Your search keyword '"Eicke S"' showing total 33 results

1. Branched oligosaccharides cause atypical starch granule initiation in Arabidopsis chloroplasts.

Author

Heutinck AJM, Camenisch S, Fischer-Stettler M, Sharma M, Pfister B, Eicke S, Liu C, and Zeeman SC

Subjects

Mutation genetics, Starch Synthase metabolism, Starch Synthase genetics, Isoamylase metabolism, Isoamylase genetics, Cytoplasmic Granules metabolism, Arabidopsis genetics, Arabidopsis metabolism, Starch metabolism, Chloroplasts metabolism, Oligosaccharides metabolism, Arabidopsis Proteins metabolism, Arabidopsis Proteins genetics

Abstract

Plant chloroplasts store starch during the day, which acts as a source of carbohydrates and energy at night. Starch granule initiation relies on the elongation of malto-oligosaccharide primers. In Arabidopsis thaliana, PROTEIN TARGETING TO STARCH 2 (PTST2) and STARCH SYNTHASE 4 (SS4) are essential for the selective binding and elongation of malto-oligosaccharide primers, respectively, and very few granules are initiated in their absence. However, the precise origin and metabolism of the primers remain unknown. Potential origins of malto-oligosaccharide primers include de novo biosynthesis or their release from existing starch granules. For example, the endoamylase α-AMYLASE 3 (AMY3) can cleave a range of malto-oligosaccharides from the granule surface during starch degradation at night, some of which are branched. In the Arabidopsis double mutant deficient in the two debranching enzymes ISOAMYLASE 3 (ISA3) and LIMIT DEXTRINASE (LDA), branched malto-oligosaccharides accumulate in the chloroplast stroma. Here, we reveal that the isa3 lda double mutant shows a substantial increase in granule number per chloroplast, caused by these branched malto-oligosaccharides. The amy3 isa3 lda triple mutant, which lacks branched malto-oligosaccharides, has far fewer granules than isa3 lda, and its granule numbers are barely higher than in the wild type. Plants lacking both ISA3 and LDA and either PTST2 or SS4 show granule over-initiation, indicating that this process occurs independently of the recently described granule initiation pathway. Our findings provide insight into how and where starch granules are initiated. This knowledge can be used to alter granule number and morphological characteristics, traits known to affect starch properties., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2025. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2025

2. SAGA1 and MITH1 produce matrix-traversing membranes in the CO 2 -fixing pyrenoid.

Author

Hennacy JH, Atkinson N, Kayser-Browne A, Ergun SL, Franklin E, Wang L, Eicke S, Kazachkova Y, Kafri M, Fauser F, Vilarrasa-Blasi J, Jinkerson RE, Zeeman SC, McCormick AJ, and Jonikas MC

Subjects

Algal Proteins metabolism, Algal Proteins genetics, Plant Proteins metabolism, Plant Proteins genetics, Carbon Dioxide metabolism, Chlamydomonas reinhardtii metabolism, Chlamydomonas reinhardtii genetics, Arabidopsis metabolism, Arabidopsis genetics

Abstract

Approximately one-third of global CO 2 assimilation is performed by the pyrenoid, a liquid-like organelle found in most algae and some plants. Specialized pyrenoid-traversing membranes are hypothesized to drive CO 2 assimilation in the pyrenoid by delivering concentrated CO 2 , but how these membranes are made to traverse the pyrenoid matrix remains unknown. Here we show that proteins SAGA1 and MITH1 cause membranes to traverse the pyrenoid matrix in the model alga Chlamydomonas reinhardtii. Mutants deficient in SAGA1 or MITH1 lack matrix-traversing membranes and exhibit growth defects under CO 2 -limiting conditions. Expression of SAGA1 and MITH1 together in a heterologous system, the model plant Arabidopsis thaliana, produces matrix-traversing membranes. Both proteins localize to matrix-traversing membranes. SAGA1 binds to the major matrix component, Rubisco, and is necessary to initiate matrix-traversing membranes. MITH1 binds to SAGA1 and is necessary for extension of membranes through the matrix. Our data suggest that SAGA1 and MITH1 cause membranes to traverse the matrix by creating an adhesive interaction between the membrane and matrix. Our study identifies and characterizes key factors in the biogenesis of pyrenoid matrix-traversing membranes, demonstrates the importance of these membranes to pyrenoid function and marks a key milestone toward pyrenoid engineering into crops for improving yields., Competing Interests: Competing interests: Princeton University has submitted U.S. patent application 63/678,898 (2024) on aspects of the findings., (© 2024. The Author(s).)

Published

2024

3. MFP1 defines the subchloroplast location of starch granule initiation.

Author

Sharma M, Abt MR, Eicke S, Ilse TE, Liu C, Lucas MS, Pfister B, and Zeeman SC

Subjects

Chloroplasts genetics, Starch, Thylakoids, Carbohydrate Metabolism, Arabidopsis genetics

Abstract

Starch is one of the major carbohydrate storage compounds in plants. The biogenesis of starch granules starts with the formation of initials, which subsequently expand into granules. Several coiled-coil domain-containing proteins have been previously implicated with the initiation process, but the mechanisms by which they act remain largely elusive. Here, we demonstrate that one of these proteins, the thylakoid-associated MAR-BINDING FILAMENT-LIKE PROTEIN 1 (MFP1), specifically determines the subchloroplast location of initial formation. The expression of MFP1 variants "mis"-targeted to specific locations within chloroplasts in Arabidopsis results in distinctive shifts in not only how many but also where starch granules are formed. Importantly, "re" localizing MFP1 to the stromal face of the chloroplast's inner envelope is sufficient to generate starch granules in this aberrant position. These findings provide compelling evidence that a single protein MFP1 possesses the capacity to direct the initiation and biosynthesis machinery of starch granules., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

4. Plasmodesmal connectivity in C 4 Gynandropsis gynandra is induced by light and dependent on photosynthesis.

Author

Schreier TB, Müller KH, Eicke S, Faulkner C, Zeeman SC, and Hibberd JM

Subjects

Plasmodesmata metabolism, Plant Leaves metabolism, Photosynthesis, Poaceae, Mesophyll Cells metabolism, Magnoliopsida

