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Regulation of Cation Homeostasis in Plants

Carlos Tello Lacal

9781773610436
520 pages
Arcler Education Inc
Overview
Homeostasis can be defined in general terms as the active maintenance of the basal conditions of a system. The plant cell needs to control its cation homeostasis, that is to say tightly regulate the concentration of the main essential positively charged ions, such as K+, Ca2+ or Mg2+, as well as that of potentially toxic cations such as Na+, in order to maintain a balance allowing for the correct functioning of its metabolism, osmotic adjustment and nutrient acquisition. To this aim, plants employ a set of proteins including pumps, channels and transporters. This book contains a collection of peer-reviewed papers describing the main families of plant transporter proteins, with special emphasis on those regulating the uptake and distribution of K+ and its competitive inhibitor Na+. In Chapter number 1, the editor of the present book describes the main effects caused by salt stress and the main adaptive responses that plants have developed against it, in addition to providing an insight into the main families of cation pumps, channels and transporters. Chapter 2 presents a detailed overview of the main systems controlling the uptake of Na+ and K+ through the roots in both Arabidopsis and rice. Chapter 3 looks into the importance of K+ as a plant macronutrient with special emphasis on its role in protection against stress conditions. In turn, Chapter 4 briefly outlines the main proteins catalyzing sodium transport in plants. The isolation of a point mutation increasing the affinity of HAK5, the most important member of the KT/KUP/HAK family, for K+ while reducing that for Na+ and Cs+ is presented in Chapter 5. In Chapter 6, the main Arabidopsis voltage-dependent and voltage-independent K+ channels are studied. In vivo distribution, traffic and response to ion concentration of voltage-dependent channels is illustrated in Chapter 7 through the example of K+ outward GORK channel. The two families of non-selective cation channels, cyclic-nucleotide gated channels (CNGC) and glutamate receptors (GLR), are dealt with in Chapters 8 and 9, describing the salt-dependent regulation of the CNGC19/CNGC20 subfamily and the functional characterization of rice GLR, respectively. Chapter 10 reviews the HKT family of Na+ and K+ transporters. The following eight chapters explore the main families of plant cation/H+ antiporters. In Chapter 11, the latest findings on the phylogenetic analysis and protein structure of the CaCA family of Ca2+/H+ antiporters in both Arabidopsis and rice are briefly presented. Chapter 12 describes the evolutionary divergence of NHX and SOS1 proteins within the CPA1 family. In Chapter 13, an Arabidopsis quadruple mutant lacking all the vacuolar NHX transporters is generated to investigate the role of these proteins in K+ homeostasis and microtubule dynamics. Chapter 14 describes the identification and characterization of orthologs in Brassica napus of the Arabidopsis endosomal NHX proteins AtNHX5 and AtNHX6. In Chapter 15, the genes for the Na+/H+ antiporter SOS1 and the H+-ATPase AHA1 of the halophyte Sesuvium portulacastrum are cloned and heterologously expressed in S. cerevisiae in order to study their coordinated function. Finally, Chapter 16 consists of a review of the proteins involved in the uptake and transport of Mn cations. The present book intends to help college students, teachers, researchers and other readers interested in plant physiology better understand the mechanisms employed by plants to compensate transient imbalances in the levels of their main cations.
Author Bio
Carlos Tello (Valencia, Spain, 1981) studied Agricultural Engineering with specialization in Biotechnology at the Universidad Politécnica de Valencia, where he graduated with a BSc thesis on the characterization of an Arabidopsis mutant with increased tolerance to seed ageing and salt stress. He moved afterwards to Sevilla to complete his MSc and PhD at the Instituto de Recursos Naturales y Agrobiología, where he studied the mechanisms employed by plants in their adaptation to abiotic stress and more specifically the role of the Arabidopsis Na+/H+ antiporter SOS1 in the regulation of Na+ and K+ homeostasis. Since 2014, he is based in Zürich and develops several freelance science-related jobs. He has recently retrained himself in the field of cell culture in bioreactors by attending an advanced training course at the Zürcher Hochschule für Angewandte Wissenschaften.