MAIN CONCLUSION: Expression of amylosucrase in potato resulted in larger starch granules with rough surfaces and novel physico-chemical properties, including improved freeze-thaw stability, higher end viscosity, and better enzymatic digestibility. Starch is a very important carbohydrate in many food and non-food applications. In planta modification of starch by genetic engineering has significant economic and environmental benefits as it makes the chemical or physical post-harvest modification obsolete. An amylosucrase from Neisseria polysaccharea fused to a starch-binding domain (SBD) was introduced in two potato genetic backgrounds to synthesize starch granules with altered composition, and thereby to broaden starch applications. Expression of SBD-amylosucrase fusion protein in the amylose-containing potato resulted in starch granules with a rough surface, a twofold increase in median granule size, and altered physico-chemical properties including improved freeze-thaw stability, higher end viscosity, and better enzymatic digestibility. These effects are possibly a result of the physical interaction between amylosucrase and starch granules. The modified larger starches not only have great benefit to the potato starch industry by reducing losses during starch isolation, but also have an advantage in many food applications such as frozen food due to its extremely high freeze-thaw stability.
MAIN CONCLUSION: Expression of amylosucrase in potato resulted in larger starch granules with rough surfaces and novel physico-chemical properties, including improved freeze-thaw stability, higher end viscosity, and better enzymatic digestibility. Starch is a very important carbohydrate in many food and non-food applications. In planta modification of starch by genetic engineering has significant economic and environmental benefits as it makes the chemical or physical post-harvest modification obsolete. An amylosucrase from Neisseria polysaccharea fused to a starch-binding domain (SBD) was introduced in two potato genetic backgrounds to synthesize starch granules with altered composition, and thereby to broaden starch applications. Expression of SBD-amylosucrase fusion protein in the amylose-containing potato resulted in starch granules with a rough surface, a twofold increase in median granule size, and altered physico-chemical properties including improved freeze-thaw stability, higher end viscosity, and better enzymatic digestibility. These effects are possibly a result of the physical interaction between amylosucrase and starch granules. The modified larger starches not only have great benefit to the potatostarch industry by reducing losses during starch isolation, but also have an advantage in many food applications such as frozen food due to its extremely high freeze-thaw stability.
Authors: G Potocki de Montalk; M Remaud-Simeon; R M Willemot; P Sarçabal; V Planchot; P Monsan Journal: FEBS Lett Date: 2000-04-14 Impact factor: 4.124
Authors: Bjorn Kloosterman; Oscar Vorst; Robert D Hall; Richard G F Visser; Christian W Bachem Journal: Plant Biotechnol J Date: 2005-09 Impact factor: 9.803
Authors: Cécile Albenne; Lars K Skov; Osman Mirza; Michael Gajhede; Gabrielle Potocki-Véronèse; Pierre Monsan; Magali Remaud-Simeon Journal: FEBS Lett Date: 2002-09-11 Impact factor: 4.124
Authors: Bjorn Kloosterman; David De Koeyer; Rebecca Griffiths; Barry Flinn; Burkhard Steuernagel; Uwe Scholz; Sophia Sonnewald; Uwe Sonnewald; Glenn J Bryan; Salomé Prat; Zsófia Bánfalvi; John P Hammond; Peter Geigenberger; Kåre L Nielsen; Richard G F Visser; Christian W B Bachem Journal: Funct Integr Genomics Date: 2008-05-27 Impact factor: 3.410