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Cover_978-3-642-22080-7
front-matter
Metal Toxicity in Plants: Perception, Signaling and Remediation
Preface
Reference
Contents
1 Heavy Metal Bindings and Their Interactions with Thiol Peptides and Other Biological Ligands in Plant Cells
Heavy Metal Bindings and Their Interactions with Thiol Peptides and Other Biological Ligands in Plant Cells
1 Introduction
2 Biological Ligands for Heavy Metal Conjugation and Detoxification in Plant Cells
2.1 Phytochelatins
2.2 Organic Acids, Nicotianamine, Amino Acids, and Phytates
2.3 Soluble Phenolics
3 Heavy Metal Localization and Distribution
3.1 Localization of Heavy Metals in Cells and Tissues of Different Plant Organs
3.2 Distribution of Heavy Metals and Conjugating Ligands in Root
3.3 Distribution of Heavy Metals and Conjugating Ligands in Shoots
4 Conclusion
References
2 Heavy Metal Perception in a Microscale Environment: A Model System Using High Doses of Pollutants
Heavy Metal Perception in a Microscale Environment: A Model System Using High Doses of Pollutants
1 Introduction
2 Microscale Versus Macroscale Analysis: Time Resolved Responses
3 ROS Signaling and Antioxidant Responses
4 Phytohormone Signaling Pathways
5 Conclusion
References
3 Genetic and Molecular Aspects of Metal Tolerance and Hyperaccumulation
Genetic and Molecular Aspects of Metal Tolerance and Hyperaccumulation
1 Introduction
1.1 Metals as Toxicants
1.2 Metals as Stressors
1.3 Defining Metal Tolerance
1.4 Defining Metal Accumulation
2 Genetic Aspects of Tolerance and Accumulation
2.1 Evidence from Classical Mendelian Genetics and Mutants
2.2 Evidence from Quantitative Genetics and Mapping
2.3 Evidence from Reverse Genetics and Genetic Engineering
2.4 Evidence from Natural Populations Variability
3 Molecular Aspects of Tolerance and Accumulation
3.1 Evidence from Physiology and Biochemistry
3.2 Evidence from Gene Cloning
3.2.1 Gene Copy Number
3.2.2 Gene Expression
3.2.3 Sequence Variants
3.2.4 Structural Information
3.3 Evidence from Transcriptomic Analysis
4 Conclusion
References
4 Cadmium and Copper Stress Induce a Cellular Oxidative Challenge Leading to Damage Versus Signalling
Cadmium and Copper Stress Induce a Cellular Oxidative Challenge Leading to Damage Versus Signalling
1 Introduction
1.1 Cadmium and Copper Uptake and Homeostasis
1.1.1 Uptake of Excess Cu and Cd by the Plant Is Unavoidable
1.1.2 Chelation and Sequestration of Excess Metals
1.2 The Perception of Cd and Cu Stress and the Generation of Excess Reactive Oxygen Species
1.2.1 Direct and Indirect Mechanisms of ROS Generation
1.2.2 Enzymatic ROS Generation
1.2.3 Cd and Cu Disturb Redox Homeostasis in Plant Organelles
1.2.4 Perception of the Stress Signal
2 The Oxidative Stress Signature Consists of Altered Redox-Related Gene Expression, Enzyme Activities and Metabolites, and Is Informative for the Oxidative Challenge Induced by Metals
2.1 Superoxide Scavenging by Superoxide Dismutases
2.2 H2O2 Scavenging: Catalases and Ascorbate Peroxidases
2.3 Detoxification of ROS Via the Ascorbate-Glutathione Cycle
2.4 Antioxidant Metabolites
2.5 Description of the Oxidative Stress Signature
3 The Oxidative Challenge Can Cause Damage and Trigger Signalling Pathways Leading to Acclimation Responses
3.1 Metal-Induced Oxidative Damage
3.2 The Cd- and Cu-Induced Oxidative Challenge Activates and Interferes with Signalling Pathways
3.3 Retrograde Signalling by Cellular Organelles
4 Conclusion
References
5 Insights into Cadmium Toxicity: Reactive Oxygen and Nitrogen Species Function
Insights into Cadmium Toxicity: Reactive Oxygen and Nitrogen Species Function
1 Introduction
2 Cadmium Toxicity in Plants
3 Plant Mechanisms to Cope with Cadmium
4 Transcriptomic and Proteomic Analyses Under Cadmium Stress
5 ROS Metabolism in Response to Cadmium
5.1 ROS Production Under Cd Stress
5.2 Antioxidant Systems Under Cd Stress
5.2.1 Enzymatic Antioxidants Systems
5.2.2 Non-enzymatic Antioxidants Systems
6 NO Metabolism in Response to Cadmium
6.1 NO Production Under Cd Stress
6.2 NO Function and Protection Under Cd Stress
7 Organelles Involvement in Cd Stress
8 Conclusion
References
