carbohydrate, Plant Leaves, Chloroplast, Phenotype, chemistry, Biochemistry, Glucosyltransferases, Amylopectin, Mutation, biology.protein, Maltase, Alpha-amylase

Abstract

Maltose is exported from the Arabidopsis chloroplast as the main product of starch degradation at night. To investigate its fate in the cytosol, we characterised plants with mutations in a gene encoding a putative glucanotransferase (disproportionating enzyme; DPE2), a protein similar to the maltase Q (MalQ) gene product involved in maltose metabolism in bacteria. Use of a DPE2 antiserum revealed that the DPE2 protein is cytosolic. Four independent mutant lines lacked this protein and displayed a decreased capacity for both starch synthesis and starch degradation in leaves. They contained exceptionally high levels of maltose, and elevated levels of glucose, fructose and other malto-oligosaccharides. Sucrose levels were lower than those in wild-type plants, especially at the start of the dark period. A glucosyltransferase activity, capable of transferring one of the glucosyl units of maltose to glycogen or amylopectin and releasing the other, was identified in leaves of wild-type plants. Its activity was sufficient to account for the rate of starch degradation. This activity was absent from dpe2 mutant plants. Based on these results, we suggest that DPE2 is an essential component of the pathway from starch to sucrose and cellular metabolism in leaves at night. Its role is probably to metabolise maltose exported from the chloroplast. We propose a pathway for the conversion of starch to sucrose in an Arabidopsis leaf.

Published

2004

3. A critical role for disproportionating enzyme in starch breakdown is revealed by a knock-out mutation in Arabidopsis

Author

Samuel C. Zeeman, Takeshi Takaha, Joanna Critchley, Alison M. Smith, and Steven M. Smith

Subjects

chemistry.chemical_classification, biology, Starch, Mutant, Wild type, food and beverages, Cell Biology, Plant Science, Metabolism, biology.organism_classification, chemistry.chemical_compound, Enzyme, chemistry, Biochemistry, Amylose, Amylopectin, Genetics, Arabidopsis thaliana

Abstract

†These authors contributed equally to this work. Summary Disproportionating enzyme (D-enzyme) is a plastidial a-1,4-glucanotransferase but its role in starch metabolism is unclear. Using a reverse genetics approach we have isolated a mutant of Arabidopsis thaliana in which the gene encoding this enzyme (DPE1) is disrupted by a T-DNA insertion. While Denzyme activity is eliminated in the homozygous dpe1‐1 mutant, changes in activities of other enzymes of starch metabolism are relatively small. During the diurnal cycle, the amount of leaf starch is higher in dpe1‐1 than in wild type and the amylose to amylopectin ratio is increased, but amylopectin structure is unaltered. The amounts of starch synthesised and degraded are lower in dpe1‐1 than in wild type. However, the lower amount of starch synthesised and the higher proportion of amylose are both eliminated when plants are completely de-starched by a period of prolonged darkness prior to the light period. During starch degradation, a large accumulation of malto-oligosaccharides occurs in dpe1‐1 but not in wild type. These data show that D-enzyme is required for malto-oligosaccharide metabolism during starch degradation. The slower rate of starch degradation in dpe1‐1 suggests that maltooligosaccharides affect an enzyme that attacks the starch granule, or that D-enzyme itself can act directly on starch. The effects on starch synthesis and composition in dpe1‐1 under normal diurnal conditions are probably a consequence of metabolism at the start of the light period, of the high levels of maltooligosaccharides generated during the dark period. We conclude that the primary function of D-enzyme

Published

2001

4. 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