既主内政, 又辖外交——以PHR为中心的基因网络调控植物-菌根真菌的共生

doi:10.11983/CBB21177

植物学报 ›› 2021, Vol. 56 ›› Issue (6): 647-650.DOI: 10.11983/CBB21177

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既主内政, 又辖外交——以PHR为中心的基因网络调控植物-菌根真菌的共生

刘栋()

清华大学生命科学学院, 植物生物学研究中心, 北京 100084

收稿日期:2021-10-12 接受日期:2021-10-18 出版日期:2021-11-01 发布日期:2021-11-12
通讯作者: 刘栋
作者简介:* E-mail: liu-d@mail.tsinghua.edu.cn
基金资助:
科技部重大研发计划(2016YFD0100700);国家自然科学基金(318870236)

Managing Both Internal and Foreign Affairs—A PHR-centered Gene Network Regulates Plant-mycorrhizal Symbiosis

Dong Liu()

Center of Plant Biology, School of Life Sciences, Tsinghua University, Beijing 100084, China

Received:2021-10-12 Accepted:2021-10-18 Online:2021-11-01 Published:2021-11-12
Contact: Dong Liu

摘要/Abstract

摘要： 磷是植物生长发育必需的大量矿质营养元素, 但自然界大部分土壤都存在严重缺磷的问题。为了适应这一营养逆境, 植物演化出一系列低磷胁迫应答反应。通过改变基因的转录水平调控低磷胁迫应答反应, 而转录因子PHR1在调控植物对低磷胁迫的转录响应中起关键作用。此外, 大部分陆生植物还能与丛枝菌根真菌建立共生关系, 通过丛枝菌根真菌更有效地从土壤中获取磷元素。最近, 中国科学院分子植物科学卓越创新中心王二涛研究组发现, 以PHR为中心的转录调控网络控制植物-丛枝菌根真菌共生的建立。因此, PHR不但在维持植物细胞自身的磷稳态中发挥作用, 而且参与植物与外界微生物的相互作用, 为植物有效地从环境中获得磷元素提供了另外一条途径。

关键词: 低磷胁迫, 转录响应, PHR转录因子, 基因网络, 丛枝菌根, 植物-丛枝菌根共生

Abstract: Phosphorus is a macronutrient essential for plant growth and development, however, phosphate (Pi), the major form of phosphorus absorbed by plants, is quite limiting in soil. To cope with this nutritional stress, plants have evolved an array of adaptive responses, which are largely regulated by changing gene expression in response to Pi deficiency. The transcription factor, PHR1 plays a key role in regulating plant transcriptional response to Pi deficiency. Besides, most land plants can form symbiosis with arbuscular mycorrhizal (AM) fungi, through which plants can obtain Pi from soil more effectively. Recently, the research group of Ertao Wang of Center for Excellence in Molecular Plant Science, Chinese Academy of Sciences, reported that a PHR-centered gene regulatory network plays an essential role in promoting plant-AM symbiosis. Therefore, PHR not only functions in maintaining plant Pi homeostasis, but also in communicating with beneficial microorganisms in the environments, which provides another route for plants to obtain Pi from soil.

Key words: low phosphate stress, transcriptional response, PHR transcription factor, gene network, arbuscular mycorrhiza, plant-arbuscular mycorrhizal symbiosis

刘栋. 既主内政, 又辖外交——以PHR为中心的基因网络调控植物-菌根真菌的共生. 植物学报, 2021, 56(6): 647-650.

Dong Liu. Managing Both Internal and Foreign Affairs—A PHR-centered Gene Network Regulates Plant-mycorrhizal Symbiosis. Chinese Bulletin of Botany, 2021, 56(6): 647-650.

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链接本文: https://www.chinbullbotany.com/CN/10.11983/CBB21177

https://www.chinbullbotany.com/CN/Y2021/V56/I6/647

图/表 2

图1 植物从土壤中获取磷素的两种途径 (1) 根表皮细胞直接从土壤中吸收磷素; (2) 植物根皮层细胞与丛枝菌根真菌形成共生关系, 丛枝菌根真菌的菌丝从土壤中吸收磷素, 再提供给植物根组织。

Figure 1 Two pathways for plants to obtain Pi from soil (1) Root epidermal cells uptake Pi from soil directly; (2) Root cortex cells form symbiosis with arbuscular mycorrhiza fungi which uptake Pi from soil and provide them to root tissues.

