Research Progress on Physiological Functions of Suberin lamellae in Water and Solutes Transport

doi:10.11983/CBB22208

Abstract

Abstract: Plant roots can acquire water and nutrients selectively from soil and transport them upwards to the aerial parts for plant growth and development. These functions are closely related to their anatomical structures. The radial transport of water and solutes absorbed by roots mainly includes three different pathways, namely, the apoplastic pathway, the symplastic pathway and the transcellular pathway. The endodermis is the innermost cell layer that surrounds the central vasculature. For a long time, endodermal differentiation formed the Casparian strips has been considered to play a decisive role in blocking water and solutes transport through the apoplastic pathway. However, in recent years, it has been found that suberin lamellae formed by endodermal differentiation plays no less important role in the radial transport of water and solutes than Casparian strips, and even that suberization is the second life of an endodermal cell. In this paper, we reviewed the latest research progress on the physiological function of suberin lamellae in water and solutes transport in recent years, and discussed the relationship between suberin lamellae and drought, salt, nutrient and heavy metal stress of crops, in order to provide a reference for the theory and practice of endodermal plasticity in the regulation of plant physiological function.

Key words: root, endodermis, suberin lamellae, water and solutes, physiological functions

Biao Zhang, Jian Wu, Yang Zhang, Xiaowei Dong, Shuo Han, Xin Gao, Congwu Du, Huiying Li, Xuefa Chong, Yingying Zhu, Haiwei Liu. Research Progress on Physiological Functions of Suberin lamellae in Water and Solutes Transport[J]. Chinese Bulletin of Botany, 2023, 58(6): 1008-1018.

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URL: https://www.chinbullbotany.com/EN/10.11983/CBB22208

https://www.chinbullbotany.com/EN/Y2023/V58/I6/1008

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References 70

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酶	物种	基因	参考文献
β-酮酯酰-CoA合成酶	东南景天	SaKCS20	Tao et al., 2019
ZIP转运体	东南景天	SaZIP1	Tao et al., 2019
HMA转运体	东南景天	SaHMA2	Tao et al., 2019
HMA转运体	东南景天	SaHMA4	Tao et al., 2019
细胞色素P450	拟南芥	AtCYP86A1/HORST	Wang et al., 2020
	印度红树	AoCYP94B1	Krishnamurthy et al., 2020
	印度红树	AoCYP94B3	Krishnamurthy et al., 2021
甘油-3-磷酸酰基转移酶	拟南芥	AtGPAT5	Hsu et al., 2021
甘油-3-磷酸酰基转移酶	东南景天	SaGPAT5	Tao et al., 2019
类蛋白	拟南芥	AtESB1	Kreszies et al., 2018
GDSL型酯酶/脂肪酶	拟南芥	AtGELP22	Ursache et al., 2021
	拟南芥	AtGELP38	Ursache et al., 2021
	拟南芥	AtGELP49	Ursache et al., 2021
	拟南芥	AtGELP51	Ursache et al., 2021
	拟南芥	AtGELP96	Ursache et al., 2021
ATP结合盒式蛋白	拟南芥	AtABCG1	Shanmugarajah et al., 2019
	拟南芥	AtABCG2	Shanmugarajah et al., 2019
	拟南芥	AtABCG6	Shanmugarajah et al., 2019
	拟南芥	AtABCG20	Shanmugarajah et al., 2019
	水稻	OsRCN1/ABCG5	Shiono et al., 2014
脂质转运蛋白	拟南芥	AtLTPI4	Deeken et al., 2016
脂质转运蛋白	拟南芥	AtLTPG15	Lee and Suh, 2018
MYB蛋白	拟南芥	AtMYB41	Shukla et al., 2021
	拟南芥	AtMYB107	Gou et al., 2017
	拟南芥	AtMYB9	Lashbrooke et al., 2016
	拟南芥	AtMYB39/SUBERMAN	Cohen et al., 2020
	拟南芥	AtMYB53	Shukla et al., 2021
	拟南芥	AtMYB92	Shukla et al., 2021
	拟南芥	AtMYB93	Shukla et al., 2021
	拟南芥	AtMYB70	Wan et al., 2021

酶	物种	基因	参考文献
β-酮酯酰-CoA合成酶	东南景天	SaKCS20	Tao et al., 2019
ZIP转运体	东南景天	SaZIP1	Tao et al., 2019
HMA转运体	东南景天	SaHMA2	Tao et al., 2019
HMA转运体	东南景天	SaHMA4	Tao et al., 2019
细胞色素P450	拟南芥	AtCYP86A1/HORST	Wang et al., 2020
	印度红树	AoCYP94B1	Krishnamurthy et al., 2020
	印度红树	AoCYP94B3	Krishnamurthy et al., 2021
甘油-3-磷酸酰基转移酶	拟南芥	AtGPAT5	Hsu et al., 2021
甘油-3-磷酸酰基转移酶	东南景天	SaGPAT5	Tao et al., 2019
类蛋白	拟南芥	AtESB1	Kreszies et al., 2018
GDSL型酯酶/脂肪酶	拟南芥	AtGELP22	Ursache et al., 2021
	拟南芥	AtGELP38	Ursache et al., 2021
	拟南芥	AtGELP49	Ursache et al., 2021
	拟南芥	AtGELP51	Ursache et al., 2021
	拟南芥	AtGELP96	Ursache et al., 2021
ATP结合盒式蛋白	拟南芥	AtABCG1	Shanmugarajah et al., 2019
	拟南芥	AtABCG2	Shanmugarajah et al., 2019
	拟南芥	AtABCG6	Shanmugarajah et al., 2019
	拟南芥	AtABCG20	Shanmugarajah et al., 2019
	水稻	OsRCN1/ABCG5	Shiono et al., 2014
脂质转运蛋白	拟南芥	AtLTPI4	Deeken et al., 2016
脂质转运蛋白	拟南芥	AtLTPG15	Lee and Suh, 2018
MYB蛋白	拟南芥	AtMYB41	Shukla et al., 2021
	拟南芥	AtMYB107	Gou et al., 2017
	拟南芥	AtMYB9	Lashbrooke et al., 2016
	拟南芥	AtMYB39/SUBERMAN	Cohen et al., 2020
	拟南芥	AtMYB53	Shukla et al., 2021
	拟南芥	AtMYB92	Shukla et al., 2021
	拟南芥	AtMYB93	Shukla et al., 2021
	拟南芥	AtMYB70	Wan et al., 2021