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DNA 摄取诱导拟南芥 CLE 肽表达变化,从而控制根形态。

DNA uptake by Arabidopsis induces changes in the expression of CLE peptides which control root morphology.

机构信息

School of Biological Sciences, The University of Queensland, St. Lucia, QLD, Australia.

出版信息

Plant Signal Behav. 2010 Sep;5(9):1112-4. doi: 10.4161/psb.5.9.12477.

DOI:10.4161/psb.5.9.12477
PMID:21490419
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3115079/
Abstract

The presence of externally supplied DNA in the growth medium enhances growth of lateral roots and root hairs in Arabidopsis. This phenomenon cannot be attributed to phosphorus (P) limitation because it is independent of the plants' P status. Rather, we hypothesized that DNA triggers a currently unknown signaling pathway. Analyzing the transcriptional changes of genes induced by externally supplied DNA, we show that 7 of the 17 studied CLAVATA3/ESR-related (CLEs) genes were differentially regulated. CLEs are known peptide hormones that affect plant development including root morphology. While previous research had shown that over-expression of these CLE genes alters root morphology, changes in gene expression had not been linked to environmental triggers. The differential expression of these CLEs genes and accompanied changes of the root phenotype are indicative of a DNA-elicited signal pathway which affects root development. We conclude that DNA acts as a signaling compound which induces root proliferation in a way that would enhance the plant's ability to acquire nutrients from soil organic matter. Our study further confirms the importance of CLEs for controlling root morphology in response to specific environmental conditions, and draws attention to a novel role of DNA as a signaling compound.

摘要

外源性 DNA 存在于生长培养基中会促进拟南芥侧根和根毛的生长。这种现象不能归因于磷 (P) 限制,因为它与植物的 P 状态无关。相反,我们假设 DNA 触发了一个目前未知的信号通路。通过分析外源性 DNA 诱导的基因转录变化,我们发现研究的 17 个 CLAVATA3/ESR 相关 (CLE) 基因中有 7 个受到差异调控。CLE 是已知的影响植物发育的肽类激素,包括根形态。虽然之前的研究表明这些 CLE 基因的过表达会改变根的形态,但基因表达的变化与环境触发因素并没有联系。这些 CLE 基因的差异表达以及伴随的根表型变化表明,DNA 会引发影响根发育的信号通路。我们得出结论,DNA 作为一种信号化合物,以一种增强植物从土壤有机质中获取营养的方式诱导根的增殖。我们的研究进一步证实了 CLE 对于控制根形态以响应特定环境条件的重要性,并引起了对 DNA 作为一种信号化合物的新作用的关注。

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