图2 SPX-PHR信号转导模块调控水稻-丛枝菌根共生的模式图

Figure 2 A diagram showing how SPX-PHR regulates arbuscular mycorrhizal symbiosis in rice

参考文献 16

[1]	Bustos R, Castrillo G, Linhares F, Puga MI, Rubio V, Pérez-Pérez J, Solano R, Leyva A, Paz-Ares J (2010). A central regulatory system largely controls transcriptional activation and repression responses to phosphate starvation in Arabidopsis. PLoS Genet 6, e1001102.
[2]	Dong JS, Ma GJ, Sui LQ, Wei MW, Satheesh V, Zhang RY, Ge SH, Li JK, Zhang TE, Wittwer C, Jessen HJ, Zhang HM, An GY, Chao DY, Liu D, Lei MG (2019). Inositol pyrophosphate InsP8 acts as an intracellular phos- phate signal in Arabidopsis. Mol Plant 12, 1463-1473. DOI URL
[3]	Jiang YN, Wang WX, Xie QJ, Liu N, Liu LX, Wang DP, Zhang XW, Yang C, Chen XY, Tang DZ, Wang ET (2017). Plants transfer lipids to sustain colonization by mutualistic mycorrhizal and parasitic fungi. Science 356, 1172-1175. DOI PMID
[4]	Liu F, Wang ZY, Ren HY, Shen CJ, Li Y, Ling HQ, Wu CY, Lian XM, Wu P (2010). OsSPX1 suppresses the function of OsPHR2 in the regulation of expression of OsPT2 and phosphate homeostasis in shoots of rice. Plant J 62, 508-517. DOI URL
[5]	López-Arredondo DL, Leyva-González MA, González- Morales SI, López-Bucio J, Herrera-Estrella L (2014). Phosphate nutrition: improving low-phosphate tolerance in crops. Annu Rev Plant Biol 65, 95-123. DOI PMID
[6]	Luginbuehl LH, Menard GN, Kurup S, Van Erp H, Radhakrishnan GV, Breakspear A, Oldroyd GED, Eastmond PJ (2017). Fatty acids in arbuscular mycorrhizal fungi are synthesized by the host plants. Science 356, 1175-1178. DOI PMID
[7]	Puga MI, Mateos I, Charukesi R, Wang ZY, Franco-Zorrilla JM, de Lorenzo L, Irigoyen ML, Masiero S, Bustos R, Rodríguez J, Leyva A, Rubio V, Sommer H, Paz-Ares J (2014). SPX1 is a phosphate-dependent inhibitor of Phosphate Starvation Response 1 in Arabidopsis. Proc Natl Acad Sci USA 111, 14947-14952. DOI URL
[8]	Rubio V, Linhares F, Solano R, Martín AC, Iglesias J, Leyva A, Paz-Ares J (2001). A conserved MYB transcription factor involved in phosphate starvation signaling both in vascular plants and in unicellular algae. Genes Dev 15, 2122-2133. DOI URL
[9]	Shi J, Zhao B, Zheng S, Zhang X, Wang X, Dong W, Xie Q, Gang W, Xiao Y, Chen F, Yu N, Wang E (2021). A phosphate starvation response-centered network regulates mycorrhizal symbiosis. Cell https://doi.org/10.1016/j.cell.202109.030.
[10]	Smith SE, Jakobsen I, Grønlund M, Smith FA (2011). Roles of arbuscular mycorrhizas in plant phosphorus nutrition: interactions between pathways of phosphorus uptake in arbuscular mycorrhizal roots have important implications for understanding and manipulating plant phosphorus acquisition. Plant Physiol 156, 1050-1057. DOI URL
[11]	Sun LC, Song L, Zhang Y, Zheng Z, Liu D (2016). Arabidopsis PHL2 and PHR1 act redundantly as the key components of the central regulatory system controlling transcriptional responses to phosphate starvation. Plant Physiol 170, 499-514. DOI URL
[12]	Wang P, Snijders R, Kohlen W, Liu JY, Bisseling T, Limpens E (2021). Medicago SPX1 and SPX3 regulate phosphate homeostasis, mycorrhizal colonization, and arbuscule degradation. Plant Cell doi: 10.1093/plcell/koab206. DOI
[13]	Wang Z, Zheng Z, Song L, Liu D (2018). Functional charac- terization of Arabidopsis PHL4 in plant response to phosphate starvation. Front Plant Sci 9, 1432. DOI PMID
[14]	Wang ZY, Ruan WY, Shi J, Zhang L, Xiang D, Yang C, Li CY, Wu ZC, Liu Y, Yu YN, Shou HX, Mo XR, Mao CZ, Wu P (2014). Rice SPX1 and SPX2 inhibit phosphate starvation responses through interacting with PHR2 in a phosphate-dependent manner. Proc Natl Acad Sci USA 111, 14953-14958. DOI URL
[15]	Wild R, Gerasimaite R, Jung JY, Truffault V, Pavlovic I, Schmidt A, Saiardi A, Jessen HJ, Poirier Y, Hothorn M, Mayer A (2016). Control of eukaryotic phosphate homeostasis by inositol polyphosphate sensor domains. Science 352, 986-990. DOI URL
[16]	Zhou J, Jiao F, Wu Z, Li Y, Wang X, He X, Zhong W, Wu P (2008). OsPHR2 is involved in phosphate-starvation signaling and excessive phosphate accumulation in shoots of plants. Plant Physiol 146, 1673-1686. DOI PMID

既主内政, 又辖外交——以PHR为中心的基因网络调控植物-菌根真菌的共生

Managing Both Internal and Foreign Affairs—A PHR-centered Gene Network Regulates Plant-mycorrhizal Symbiosis

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