Abstract

In leaves of C 4 plants, the reactions of photosynthesis become restricted between two compartments. Typically, this allows accumulation of C 4 acids in mesophyll (M) cells and subsequent decarboxylation in the bundle sheath (BS). In C 4 grasses, proliferation of plasmodesmata between these cell types is thought to increase cell-to-cell connectivity to allow efficient metabolite movement. However, it is not known whether C 4 dicotyledons also show this enhanced plasmodesmal connectivity and so whether this is a general requirement for C 4 photosynthesis is not clear. How M and BS cells in C 4 leaves become highly connected is also not known. We investigated these questions using 3D- and 2D-electron microscopy on the C 4 dicotyledon Gynandropsis gynandra as well as phylogenetically close C 3 relatives. The M-BS interface of C 4 G. gynandra showed higher plasmodesmal frequency compared with closely related C 3 species. Formation of these plasmodesmata was induced by light. Pharmacological agents that perturbed photosynthesis reduced the number of plasmodesmata, but this inhibitory effect could be reversed by the provision of exogenous sucrose. We conclude that enhanced formation of plasmodesmata between M and BS cells is wired to the induction of photosynthesis in C 4 G. gynandra., (© 2023 The Authors New Phytologist © 2023 New Phytologist Foundation.)

Published

2024

5. LIKE EARLY STARVATION 1 and EARLY STARVATION 1 promote and stabilize amylopectin phase transition in starch biosynthesis.

Author

Liu C, Pfister B, Osman R, Ritter M, Heutinck A, Sharma M, Eicke S, Fischer-Stettler M, Seung D, Bompard C, Abt MR, and Zeeman SC

Subjects

Starch chemistry, Glucans chemistry, Glucans metabolism, Plants metabolism, Amylopectin chemistry, Amylopectin metabolism, Arabidopsis genetics, Arabidopsis metabolism

Abstract

Starch, the most abundant carbohydrate reserve in plants, primarily consists of the branched glucan amylopectin, which forms semi-crystalline granules. Phase transition from a soluble to an insoluble form depends on amylopectin architecture, requiring a compatible distribution of glucan chain lengths and a branch-point distribution. Here, we show that two starch-bound proteins, LIKE EARLY STARVATION 1 (LESV) and EARLY STARVATION 1 (ESV1), which have unusual carbohydrate-binding surfaces, promote the phase transition of amylopectin-like glucans, both in a heterologous yeast system expressing the starch biosynthetic machinery and in Arabidopsis plants. We propose a model wherein LESV serves as a nucleating role, with its carbohydrate-binding surfaces helping align glucan double helices to promote their phase transition into semi-crystalline lamellae, which are then stabilized by ESV1. Because both proteins are widely conserved, we suggest that protein-facilitated glucan crystallization may be a general and previously unrecognized feature of starch biosynthesis.

Published

2023

6. Coalescence and directed anisotropic growth of starch granule initials in subdomains of Arabidopsis thaliana chloroplasts.

Author

Bürgy L, Eicke S, Kopp C, Jenny C, Lu KJ, Escrig S, Meibom A, and Zeeman SC

Subjects

Anisotropy, Arabidopsis cytology, Arabidopsis genetics, Arabidopsis Proteins genetics, Cytoplasmic Granules metabolism, Glucose metabolism, Plants, Genetically Modified, Starch Synthase genetics, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Chloroplasts metabolism, Starch metabolism, Starch Synthase metabolism

Abstract

Living cells orchestrate enzyme activities to produce myriads of biopolymers but cell-biological understanding of such processes is scarce. Starch, a plant biopolymer forming discrete, semi-crystalline granules within plastids, plays a central role in glucose storage, which is fundamental to life. Combining complementary imaging techniques and Arabidopsis genetics we reveal that, in chloroplasts, multiple starch granules initiate in stromal pockets between thylakoid membranes. These initials coalesce, then grow anisotropically to form lenticular granules. The major starch polymer, amylopectin, is synthesized at the granule surface, while the minor amylose component is deposited internally. The non-enzymatic domain of STARCH SYNTHASE 4, which controls the protein's localization, is required for anisotropic growth. These results present us with a conceptual framework for understanding the biosynthesis of this key nutrient., (© 2021. The Author(s).)

Published

2021

7. Ectopic maltase alleviates dwarf phenotype and improves plant frost tolerance of maltose transporter mutants.

Author

Cvetkovic J, Haferkamp I, Rode R, Keller I, Pommerrenig B, Trentmann O, Altensell J, Fischer-Stettler M, Eicke S, Zeeman SC, and Neuhaus HE

Subjects

Arabidopsis genetics, Arabidopsis Proteins metabolism, Membrane Transport Proteins metabolism, Arabidopsis physiology, Arabidopsis Proteins genetics, Cold Temperature, Membrane Transport Proteins genetics, Phenotype

Abstract

Maltose, the major product of starch breakdown in Arabidopsis (Arabidopsis thaliana) leaves, exits the chloroplast via the maltose exporter1 MEX1. Consequently, mex1 loss-of-function plants exhibit substantial maltose accumulation, a starch-excess phenotype and a specific chlorotic phenotype during leaf development. Here, we investigated whether the introduction of an alternative metabolic route could suppress the marked developmental defects typical for mex1 loss-of-function mutants. To this end, we ectopically expressed in mex1  chloroplasts a functional maltase (MAL) from baker's yeast (Saccharomyces cerevisiae, chloroplastidial MAL [cpMAL] mutants). Remarkably, the stromal MAL activity substantially alleviates most phenotypic peculiarities typical for mex1 plants. However, the cpMAL lines contained only slightly less maltose than parental mex1 plants and their starch levels were, surprisingly, even higher. These findings point to a threshold level of maltose responsible for the marked developmental defects in mex1. While growth and flowering time were only slightly retarded, cpMAL lines exhibited a substantially improved frost tolerance, when compared to wild-types. In summary, these results demonstrate the possibility to bypass the MEX1 transporter, allow us to differentiate between possible starch-excess and maltose-excess responses, and demonstrate that stromal maltose accumulation prevents frost defects. The latter insight may be instrumental for the development of crop plants with improved frost tolerance., (© American Society of Plant Biologists 2021. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2021

8. Distinct plastid fructose bisphosphate aldolases function in photosynthetic and non-photosynthetic metabolism in Arabidopsis.

