Seo Beom-seok, Kim Seungtaek, Scott M Paul, Singletary George W, Wong Kit-sum, James Martha G, Myers Alan M
Department of Biochemistry, Biophysics, and Molecular Biology, Iowa State University, Ames, IA 50011, USA.
Plant Physiol. 2002 Apr;128(4):1189-99. doi: 10.1104/pp.010756.
Starch-branching enzymes (SBEs) catalyze the formation of alpha(1-->6) glycoside bonds in glucan polymers, thus, affecting the structure of amylopectin and starch granules. Two distinct classes of SBE are generally conserved in higher plants, although the specific role(s) of each isoform in determination of starch structure is not clearly understood. This study used a heterologous in vivo system to isolate the function of each of the three known SBE isoforms of maize (Zea mays) away from the other plant enzymes involved in starch biosynthesis. The ascomycete Brewer's yeast (Saccharomyces cerevisiae) was employed as the host species. All possible combinations of maize SBEs were expressed in the absence of the endogenous glucan-branching enzyme. Each maize SBE was functional in yeast cells, although SBEI had a significant effect only if SBEIIa and SBEIIb also were present. SBEI by itself did not support glucan accumulation, whereas SBEIIa and SBEIIb both functioned along with the native glycogen synthases (GSs) to produce significant quantities of alpha-glucan polymers. SBEIIa was phenotypically dominant to SBEIIb in terms of glucan structure. The specific branching enzyme present had a significant effect on the molecular weight of the product. From these data we suggest that SBEs and GSs work in a cyclically interdependent fashion, such that SBE action is needed for optimal GS activity; and GS, in turn, influences the further effects of SBE. Also, SBEIIa and SBEIIb appear to act before SBEI during polymer assembly in this heterologous system.
淀粉分支酶(SBEs)催化葡聚糖聚合物中α(1→6)糖苷键的形成,从而影响支链淀粉和淀粉颗粒的结构。在高等植物中,通常存在两种不同类型的SBE,尽管每种同工型在淀粉结构测定中的具体作用尚不清楚。本研究使用了一种异源体内系统,以分离玉米(Zea mays)三种已知SBE同工型中每种同工型的功能,使其不受参与淀粉生物合成的其他植物酶的影响。酿酒酵母(Saccharomyces cerevisiae)这种子囊菌被用作宿主物种。在缺乏内源性葡聚糖分支酶的情况下,表达了玉米SBE的所有可能组合。每种玉米SBE在酵母细胞中都具有功能,不过只有当SBEIIa和SBEIIb也存在时,SBEI才会产生显著影响。单独的SBEI不支持葡聚糖积累,而SBEIIa和SBEIIb都与天然糖原合酶(GSs)一起发挥作用,产生大量的α-葡聚糖聚合物。就葡聚糖结构而言,SBEIIa在表型上对SBEIIb占主导地位。存在的特定分支酶对产物的分子量有显著影响。根据这些数据,我们认为SBEs和GSs以循环相互依赖的方式发挥作用,即SBE的作用是最佳GS活性所必需的;而GS反过来又影响SBE的进一步作用。此外,在这个异源系统中,在聚合物组装过程中,SBEIIa和SBEIIb似乎在SBEI之前起作用。