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Expression of starch-binding factor CBM20 in barley plastids controls the number of starch granules and the level of CO2 fixation

Zhong, Y.; Sagnelli, D.; Topbjerg, H.B.; Hasler-Sheetal, H.; Andrzejczak, O.A.; Hooshmand, K.; Gislum, R.é; Jiang, D.; Møller, I.M.; Blennow, A.; Hebelstrup, K.H.

Journal of Experimental Botany 71(1): 234-246

2020

ISSN/ISBN: 1460-2431
PMID: 31494665
DOI: 10.1093/jxb/erz401
Accession: 069315360
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The biosynthesis of starch granules in plant plastids is coordinated by the orchestrated action of transferases, hydrolases, and dikinases. These enzymes either contain starch-binding domain(s) themselves, or are dependent on direct interactions with co-factors containing starch-binding domains. As a means to competitively interfere with existing starch-protein interactions, we expressed the protein module Carbohydrate-Binding Motif 20 (CBM20), which has a very high affinity for starch, ectopically in barley plastids. This interference resulted in an increase in the number of starch granules in chloroplasts and in formation of compound starch granules in grain amyloplasts, which is unusual for barley. More importantly, we observed a photosystem-independent inhibition of CO2 fixation, with a subsequent reduced growth rate and lower accumulation of carbohydrates with effects throughout the metabolome, including lower accumulation of transient leaf starch. Our results demonstrate the importance of endogenous starch-protein interactions for controlling starch granule morphology and number, and plant growth, as substantiated by a metabolic link between starch-protein interactions and control of CO2 fixation in chloroplasts.

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Related References

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Hirota, S.; Takahama, U. 2018: Suppression of Pancreatin-Induced Digestion of Starch in Starch Granules by Starch/Fatty Acid and Starch/Flavonoid Complexes in Retrograding Rice Flour Foods 7(8)
Mu-Forster, C.; Huang, R.; Powers, J.R.; Harriman, R.W.; Knight, M.; Singletary, G.W.; Keeling, P.L.; Wasserman, B.P. 1996: Physical association of starch biosynthetic enzymes with starch granules of maize endosperm. Granule-associated forms of starch synthase I and starch branching enzyme II Plant Physiology 111(3): 821-829
Carciofi, M.; Blennow, A.; Jensen, S.L.; Shaik, S.S.; Henriksen, A.; Buléon, A.; Holm, P.B.; Hebelstrup, K.H. 2012: Concerted suppression of all starch branching enzyme genes in barley produces amylose-only starch granules Bmc Plant Biology 12: 223
Li, J.H.; Vasanthan, T.; Hoover, R.; Rossnagel, B.G. 2004: Starch from hull-less barley: IV. Morphological and structural changes in waxy, normal and high-amylose starch granules during heating Food Research International 37(5): 417-428
Goering, K.; Jackson, L.; Dehaas, B. 1975: Effect of some nonstarch components in corn and barley starch granules on the viscosity of heated starch-water suspensions Cereal Chemistry 52(4): 493-500
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Ji, Q.; Vincken, J-Paul.; Suurs, L.C.J.M.; Visser, R.G.F. 2003: Microbial starch-binding domains as a tool for targeting proteins to granules during starch biosynthesis Plant molecular biology 51(5): 789-801