Author

Carrera DÁ, George GM, Fischer-Stettler M, Galbier F, Eicke S, Truernit E, Streb S, and Zeeman SC

Subjects

Fructose-Bisphosphate Aldolase genetics, Fructose-Bisphosphate Aldolase metabolism, Photosynthesis, Phylogeny, Plastids metabolism, Arabidopsis genetics, Arabidopsis metabolism

Abstract

Plastid metabolism is critical in both photoautotrophic and heterotrophic plant cells. In chloroplasts, fructose-1,6-bisphosphate aldolase (FBA) catalyses the formation of both fructose 1,6-bisphosphate and sedoheptulose 1,7-bisphosphate within the Calvin-Benson cycle. Three Arabidopsis genes, AtFBA1-AtFBA3, encode plastidial isoforms of FBA, but the contribution of each isoform is unknown. Phylogenetic analysis indicates that FBA1 and FBA2 derive from a recently duplicated gene, while FBA3 is a more ancient paralog. fba1 mutants are phenotypically indistinguishable from the wild type, while both fba2 and fba3 have reduced growth. We show that FBA2 is the major isoform in leaves, contributing most of the measurable activity. Partial redundancy with FBA1 allows both single mutants to survive, but combining both mutations is lethal, indicating a block of photoautotrophy. In contrast, FBA3 is expressed predominantly in heterotrophic tissues, especially the leaf and root vasculature, but not in the leaf mesophyll. We show that the loss of FBA3 affects plastidial glycolytic metabolism of the root, potentially limiting the biosynthesis of essential compounds such as amino acids. However, grafting experiments suggest that fba3 is dysfunctional in leaf phloem transport, and we suggest that a block in photoassimilate export from leaves causes the buildup of high carbohydrate concentrations and retarded growth., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2021

9. A multifaceted analysis reveals two distinct phases of chloroplast biogenesis during de-etiolation in Arabidopsis .

Author

Pipitone R, Eicke S, Pfister B, Glauser G, Falconet D, Uwizeye C, Pralon T, Zeeman SC, Kessler F, and Demarsy E

Subjects

Arabidopsis physiology, Chloroplasts physiology, Etiolation, Organelle Biogenesis

Abstract

Light triggers chloroplast differentiation whereby the etioplast transforms into a photosynthesizing chloroplast and the thylakoid rapidly emerges. However, the sequence of events during chloroplast differentiation remains poorly understood. Using Serial Block Face Scanning Electron Microscopy (SBF-SEM), we generated a series of chloroplast 3D reconstructions during differentiation, revealing chloroplast number and volume and the extent of envelope and thylakoid membrane surfaces. Furthermore, we used quantitative lipid and whole proteome data to complement the (ultra)structural data, providing a time-resolved, multi-dimensional description of chloroplast differentiation. This showed two distinct phases of chloroplast biogenesis: an initial photosynthesis-enabling 'Structure Establishment Phase' followed by a 'Chloroplast Proliferation Phase' during cell expansion. Moreover, these data detail thylakoid membrane expansion during de-etiolation at the seedling level and the relative contribution and differential regulation of proteins and lipids at each developmental stage. Altogether, we establish a roadmap for chloroplast differentiation, a critical process for plant photoautotrophic growth and survival., Competing Interests: RP, SE, BP, GG, DF, CU, TP, SZ, FK, ED No competing interests declared, (© 2021, Pipitone et al.)

Published

2021

10. STARCH SYNTHASE5, a Noncanonical Starch Synthase-Like Protein, Promotes Starch Granule Initiation in Arabidopsis.

Author

Abt MR, Pfister B, Sharma M, Eicke S, Bürgy L, Neale I, Seung D, and Zeeman SC

Subjects

Arabidopsis Proteins chemistry, Binding Sites, Chloroplast Proteins chemistry, Chloroplasts metabolism, Conserved Sequence, Glucans metabolism, Glycosyltransferases chemistry, Models, Molecular, Mutation genetics, Phenotype, Plant Leaves enzymology, Protein Binding, Saccharomyces cerevisiae metabolism, Starch Synthase chemistry, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Chloroplast Proteins metabolism, Glycosyltransferases metabolism, Starch metabolism, Starch Synthase metabolism

Abstract

What determines the number of starch granules in plastids is an enigmatic aspect of starch metabolism. Several structurally and functionally diverse proteins have been implicated in the granule initiation process in Arabidopsis ( Arabidopsis thaliana ), with each protein exerting a varying degree of influence. Here, we show that a conserved starch synthase-like protein, STARCH SYNTHASE5 (SS5), regulates the number of starch granules that form in Arabidopsis chloroplasts. Among the starch synthases, SS5 is most closely related to SS4, a major determinant of granule initiation and morphology. However, unlike SS4 and the other starch synthases, SS5 is a noncanonical isoform that lacks catalytic glycosyltransferase activity. Nevertheless, loss of SS5 reduces starch granule numbers that form per chloroplast in Arabidopsis, and ss5 mutant starch granules are larger than wild-type granules. Like SS4, SS5 has a conserved putative surface binding site for glucans and also interacts with MYOSIN-RESEMBLING CHLOROPLAST PROTEIN, a proposed structural protein influential in starch granule initiation. Phenotypic analysis of a suite of double mutants lacking both SS5 and other proteins implicated in starch granule initiation allows us to propose how SS5 may act in this process., (© 2020 American Society of Plant Biologists. All rights reserved.)

Published

2020

11. A Reservoir of Pluripotent Phloem Cells Safeguards the Linear Developmental Trajectory of Protophloem Sieve Elements.

Author

Gujas B, Kastanaki E, Sturchler A, Cruz TMD, Ruiz-Sola MA, Dreos R, Eicke S, Truernit E, and Rodriguez-Villalon A

Subjects

Arabidopsis metabolism, Arabidopsis Proteins metabolism, Membrane Proteins metabolism, Meristem growth & development, Meristem metabolism, Phloem metabolism, Plant Roots metabolism, Protein Serine-Threonine Kinases metabolism, Signal Transduction, Arabidopsis growth & development, Phloem growth & development, Plant Roots growth & development

Abstract

Plant cells can change their identity based on positional information, a mechanism that confers developmental plasticity to plants. This ability, common to distinct multicellular organisms, is particularly relevant for plant phloem cells. Protophloem sieve elements (PSEs), one type of phloem conductive cells, act as the main organizers of the phloem pole, which comprises four distinct cell files organized in a conserved pattern. Here, we report how Arabidopsis roots generate a reservoir of meristematic phloem cells competent to swap their cell identities. Although PSE misspecification induces cell identity hybridism, the activity of RECEPTOR LIKE PROTEIN KINASE 2 (RPK2) by perceiving CLE45 peptide contributes to restrict PSE identity to the PSE position. By maintaining a spatiotemporal window when PSE and PSE-adjacent cells' identities are interchangeable, CLE45 signaling endows phloem cells with the competence to re-pattern a functional phloem pole when protophloem fails to form., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2019 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