6 Exploring the Plant Response to Cadmium Exposure by Transcriptomic, Proteomic and Metabolomic Approaches
Exploring the Plant Response to Cadmium Exposure by Transcriptomic, Proteomic and Metabolomic Approaches: Potentiality of High-Throughput Methods, Promises of Integrative Biology
1 Introduction
2 Global Response of Plants to Cadmium Exposure
2.1 Overview of a Cadmium Exposure in Plants as Evaluated by Transcriptomic, Proteomic and Metabolomic Approaches
2.1.1 Primary Metabolism
2.1.2 Defence Mechanisms
2.2 Transcriptomic Analysis Allow for Large Scale Comparisons Between Species and/or Treatment
3.4 Data Mining and Integration: The Bioinformatics Challenge
4 Conclusion
References
7 Proteomics as a Toolbox to Study the Metabolic Adjustment of Trees During Exposure to Metal Trace Elements
Proteomics as a Toolbox to Study the Metabolic Adjustment of Trees During Exposure to Metal Trace Elements
1 Introduction
2 Proteomics of Woody Species
2.1 Proteomics: General Considerations
2.1.1 Protein Extraction and Sample Preparation
2.1.2 2D-PAGE
2.1.3 Protein Identification
2.2 Case Study: Proteome Study of Poplar and Cd Pollution
3 Conclusion
References
8 Proteomics of Plant Hyperaccumulators
Proteomics of Plant Hyperaccumulators
1 Plant Hyperaccumulators
2 Methods in Plant Proteomics
2.1 Protein Extraction
2.2 Protein Separation
2.3 Protein Patterns Analysis and Protein Identification
3 Proteomic Approaches for Identification of Key Functions in the Hyperaccumulators
3.1 Proteins Involved in Plant-Soil Interaction
3.2 Root Proteome
3.3 Shoot Proteome
4 Follow-Up in Proteomic of Hyperaccumulators
5 Conclusion
References
9 Heavy Metal Toxicity: Oxidative Stress Parameters and DNA Repair
Heavy Metal Toxicity: Oxidative Stress Parameters and DNA Repair
1 Introduction
2 Oxidative Stress and Cell Defenses
3 DNA Repair Mechanisms: A General Overview
3.1 Base Excision Repair (BER)
3.2 Nucleotide Excision Repair (NER)
3.3 Mismatch Repair (MMR)
3.4 Double-Strand Break Repair
4 Heavy Metals
4.1 Arsenic
4.2 Cadmium
4.3 Chromium
4.4 Copper
4.5 Lead
4.6 Mercury
4.7 Selenium
4.8 Zinc
5 Heavy Metal Hyperaccumulator Phenotypes in Plants
6 Conclusion
References
10 Protein Oxidative Modifications
Protein Oxidative Modifications
1 Proteins as Molecular Targets of Oxidative Reactions
1.1 Protein Oxidative Products
2 Metals as Responsible of Protein Oxidation
2.1 Metals Ions-Catalyzed Oxidation Systems
2.2 Metalloproteins Susceptibility to Oxidative Stress
3 Metal Stress in Plants Is Associated to an Increase in Protein Carbonylation
3.1 Metals Catalyze Reactive Oxygen Species Generation Inside the Cell
4 Metals Can Alter Cell Metabolism by Mediating Protein Carbonylation
4.1 Regulation of the Translation of Isoforms: The Catalase
5 Carbonylated Protein Degradation
5.1 Role of Proteases
5.2 Role of 20S Proteasome
6 Conclusion
References
11 Zn/Cd/Co/Pb P1b-ATPases in Plants, Physiological Roles and Biological Interest
Zn/Cd/Co/Pb P1b-ATPases in Plants, Physiological Roles and Biological Interest
1 Introduction
1.1 P-ATPases Subfamily
1.2 Structure of the P1B-ATPases
2 Physiological Roles and Expression Profiles of Plant P1B-ATPases
2.1 HMA1
2.2 HMA6 and HMA8
2.3 HMA5
2.4 HMA7
2.5 HMA2, HMA4 and HMA3
2.5.1 HMA2 and HMA4
2.5.2 HMA3
3 Phylogeny
4 Biotechnological Interest
4.1 Biofortification
4.2 Interest in Phytoremediation
5 Conclusion
References
12 Interference of Heavy Metal Toxicity with Auxin Physiology
Interference of Heavy Metal Toxicity with Auxin Physiology
1 Introduction: Auxin as a Growth Regulator
2 Auxin: A Mediator Between Growth and Stress Adaptation
3 Auxin and Heavy Metal Stress
4 Auxin and Essential Metals
5 Conclusions
References
INDEX
Nội dung
