甘蓝型油菜 GLABRA2 基因：与种子含油量及发育相关功能分析及功能标记开发。

Brassica GLABRA2 genes: analysis of function related to seed oil content and development of functional markers.

机构信息

The Key Lab of Oil Crops Biology, The Ministry of Agriculture of the People's Republic of China, Oil Crops Research Institute, Chinese Academy of Agricultural Sciences, No. 2 Xudong 2nd Road, Wuhan, 430062, Hubei, People's Republic of China.

出版信息

Theor Appl Genet. 2010 May;120(8):1597-610. doi: 10.1007/s00122-010-1279-8. Epub 2010 Feb 17.

DOI:10.1007/s00122-010-1279-8

PMID:20162256

Abstract

Regulation of seed oil accumulation in oilseed rape (Brassica napus) has important economic significance. However, few genes have been characterized that affect final seed oil content. Through a mutant identification, the class IV homeodomain-ZIP transcription factor GLABRA2 (GL2) has been found to regulate seed oil accumulation in Arabidopsis, in addition to its role in trichome development. In this study, we isolated four distinct orthologues of GL2 from B. napus (AC-genome), B. rapa (A) and B. oleracea (C), using an overlapping-PCR strategy. The four GL2 orthologues were very similar, with 96.10-99.69% identity in exon regions, 75.45-93.84% in intron regions, 97.34-99.87% in amino acid sequences. Alignments of the four genes revealed that the A-genome sequences of BnaA.GL2.a from B. napus and BraA.GL2.a from B. rapa are more similar than the others, and likewise the C-genome sequences of BnaC.GL2.b from B. napus and BolC.GL2.a from B. oleracea are more similar. BnaA.GL2.a and BraA.GL2.a from the A-genome are highly expressed in roots, whilst BnaC.GL2.b and BolC.GL2.a from the C-genome are preferentially expressed in seeds. Transgenic ectopic overexpression and suppression of BnaC.GL2.b in Arabidopsis allowed further investigation of the effect on seed oil content. Overexpression generated two phenotypes: the wild-type-like and the gl2-mutant-like (an Arabidopsis glabrous mutant of gl2-2), with increases in seed oil content of 3.5-5.0% in the gl2-mutant-like transgenic plants. Suppression resulted in increases of 2.5-6.1% in seed oil content, and reduced trichome number at the leaf margins. These results suggest that BnaC.GL2.b can negatively regulate oil accumulation in Arabidopsis seeds. As a result of comparing the four GL2 genes, three A/C-genome-specific primer sets were developed and a C-genome-specific EcoRV cleavage site was identified, which can be used as functional markers to distinguish these orthologues within Brassica species. The genes identified and their molecular markers developed in this study will be valuable both for oilseed rape breeding focusing on improvement of seed oil content, and for detecting gene flow between populations.

摘要

调控油菜籽（甘蓝型油菜）的种子油脂积累具有重要的经济意义。然而，仅有少数基因被鉴定出来可以影响最终的种子含油量。通过突变体鉴定，我们发现第四类同源域-ZIP 转录因子 GLABRA2（GL2）除了在毛状体发育中起作用外，还可以调控拟南芥的种子油脂积累。在这项研究中，我们利用重叠 PCR 策略，从甘蓝型油菜（A 基因组）、白菜型油菜（A）和甘蓝（C）中分离出了 GL2 的四个不同的直系同源物。这四个 GL2 直系同源物非常相似，外显子区域的同源性为 96.10-99.69%，内含子区域的同源性为 75.45-93.84%，氨基酸序列的同源性为 97.34-99.87%。四个基因的序列比对表明，甘蓝型油菜和白菜型油菜的 A 基因组序列 BnaA.GL2.a 比其他序列更相似，而甘蓝型油菜和甘蓝的 C 基因组序列 BnaC.GL2.b 和 BolC.GL2.a 比其他序列更相似。A 基因组的 BnaA.GL2.a 和 BraA.GL2.a 在根中高度表达，而 C 基因组的 BnaC.GL2.b 和 BolC.GL2.a 则在种子中优先表达。在拟南芥中异位过表达和抑制 BnaC.GL2.b 进一步研究了对种子含油量的影响。过表达产生了两种表型：野生型样和 gl2 突变体样（gl2-2 的拟南芥无毛突变体），gl2 突变体样转基因植物的种子含油量增加了 3.5-5.0%。抑制导致种子含油量增加 2.5-6.1%，同时减少了叶缘毛状体的数量。这些结果表明，BnaC.GL2.b 可以负调控拟南芥种子中的油脂积累。通过比较这四个 GL2 基因，我们开发了三个 A/C 基因组特异性引物对，并鉴定出一个 C 基因组特异性 EcoRV 酶切位点，该位点可作为功能标记，用于区分这些在芸薹属物种中的直系同源物。本研究中鉴定的基因及其分子标记不仅对油菜籽育种具有重要意义，可提高种子含油量，而且对检测种群间的基因流也具有重要意义。

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甘蓝型油菜 GLABRA2 基因：与种子含油量及发育相关功能分析及功能标记开发。

Brassica GLABRA2 genes: analysis of function related to seed oil content and development of functional markers.

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