12. LIKE SEX4 1 Acts as a β-Amylase-Binding Scaffold on Starch Granules during Starch Degradation.

Author

Schreier TB, Umhang M, Lee SK, Lue WL, Shen Z, Silver D, Graf A, Müller A, Eicke S, Stadler-Waibel M, Seung D, Bischof S, Briggs SP, Kötting O, Moorhead GBG, Chen J, and Zeeman SC

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Carbohydrate Metabolism genetics, Carrier Proteins, Cloning, Molecular, Dual-Specificity Phosphatases genetics, Gene Expression Regulation, Plant, Glucans metabolism, Phosphorylation, Plant Leaves metabolism, Plants, Genetically Modified, Protein Interaction Domains and Motifs, Protein Serine-Threonine Kinases metabolism, Recombinant Proteins, Sequence Alignment, Nicotiana genetics, Nicotiana metabolism, beta-Amylase genetics, Arabidopsis metabolism, Carbohydrate Metabolism physiology, Dual-Specificity Phosphatases metabolism, Starch metabolism, beta-Amylase metabolism

Abstract

In Arabidopsis ( Arabidopsis thaliana ) leaves, starch is synthesized during the day and degraded at night to fuel growth and metabolism. Starch is degraded primarily by β-amylases, liberating maltose, but this activity is preceded by glucan phosphorylation and is accompanied by dephosphorylation. A glucan phosphatase family member, LIKE SEX4 1 (LSF1), binds starch and is required for normal starch degradation, but its exact role is unclear. Here, we show that LSF1 does not dephosphorylate glucans. The recombinant dual specificity phosphatase (DSP) domain of LSF1 had no detectable phosphatase activity. Furthermore, a variant of LSF1 mutated in the catalytic cysteine of the DSP domain complemented the starch-excess phenotype of the lsf1 mutant. By contrast, a variant of LSF1 with mutations in the carbohydrate binding module did not complement lsf1 Thus, glucan binding, but not phosphatase activity, is required for the function of LSF1 in starch degradation. LSF1 interacts with the β-amylases BAM1 and BAM3, and the BAM1-LSF1 complex shows amylolytic but not glucan phosphatase activity. Nighttime maltose levels are reduced in lsf1 , and genetic analysis indicated that the starch-excess phenotype of lsf1 is dependent on bam1 and bam3 We propose that LSF1 binds β-amylases at the starch granule surface, thereby promoting starch degradation., (© 2019 American Society of Plant Biologists. All rights reserved.)

Published

2019

13. Two Plastidial Coiled-Coil Proteins Are Essential for Normal Starch Granule Initiation in Arabidopsis.

Author

Seung D, Schreier TB, Bürgy L, Eicke S, and Zeeman SC

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Chloroplasts genetics, Chloroplasts metabolism, Mutation genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Starch metabolism, Starch Synthase genetics, Starch Synthase metabolism, Thylakoids genetics, Thylakoids metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism

Abstract

The mechanism of starch granule initiation in chloroplasts is not fully understood. Here, we aimed to build on our recent discovery that PROTEIN TARGETING TO STARCH (PTST) family members, PTST2 and PTST3, are key players in starch granule initiation, by identifying and characterizing additional proteins involved in the process in Arabidopsis thaliana chloroplasts. Using immunoprecipitation and mass spectrometry, we demonstrate that PTST2 interacts with two plastidial coiled-coil proteins. Surprisingly, one of the proteins is the thylakoid-associated MAR BINDING FILAMENT-LIKE PROTEIN1 (MFP1), which was proposed to bind plastid nucleoids. The other protein, MYOSIN-RESEMBLING CHLOROPLAST PROTEIN (MRC), contains long coiled coils and no known domains. Whereas wild-type chloroplasts contained multiple starch granules, only one large granule was observed in most chloroplasts of the mfp1 and mrc mutants. The mfp1 mrc double mutant had a higher proportion of chloroplasts containing no visible granule than either single mutant and accumulated ADP-glucose, the substrate for starch synthesis. PTST2 was partially associated with the thylakoid membranes in wild-type plants, and fluorescently tagged PTST2 was located in numerous discrete patches within the chloroplast in which MFP1 was also located. In the mfp1 mutant, PTST2 was not associated with the thylakoids and formed discrete puncta, suggesting that MFP1 is necessary for normal PTST2 localization. Overall, we reveal that proper granule initiation requires the presence of MFP1 and MRC, and the correct location of PTST2., (© 2018 American Society of Plant Biologists. All rights reserved.)

Published

2018

14. Distinct Functions of STARCH SYNTHASE 4 Domains in Starch Granule Formation.

Author

Lu KJ, Pfister B, Jenny C, Eicke S, and Zeeman SC

Subjects

Agrobacterium tumefaciens metabolism, Arabidopsis genetics, Arabidopsis ultrastructure, Arabidopsis Proteins chemistry, Chloroplasts metabolism, Chloroplasts ultrastructure, Cytoplasmic Granules ultrastructure, Germination, Glycogen Synthase metabolism, Phenotype, Plant Development, Plant Leaves metabolism, Plant Leaves ultrastructure, Plants, Genetically Modified, Protein Domains, Starch Synthase chemistry, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Cytoplasmic Granules metabolism, Starch metabolism, Starch Synthase metabolism

Abstract

The formation of normal starch granules in Arabidopsis ( Arabidopsis thaliana ) leaf chloroplasts requires STARCH SYNTHASE 4 (SS4). In plants lacking SS4, chloroplasts typically produce only one round granule rather than multiple lenticular granules. The mechanisms by which SS4 determines granule number and morphology are not understood. The N-terminal region of SS4 is unique among SS isoforms and contains several long coiled-coil motifs, typically implicated in protein-protein interactions. The C-terminal region contains the catalytic glucosyltransferase domains, which are widely conserved in plant SS and bacterial glycogen synthase (GS) isoforms. We investigated the specific roles of the N- and C-terminal regions of SS4 by expressing truncated versions of SS4 and a fusion between the N-terminal region of SS4 and GS in the Arabidopsis ss4 mutant. Expression of the N-terminal region of SS4 alone did not alter the ss4 mutant phenotype. Expression of the C-terminal region of SS4 alone increased granule initiation but did not rescue their aberrant round morphology. Expression of a self-priming GS from Agrobacterium tumefaciens also increased the number of round granules. Remarkably, fusion of the N-terminal region of SS4 to A. tumefaciens GS restored the development of wild-type-like lenticular starch granules. Interestingly, the N-terminal region of SS4 alone or when fused to GS conferred a patchy subchloroplastic localization similar to that of the full-length SS4 protein. Considered together, these data suggest that, while the glucosyltransferase activity of SS4 is important for granule initiation, the N-terminal part of SS4 serves to establish the correct granule morphology by properly localizing this activity., (© 2018 American Society of Plant Biologists. All Rights Reserved.)