[...]... Experimental Del Zaidin, CSIC, Granada 18008, Spain e-mail: guptadk1971@gmail.com D.K Gupta and L.M Sandalio (eds.), MetalToxicity in Plants: Perception,Signalingand Remediation, DOI 10.1007/978-3-642-22081-4_1, # Springer-Verlag Berlin Heidelberg 2012 1 2 M Inouhe et al lesser toxic binding forms and hence affecting their movements, transports, accumulations and their final fates in vivo inplants PCs have... different sites of the plant body including their consolidate bindings to polymeric ligands in the structures are compared to facilitate our understanding on the possible roles of PCs and non-PC ligands contained in them 4 M Inouhe et al 2 Biological Ligands for Heavy Metal Conjugation and Detoxification in Plant Cells 2.1 Phytochelatins To protect themselves from the toxicity of metal ions, plant cells have... Fig 2 Possible metal localization and presence of major metal- binding ligands in a model plant with a standard root, stem and shoot system In each organ, tissues and cells are conventionally divided into apoplasic and symplastic sites The former including xylem (sap) in the conductive tissues of each organ, and rizosphere connected to or surrounding the root system underground, and also in some cases... in coordination and storage of phosphate and metals such as Zn, Mg, and K in vacuole and cytoplasm and also in the detoxification of Cd has been widely suggested (Van Steveninck et al 1992; Hayden and Cobbett 2006) Amino acids are the most abundant amphoteric ions with variable forms and residues, existing in 10–100 mM orders of concentrations and serving multiple functions in plant cells Cysteine (Cys)... amide group consisting of both O- and N-donors (ÀCO-NH2) All these are generally rich in phloem sap, for example, at near 300 mM in cereals and 50 mM in some dicotyledonous plants (Oshima et al 1990; Winter et al 1992), and can be potential ligands for translocational metal cations Histidine (His) is the most characterized imidazole (¼NH)-containing Heavy Metal Bindings and Their Interactions with Thiol... the organic ligand’s interactions with metals in each site at different but almost constant pH conditions (Callahan et al 2006) Some bindings between metals and ligands are not specific and not stable, especially under varied pH and ion-strength conditions Conversely the regulated conditions can promise a unique and established mechanism for metal transport and binding systems in land plants 2.3 Soluble... respective metals in plants (Fig 1) The tolerance characteristics of plants to heavy metal ions are diverse among the metal ions involved (Foy et al 1978; Woolhouse 1983; Verkleij and Schat 1990) Especially a group of metals called “Borderline class” metals including Mn, Zn, Fe, Ni, Cd, Pb and Cu etc are capable of binding to multiple types of naturally occurring chemicals or components in plants, although... detoxification than wall bindings 3.2 Distribution of Heavy Metals and Conjugating Ligands in Root Besides bioavailability, uptake and translocation efficiencies determine metal accumulation and distribution in plants (Clemens 2006) Roots are the plant organs in closest contact with metal- contaminated soils; therefore, they are the most affected by metals Resistance to excess metals can be achieved by... contain amounts of heavy metals Overexpression of cysteine synthase confers Cd tolerance to tobacco, and the endogenous concentration of Cd was 20% less in transgenic plants than in wild-type plants The numbers of both long and short trichomes in the transgenic plants were 25% higher than in that of wild-type plants, indicating the active excretion of Cd from trichomes in transgenic plants (Harada and. .. sites may allow more variable and more complicated interactions between the metaland biological ligands in plants This might be a potential for the differentiation and specification of a unique hyperaccumulator to be evolved on ground Readjustment of both the symplastic and apoplastic activities including the formations of PC-dependent and -independent metal- binding ligands and their transport systems . h1" alt="" Metal Toxicity in Plants: Perception, Signaling and Remediation . Dharmendra K. Gupta • Luisa M. Sandalio Editors Metal Toxicity in Plants: Perception, Signaling and Remediation Editors Dharmendra. Gupta and L.M. Sandalio (eds.), Metal Toxicity in Plants: Perception, Signaling and Remediation, DOI 10.1007/978-3-642-22081-4_1, # Springer-Verlag Berlin Heidelberg 2012 1 lesser toxic binding. metal detoxification and tolerance. Potential ligands include amino acids, nicotianamine, phytochelatins and metallothioneins (Clemens 2001). Phytochelatins have been the most widely studied in