马铃薯激光显微切割韧皮部的组织完整性和RNA质量

Tissue integrity and RNA quality of laser microdissected phloem of potato.

作者信息

Yu Yueyue, Lashbrook C C, Hannapel David J

机构信息

Molecular, Cellular, and Developmental Biology Major, Iowa State University, Ames, IA 50011, USA.

出版信息

Planta. 2007 Aug;226(3):797-803. doi: 10.1007/s00425-007-0509-z. Epub 2007 Mar 27.

DOI:10.1007/s00425-007-0509-z

PMID:17387510

Abstract

The phloem is an important conduit for the transport of signaling molecules including RNA. Phloem sap has served as a source of RNA to profile uncontaminated phloem transcriptomes but its collection is difficult in many species. Laser capture microdissection techniques offer a valuable alternative for isolating RNA from specific vascular cells. In potato (Solanum tuberosum L.), there are seven BEL1-like transcription factors expressed throughout the plant with diverse functions. The RNA of one of these, StBEL5, moves through the phloem from the leaf to stolon tips to regulate tuber formation. In this study, the presence of several BEL RNAs and one Knotted1-like RNA was determined in phloem cells collected by laser microdissection coupled to laser pressure catapulting (LMPC). Three fixatives were compared for their effect on cell morphology and RNA quality in transverse sections of stems of potato. For optimum tissue integrity and quality of RNA from potato stem sections, the best results were achieved using ethanol acetate as the fixative. In addition, the RT-PCR results demonstrated the presence of six out of seven of the StBEL RNAs and a potato Knox RNA in phloem cells.

摘要

韧皮部是包括RNA在内的信号分子运输的重要通道。韧皮部汁液一直是用于分析未受污染的韧皮部转录组的RNA来源，但在许多物种中收集韧皮部汁液都很困难。激光捕获显微切割技术为从特定维管细胞中分离RNA提供了一种有价值的替代方法。在马铃薯（Solanum tuberosum L.）中，有7种BEL1类转录因子在整个植株中表达，功能多样。其中之一的StBEL5的RNA通过韧皮部从叶片移动到匍匐茎顶端，以调节块茎形成。在本研究中，通过激光显微切割结合激光压力弹射法（LMPC）收集的韧皮部细胞中，测定了几种BEL RNA和一种Knotted1类RNA的存在情况。比较了三种固定剂对马铃薯茎横切片中细胞形态和RNA质量的影响。为了使马铃薯茎切片具有最佳的组织完整性和RNA质量，使用乙醇乙酸酯作为固定剂可获得最佳结果。此外，RT-PCR结果表明，在韧皮部细胞中存在7种StBEL RNA中的6种以及一种马铃薯Knox RNA。

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马铃薯激光显微切割韧皮部的组织完整性和RNA质量

Tissue integrity and RNA quality of laser microdissected phloem of potato.

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