Published

2018

15. Plastid thylakoid architecture optimizes photosynthesis in diatoms.

Author

Flori S, Jouneau PH, Bailleul B, Gallet B, Estrozi LF, Moriscot C, Bastien O, Eicke S, Schober A, Bártulos CR, Maréchal E, Kroth PG, Petroutsos D, Zeeman S, Breyton C, Schoehn G, Falconet D, and Finazzi G

Subjects

Chloroplasts metabolism, Diatoms metabolism, Photosystem I Protein Complex metabolism, Photosystem II Protein Complex metabolism, Diatoms physiology, Photosynthesis physiology, Plastids metabolism, Thylakoids metabolism

Abstract

Photosynthesis is a unique process that allows independent colonization of the land by plants and of the oceans by phytoplankton. Although the photosynthesis process is well understood in plants, we are still unlocking the mechanisms evolved by phytoplankton to achieve extremely efficient photosynthesis. Here, we combine biochemical, structural and in vivo physiological studies to unravel the structure of the plastid in diatoms, prominent marine eukaryotes. Biochemical and immunolocalization analyses reveal segregation of photosynthetic complexes in the loosely stacked thylakoid membranes typical of diatoms. Separation of photosystems within subdomains minimizes their physical contacts, as required for improved light utilization. Chloroplast 3D reconstruction and in vivo spectroscopy show that these subdomains are interconnected, ensuring fast equilibration of electron carriers for efficient optimum photosynthesis. Thus, diatoms and plants have converged towards a similar functional distribution of the photosystems although via different thylakoid architectures, which likely evolved independently in the land and the ocean.

Published

2017

16. Increasing the carbohydrate storage capacity of plants by engineering a glycogen-like polymer pool in the cytosol.

Author

Eicke S, Seung D, Egli B, Devers EA, and Streb S

Subjects

Cytosol metabolism, Gene Expression Regulation, Plant physiology, Glucose metabolism, Metabolic Engineering methods, Metabolic Networks and Pathways genetics, Plants, Genetically Modified genetics, Starch genetics, Up-Regulation physiology, Carbohydrate Metabolism physiology, Genetic Enhancement methods, Glycogen metabolism, Plant Leaves physiology, Plants, Genetically Modified metabolism, Starch metabolism, Nicotiana physiology

Abstract

Global demand for higher crop yields and for more efficient utilization of agricultural products will grow over the next decades. Here, we present a new concept for boosting the carbohydrate content of plants, by channeling photosynthetically fixed carbon into a newly engineered glucose polymer pool. We transiently expressed the starch/glycogen synthases from either Saccharomyces cerevisiae or Cyanidioschyzon merolae, together with the starch branching enzyme from C. merolae, in the cytosol of Nicotiana benthamiana leaves. This effectively built a UDP-glucose-dependent glycogen biosynthesis pathway. Glycogen synthesis was observed with Transmission Electron Microscopy, and the polymer structure was further analyzed. Within three days of enzyme expression, glycogen content of the leaf was 5-10 times higher than the starch levels of the control. Further, the leaves produced less starch and sucrose, which are normally the carbohydrate end-products of photosynthesis. We conclude that after enzyme expression, the newly fixed carbohydrates were routed into the new glycogen sink and trapped. Our approach allows carbohydrates to be efficiently stored in a new subcellular compartment, thus increasing the value of vegetative crop tissues for biofuel production or animal feed. The method also opens new potential for increasing the sink strength of heterotrophic tissues., (Copyright © 2017 International Metabolic Engineering Society. Published by Elsevier Inc. All rights reserved.)

Published

2017

17. The Starch Granule-Associated Protein EARLY STARVATION1 Is Required for the Control of Starch Degradation in Arabidopsis thaliana Leaves.

Author

Feike D, Seung D, Graf A, Bischof S, Ellick T, Coiro M, Soyk S, Eicke S, Mettler-Altmann T, Lu KJ, Trick M, Zeeman SC, and Smith AM

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Chloroplasts genetics, Chloroplasts metabolism, Mutation, Plant Leaves genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Plant Leaves metabolism, Starch metabolism

Abstract

To uncover components of the mechanism that adjusts the rate of leaf starch degradation to the length of the night, we devised a screen for mutant Arabidopsis thaliana plants in which starch reserves are prematurely exhausted. The mutation in one such mutant, named early starvation1 (esv1), eliminates a previously uncharacterized protein. Starch in mutant leaves is degraded rapidly and in a nonlinear fashion, so that reserves are exhausted 2 h prior to dawn. The ESV1 protein and a similar uncharacterized Arabidopsis protein (named Like ESV1 [LESV]) are located in the chloroplast stroma and are also bound into starch granules. The region of highest similarity between the two proteins contains a series of near-repeated motifs rich in tryptophan. Both proteins are conserved throughout starch-synthesizing organisms, from angiosperms and monocots to green algae. Analysis of transgenic plants lacking or overexpressing ESV1 or LESV, and of double mutants lacking ESV1 and another protein necessary for starch degradation, leads us to propose that these proteins function in the organization of the starch granule matrix. We argue that their misexpression affects starch degradation indirectly, by altering matrix organization and, thus, accessibility of starch polymers to starch-degrading enzymes., (© 2016 American Society of Plant Biologists. All rights reserved.)

