Farhad Nazarian-Firouzabadi scite author profile

Starch, a very compact form of glucose units, is the most abundant form of storage polyglucan in nature. The starch synthesis pathway is among the central biochemical pathways, however, our understanding of this important pathway regarding genetic elements controlling this pathway, is still insufficient. Starch biosynthesis requires the action of several enzymes. Soluble starch synthases (SSs) are a group of key players in starch biosynthesis which have proven their impact on different aspects of the starch biosynthesis and functionalities. These enzymes have been studied in different plant species and organs in detail, however, there seem to be key differences among species regarding their contributions to the starch synthesis. In this review, we consider an update on various SSs with an emphasis on potato SSs as a model for storage organs. The genetics and regulatory mechanisms of potato starch synthases will be highlighted. Different aspects of various isoforms of SSs are also discussed.

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Expression of an engineered granule‐bound Escherichia coli glycogen branching enzyme in potato results in severe morphological changes in starch granules

Huang

Nazarian-Firouzabadi

Vincken

et al. 2012

Plant Biotechnology Journal

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fax +31(0)317483457; email luisa. trindade@wur.nl) † These authors contributed equally to this study.Keywords: starch, E. coli glycogen branching enzyme, GLGB, starchbinding domain, starch granule morphology. SummaryThe Escherichia coli glycogen branching enzyme (GLGB) was fused to either the C-or N-terminus of a starch-binding domain (SBD) and expressed in two potato genetic backgrounds: the amylose-free mutant (amf) and an amylose-containing line (Kardal). Regardless of background or construct used, a large amount of GLGB/SBD fusion protein was accumulated inside the starch granules, however, without an increase in branching. The presence of GLGB/SBD fusion proteins resulted in altered morphology of the starch granules in both genetic backgrounds. In the amf genetic background, the starch granules showed both amalgamated granules and porous starch granules, whereas in Kardal background, the starch granules showed an irregular rough surface. The altered starch granules in both amf and Kardal backgrounds were visible from the initial stage of potato tuber development. High-throughput transcriptomic analysis showed that expression of GLGB/SBD fusion protein in potato tubers did not affect the expression level of most genes directly involved in the starch biosynthesis except for the up-regulation of a betaamylase gene in Kardal background. The beta-amylase protein could be responsible for the degradation of the extra branches potentially introduced by GLGB.

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Expression analysis of anthocyanin biosynthesis key regulatory genes involved in pomegranate (Punica granatum L.)

Rouholamin

Zahedi

Nazarian-Firouzabadi

et al. 2015

Scientia Horticulturae

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Genome-wide in silico identification of LysM-RLK genes in potato (Solanum tuberosum L.)

et al. 2019

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