淀粉颗粒的起始由马铃薯块茎中的一种异源多聚体异淀粉酶控制。
Starch granule initiation is controlled by a heteromultimeric isoamylase in potato tubers.
作者信息
Bustos Regla, Fahy Brendan, Hylton Christopher M, Seale Robert, Nebane N Miranda, Edwards Anne, Martin Cathie, Smith Alison M
机构信息
John Innes Centre, Colney Lane, Norwich NR4 7UH, United Kingdom.
出版信息
Proc Natl Acad Sci U S A. 2004 Feb 17;101(7):2215-20. doi: 10.1073/pnas.0305920101. Epub 2004 Feb 6.
Abstract
Starch granule initiation is not understood, but recent evidence implicates a starch debranching enzyme, isoamylase, in the control of this process. Potato tubers contain isoamylase activity attributable to a heteromultimeric protein containing Stisa1 and Stisa2, the products of two of the three isoamylase genes of potato. To discover whether this enzyme is involved in starch granule initiation, activity was reduced by expression of antisense RNA for Stisa1 or Stisa2. Transgenic tubers accumulated a small amount of a soluble glucan, similar in structure to the phytoglycogen of cereal, Arabidopsis, and Chlamydomonas mutants lacking isoamylase. The major effect, however, was on the number of starch granules. Transgenic tubers accumulated large numbers of tiny granules not seen in normal tubers. These data indicate that the heteromultimeric isoamylase functions during starch synthesis to suppress the initiation of glucan molecules in the plastid stroma that would otherwise crystallize to nucleate new starch granules.
摘要
淀粉颗粒的起始过程尚不清楚,但最近的证据表明,一种淀粉脱支酶——异淀粉酶,参与了这一过程的调控。马铃薯块茎中含有异淀粉酶活性,这归因于一种包含Stisa1和Stisa2的异源多聚体蛋白,它们是马铃薯三个异淀粉酶基因中两个基因的产物。为了探究这种酶是否参与淀粉颗粒的起始过程,通过表达针对Stisa1或Stisa2的反义RNA来降低其活性。转基因块茎积累了少量可溶性葡聚糖,其结构与缺乏异淀粉酶的谷物、拟南芥和衣藻突变体中的植物糖原相似。然而,主要影响在于淀粉颗粒的数量。转基因块茎积累了大量正常块茎中未见的微小颗粒。这些数据表明,异源多聚体异淀粉酶在淀粉合成过程中发挥作用,抑制质体基质中葡聚糖分子的起始,否则这些葡聚糖分子会结晶形成新淀粉颗粒的核。
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