Published

2016

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

Author

Seung D, Soyk S, Coiro M, Maier BA, Eicke S, and Zeeman SC

Subjects

Amylopectin metabolism, Arabidopsis classification, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Breeding, Cytoplasmic Granules chemistry, Cytoplasmic Granules metabolism, Phylogeny, Plant Leaves genetics, Plant Leaves metabolism, Plants, Genetically Modified, Protein Structure, Tertiary, Starch Synthase metabolism, Amylose biosynthesis, Arabidopsis genetics, Arabidopsis Proteins genetics, Gene Expression Regulation, Plant, Starch Synthase genetics

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

19. Genetic Evidence That Chain Length and Branch Point Distributions Are Linked Determinants of Starch Granule Formation in Arabidopsis.

Author

Pfister B, Lu KJ, Eicke S, Feil R, Lunn JE, Streb S, and Zeeman SC

Abstract

The major component of starch is the branched glucan amylopectin. Structural features of amylopectin, such as the branching pattern and the chain length distribution, are thought to be key factors that enable it to form semicrystalline starch granules. We varied both structural parameters by creating Arabidopsis (Arabidopsis thaliana) mutants lacking combinations of starch synthases (SSs) SS1, SS2, and SS3 (to vary chain lengths) and the debranching enzyme ISOAMYLASE1-ISOAMYLASE2 (ISA; to alter branching pattern). The isa mutant accumulates primarily phytoglycogen in leaf mesophyll cells, with only small amounts of starch in other cell types (epidermis and bundle sheath cells). This balance can be significantly shifted by mutating different SSs. Mutation of SS1 promoted starch synthesis, restoring granules in mesophyll cell plastids. Mutation of SS2 decreased starch synthesis, abolishing granules in epidermal and bundle sheath cells. Thus, the types of SSs present affect the crystallinity and thus the solubility of the glucans made, compensating for or compounding the effects of an aberrant branching pattern. Interestingly, ss2 mutant plants contained small amounts of phytoglycogen in addition to aberrant starch. Likewise, ss2ss3 plants contained phytoglycogen, but were almost devoid of glucan despite retaining other SS isoforms. Surprisingly, glucan production was restored in the ss2ss3isa triple mutants, indicating that SS activity in ss2ss3 per se is not limiting but that the isoamylase suppresses glucan accumulation. We conclude that loss of only SSs can cause phytoglycogen production. This is readily degraded by isoamylase and other enzymes so it does not accumulate and was previously unnoticed., (© 2014 American Society of Plant Biologists. All Rights Reserved.)

Published

2014

20. Plastidial NAD-dependent malate dehydrogenase is critical for embryo development and heterotrophic metabolism in Arabidopsis.

Author

Beeler S, Liu HC, Stadler M, Schreier T, Eicke S, Lue WL, Truernit E, Zeeman SC, Chen J, and Kötting O

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Autotrophic Processes genetics, Chlorophyll metabolism, Chloroplasts genetics, Chloroplasts ultrastructure, Circadian Rhythm genetics, DNA Transposable Elements genetics, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, Gene Silencing, Genes, Plant genetics, Homozygote, Malate Dehydrogenase genetics, Metabolome genetics, Morphogenesis genetics, Mutagenesis, Insertional genetics, Photosynthesis, Protein Transport, Arabidopsis embryology, Arabidopsis metabolism, Chloroplasts enzymology, Heterotrophic Processes genetics, Malate Dehydrogenase metabolism, Seeds embryology, Seeds enzymology

Abstract

In illuminated chloroplasts, one mechanism involved in reduction-oxidation (redox) homeostasis is the malate-oxaloacetate (OAA) shuttle. Excess electrons from photosynthetic electron transport in the form of nicotinamide adenine dinucleotide phosphate, reduced are used by NADP-dependent malate dehydrogenase (MDH) to reduce OAA to malate, thus regenerating the electron acceptor NADP. NADP-MDH is a strictly redox-regulated, light-activated enzyme that is inactive in the dark. In the dark or in nonphotosynthetic tissues, the malate-OAA shuttle was proposed to be mediated by the constitutively active plastidial NAD-specific MDH isoform (pdNAD-MDH), but evidence is scarce. Here, we reveal the critical role of pdNAD-MDH in Arabidopsis (Arabidopsis thaliana) plants. A pdnad-mdh null mutation is embryo lethal. Plants with reduced pdNAD-MDH levels by means of artificial microRNA (miR-mdh-1) are viable, but dark metabolism is altered as reflected by increased nighttime malate, starch, and glutathione levels and a reduced respiration rate. In addition, miR-mdh-1 plants exhibit strong pleiotropic effects, including dwarfism, reductions in chlorophyll levels, photosynthetic rate, and daytime carbohydrate levels, and disordered chloroplast ultrastructure, particularly in developing leaves, compared with the wild type. pdNAD-MDH deficiency in miR-mdh-1 can be functionally complemented by expression of a microRNA-insensitive pdNAD-MDH but not NADP-MDH, confirming distinct roles for NAD- and NADP-linked redox homeostasis.

Published

2014

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

Author

Crumpton-Taylor M, Pike M, Lu KJ, Hylton CM, Feil R, Eicke S, Lunn JE, Zeeman SC, and Smith AM

Subjects

Adenosine Diphosphate Glucose metabolism, Agrobacterium enzymology, Arabidopsis Proteins, Glucans metabolism, Glycogen Synthase metabolism, Heterozygote, Isoenzymes metabolism, Metabolome, Mutation genetics, Organelle Size, RNA Interference, Solubility, Arabidopsis enzymology, Arabidopsis growth & development, Chloroplasts metabolism, Plant Leaves enzymology, Plant Leaves growth & development, Starch biosynthesis, Starch Synthase metabolism

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., (© 2013 The Authors. New Phytologist © 2013 New Phytologist Trust.)

Published

2013

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

Author

Sundberg M, Pfister B, Fulton D, Bischof S, Delatte T, Eicke S, Stettler M, Smith SM, Streb S, and Zeeman SC

Subjects

Base Sequence, Chromatography, Gel, Chromatography, Ion Exchange, DNA Primers genetics, Electrophoresis, Polyacrylamide Gel, Escherichia coli, Genetic Complementation Test, Glycogen biosynthesis, Glycogen metabolism, Isoamylase genetics, Isoamylase isolation & purification, Microscopy, Electron, Transmission, Molecular Sequence Data, Protein Stability, Protein Subunits metabolism, Sequence Alignment, Sequence Analysis, DNA, Starch biosynthesis, Substrate Specificity, Arabidopsis enzymology, Glycogen Debranching Enzyme System metabolism, Isoamylase metabolism, Multiprotein Complexes metabolism

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

23. Cecropia peltata accumulates starch or soluble glycogen by differentially regulating starch biosynthetic genes.

Author

Bischof S, Umhang M, Eicke S, Streb S, Qi W, and Zeeman SC

Subjects

1,4-alpha-Glucan Branching Enzyme genetics, 1,4-alpha-Glucan Branching Enzyme metabolism, Carbohydrate Metabolism genetics, Electrophoresis, Polyacrylamide Gel, Gene Expression Regulation, Enzymologic, Gene Expression Regulation, Plant, Glycogen Synthase genetics, Glycogen Synthase metabolism, Microscopy, Electron, Transmission, Models, Genetic, Plant Leaves genetics, Plant Leaves metabolism, Plant Leaves ultrastructure, Plant Proteins genetics, Proteome genetics, Proteome metabolism, Proteomics, Sequence Analysis, RNA, Solubility, Starch ultrastructure, Starch Synthase genetics, Starch Synthase metabolism, Tandem Mass Spectrometry, Transcriptome, Urticaceae genetics, Glycogen biosynthesis, Plant Proteins metabolism, Starch metabolism, Urticaceae metabolism

Abstract

The branched glucans glycogen and starch are the most widespread storage carbohydrates in living organisms. The production of semicrystalline starch granules in plants is more complex than that of small, soluble glycogen particles in microbes and animals. However, the factors determining whether glycogen or starch is formed are not fully understood. The tropical tree Cecropia peltata is a rare example of an organism able to make either polymer type. Electron micrographs and quantitative measurements show that glycogen accumulates to very high levels in specialized myrmecophytic structures (Müllerian bodies), whereas starch accumulates in leaves. Compared with polymers comprising leaf starch, glycogen is more highly branched and has shorter branches--factors that prevent crystallization and explain its solubility. RNA sequencing and quantitative shotgun proteomics reveal that isoforms of all three classes of glucan biosynthetic enzyme (starch/glycogen synthases, branching enzymes, and debranching enzymes) are differentially expressed in Müllerian bodies and leaves, providing a system-wide view of the quantitative programming of storage carbohydrate metabolism. This work will prompt targeted analysis in model organisms and cross-species comparisons. Finally, as starch is the major carbohydrate used for food and industrial applications worldwide, these data provide a basis for manipulating starch biosynthesis in crops to synthesize tailor-made polyglucans.

Published

2013

24. The simultaneous abolition of three starch hydrolases blocks transient starch breakdown in Arabidopsis.

Author

Streb S, Eicke S, and Zeeman SC

Subjects

Amylases genetics, Arabidopsis genetics, Arabidopsis Proteins genetics, Isoamylase genetics, Mutation, Starch genetics, Amylases metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Isoamylase metabolism, Starch metabolism

Abstract

In this study, we investigated which enzymes are involved in debranching amylopectin during transient starch degradation. Previous studies identified two debranching enzymes, isoamylase 3 (ISA3) and limit dextrinase (LDA), involved in this process. However, plants lacking both enzymes still degrade substantial amounts of starch. Thus, other enzymes/mechanisms must contribute to starch breakdown. We show that the chloroplastic α-amylase 3 (AMY3) also participates in starch degradation and provide evidence that all three enzymes can act directly at the starch granule surface. The isa3 mutant has a starch excess phenotype, reflecting impaired starch breakdown. In contrast, removal of AMY3, LDA, or both enzymes together has no impact on starch degradation. However, removal of AMY3 or LDA in addition to ISA3 enhances the starch excess phenotype. In plants lacking all three enzymes, starch breakdown is effectively blocked, and starch accumulates to the highest levels observed so far. This provides indirect evidence that the heteromultimeric debranching enzyme ISA1-ISA2 is not involved in starch breakdown. However, we illustrate that ISA1-ISA2 can hydrolyze small soluble branched glucans that accumulate when ISA3 and LDA are missing, albeit at a slow rate. Starch accumulation in the mutants correlates inversely with plant growth.

Published

2012

25. Transition Metal Compounds Towards Holography.

Author

Dieckmann V, Eicke S, Springfeld K, and Imlau M

Abstract

We have successfully proposed the application of transition metal compounds in holographic recording media. Such compounds feature an ultra-fast light-induced linkage isomerization of the transition-metal-ligand bond with switching times in the sub-picosecond regime and lifetimes from microseconds up to hours at room temperature. This article highlights the photofunctionality of two of the most promising transition metal compounds and the photophysical mechanisms that are underlying the hologram recording. We present the latest progress with respect to the key measures of holographic media assembled from transition metal compounds, the molecular embedding in a dielectric matrix and their impressive potential for modern holographic applications.

Published

2012

26. Thermal stability, photochromic sensitivity and optical properties of [Ru(bpy)(2)(OSOR)]+ compounds with R = Bn, BnCl, BnMe.

Author

Dieckmann V, Springfeld K, Eicke S, Imlau M, and Rack JJ

Abstract

The influence of ligand substitution on the photochromic properties of [Ru(bpy)(2)(OSOR)]∙PF(6) compounds (bpy = 2,2'-bipyridine, OSO = 2-methylsulfinylbenzoate) dissolved in propylene carbonate is studied by UV/VIS laser-spectroscopy as a function of temperature and exposure. The group R is either Bn (CH(2)C(6)H(5)), BnCl or BnMe. The photochromic properties originate from a phototriggered linkage isomerization located at the SO ligand. It is shown that the thermal stability of the studied compounds can be varied by ligand substitution in the range of 1.6 × 10(3) s to 3.9 × 10(4) s. In contrast, absorption spectra of ground and metastable states as well as the characteristic exposure of the photochromic response remain unchanged. The results are explained in the frame of photoinduced linkage isomerization located at the SO ligand.

Published

2010

27. The debate on the pathway of starch synthesis: a closer look at low-starch mutants lacking plastidial phosphoglucomutase supports the chloroplast-localized pathway.

Author

Streb S, Egli B, Eicke S, and Zeeman SC

Subjects

Arabidopsis cytology, Arabidopsis ultrastructure, Chloroplasts metabolism, Iodine metabolism, Phosphoglucomutase metabolism, Plant Leaves cytology, Plant Leaves metabolism, Plant Leaves ultrastructure, Staining and Labeling, Arabidopsis enzymology, Arabidopsis genetics, Chloroplasts enzymology, Metabolic Networks and Pathways, Mutation genetics, Phosphoglucomutase deficiency, Starch biosynthesis

Published

2009

28. Blocking the metabolism of starch breakdown products in Arabidopsis leaves triggers chloroplast degradation.

Author

Stettler M, Eicke S, Mettler T, Messerli G, Hörtensteiner S, and Zeeman SC

Subjects

Arabidopsis genetics, Chloroplasts genetics, Chloroplasts ultrastructure, Mutation, Phenotype, Photosynthesis genetics, Plant Leaves growth & development, Arabidopsis metabolism, Chloroplasts metabolism, Starch antagonists & inhibitors, Starch metabolism

Abstract

In most plants, a large fraction of photo-assimilated carbon is stored in the chloroplasts during the day as starch and remobilized during the subsequent night to support metabolism. Mutations blocking either starch synthesis or starch breakdown in Arabidopsis thaliana reduce plant growth. Maltose is the major product of starch breakdown exported from the chloroplast at night. The maltose excess 1 mutant (mex1), which lacks the chloroplast envelope maltose transporter, accumulates high levels of maltose and starch in chloroplasts and develops a distinctive but previously unexplained chlorotic phenotype as leaves mature. The introduction of additional mutations that prevent starch synthesis, or that block maltose production from starch, also prevent chlorosis of mex1. In contrast, introduction of mutations in disproportionating enzyme (DPE1) results in the accumulation of maltotriose in addition to maltose, and greatly increases chlorosis. These data suggest a link between maltose accumulation and chloroplast homeostasis. Microscopic analyses show that the mesophyll cells in chlorotic mex1 leaves have fewer than half the number of chloroplasts than wild-type cells. Transmission electron microscopy reveals autophagy-like chloroplast degradation in both mex1 and the dpe1/mex1 double mutant. Microarray analyses reveal substantial reprogramming of metabolic and cellular processes, suggesting that organellar protein turnover is increased in mex1, though leaf senescence and senescence-related chlorophyll catabolism are not induced. We propose that the accumulation of maltose and malto-oligosaccharides causes chloroplast dysfunction, which may by signaled via a form of retrograde signaling and trigger chloroplast degradation.

Published

2009

29. Pronounced photosensitivity of molecular [Ru(bpy)2(OSO)]+ solutions based on two photoinduced linkage isomers.

Author

Dieckmann V, Eicke S, Rack JJ, Woike T, and Imlau M

Abstract

Photosensitive properties of [Ru(bpy)(2)(OSO)] PF(6) dissolved in propylene carbonate originating from photoinduced linkage isomerism have been studied by temperature and exposure dependent transmission and UV/Vis absorption spectroscopy. An exceeding photochromic photosensitivity of S = (63 +/- 10) x 10(3) cm l J(-1) mol(-1) is determined. It is attributed to a maximum population of 100% molecules in the photoinduced isomers, a unique absorption cross section per molecule and a very low light exposure of Q(0) = (0.25 +/- 0.03) Ws cm(-2) for isomerism. Relaxation studies of O-bonded to S-bonded isomers at different temperatures verify the existence of two distinct structures of linkage isomers determined by the activation energies of E(A,1) = (0.76 +/- 0.08) eV and E(A,2) = (1.00 +/- 0.14) eV.

Published

2009

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

Author

Kötting O, Santelia D, Edner C, Eicke S, Marthaler T, Gentry MS, Comparot-Moss S, Chen J, Smith AM, Steup M, Ritte G, and Zeeman SC

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Carbohydrate Metabolism, DNA, Bacterial genetics, Glucans metabolism, Mutagenesis, Insertional, Phosphorylation, Protein Tyrosine Phosphatases genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Protein Tyrosine Phosphatases metabolism, Starch metabolism

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 alpha-1,4-glucans esterified with one or two phosphate groups. They are released from starch granules by the glucan hydrolases alpha-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

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

Author

Streb S, Delatte T, Umhang M, Eicke S, Schorderet M, Reinhardt D, and Zeeman SC

Subjects

Amylopectin metabolism, Arabidopsis genetics, Arabidopsis ultrastructure, Cryoelectron Microscopy, Glycoside Hydrolases genetics, Isoamylase genetics, Maltose metabolism, Oligosaccharides metabolism, Plants, Genetically Modified enzymology, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Plants, Genetically Modified ultrastructure, Spectroscopy, Fourier Transform Infrared, Starch genetics, alpha-Amylases genetics, Arabidopsis enzymology, Arabidopsis metabolism, Glycoside Hydrolases physiology, Isoamylase physiology, Starch biosynthesis, alpha-Amylases physiology

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 alpha- and beta-amylases during periods of net accumulation, giving rise to maltose and branched malto-oligosaccharides. The additional loss of the chloroplastic alpha-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

2008

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

Author

Fulton DC, Stettler M, Mettler T, Vaughan CK, Li J, Francisco P, Gil M, Reinhold H, Eicke S, Messerli G, Dorken G, Halliday K, Smith AM, Smith SM, and Zeeman SC

Subjects

Amino Acid Sequence, Base Sequence, Catalysis, DNA Primers, Escherichia coli genetics, Microscopy, Fluorescence, Molecular Sequence Data, Recombinant Proteins genetics, Sequence Homology, Amino Acid, beta-Amylase chemistry, beta-Amylase genetics, Arabidopsis enzymology, Chloroplasts enzymology, Starch metabolism, beta-Amylase metabolism

Abstract

This work investigated the roles of beta-amylases in the breakdown of leaf starch. Of the nine beta-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 beta-amylase activity but BAM4 did not. BAM4 has multiple amino acid substitutions relative to characterized beta-amylases, including one of the two catalytic residues. Modeling predicts major differences between the glucan binding site of BAM4 and those of active beta-amylases. Thus, BAM4 probably lost its catalytic capacity during evolution. Total beta-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 beta-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

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

Author

Delatte T, Umhang M, Trevisan M, Eicke S, Thorneycroft D, Smith SM, and Zeeman SC

Subjects

Amylopectin metabolism, Arabidopsis genetics, Chloroplasts genetics, Dextrins metabolism, Glucans metabolism, Glycoside Hydrolases genetics, Isoamylase genetics, Mutation, Phenotype, Plant Leaves chemistry, Plant Leaves metabolism, Starch chemistry, Arabidopsis metabolism, Chloroplasts metabolism, Glycoside Hydrolases metabolism, Isoamylase metabolism, Starch metabolism

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