Phenotyping crop plants for physiological and biochemical traits

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Phenotyping crop plants for physiological and biochemical traits

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Phenotyping Crop Plants for Physiological and Biochemical Traits Page left intentionally blank Phenotyping Crop Plants for Physiological and Biochemical Traits P Sudhakar Department of Crop Physiology S V Agricultural College Acharya N G Ranga Agricultural University Tirupati, A.P., India P Latha Institute of Frontier Technology Regional Agricultural Research Station Acharya N G Ranga Agricultural University Tirupati, A.P., India P.V Reddy Regional Agricultural Research Station Acharya N G Ranga Agricultural University Tirupati, A.P., India AMSTERDAM • BOSTON • HEIDELBERG • LONDON NEW YORK • OXFORD • PARIS • SAN DIEGO SAN FRANCISCO • SINGAPORE • SYDNEY • TOKYO Academic Press is an imprint of Elsevier Academic Press is an imprint of Elsevier 125 London Wall, London EC2Y 5AS, UK 525 B Street, Suite 1800, San Diego, CA 92101-4495, USA 50 Hampshire Street, 5th Floor, Cambridge, MA 02139, USA The Boulevard, Langford Lane, Kidlington, Oxford OX5 1GB, UK Copyright © 2016 BSP Books Pvt Ltd Published by Elsevier Inc All rights reserved Distributed in India, Pakistan, Bangladesh, and Sri Lanka by BS Publications No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher Details on how to seek permission, further information about the Publisher’s permissions policies and our arrangements with organizations such as the Copyright Clearance Center and the Copyright Licensing Agency, can be found at our website: www.elsevier.com/permissions This book and the individual contributions contained in it are protected under copyright by the Publisher (other than as may be noted herein) Notices Knowledge and best practice in this field are constantly changing As new research and experience broaden our understanding, changes in research methods, professional practices, or medical treatment may become necessary Practitioners and researchers must always rely on their own experience and knowledge in evaluating and using any information, methods, compounds, or experiments described herein In using such information or methods they should be mindful of their own safety and the safety of others, including parties for whom they have a professional responsibility To the fullest extent of the law, neither the Publisher nor the authors, contributors, or editors, assume any liability for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions, or ideas contained in the material herein British Library Cataloguing-in-Publication Data A catalogue record for this book is available from the British Library Library of Congress Cataloging-in-Publication Data A catalog record for this book is available from the Library of Congress ISBN: 978-0-12-804073-7 For information on all Academic Press publications visit our website at https://www.elsevier.com/ Publisher: Nikki Levy Acquisition Editor: Nancy Maragioglio Editorial Project Manager: Billie Jean Fernandez Production Project Manager: Nicky Carter Designer: Matthew Limbert Typeset by Thomson Digital Contents Message xi Foreword xiii Preface .xv Abbreviations xvii Introduction xix SECTION I CHAPTER Various Methods of Conducting Crop Experiments 1.1 Field Experiments 1.2 Experiments Under Green Houses 1.2.1 Demerits 1.3 Experiments in Growth Chambers 1.3.1 Demerits 1.4 Hydroponics 1.4.1 Precautions 1.5 Pot Culture SECTION II CHAPTER Seed Physiological and Biochemical Traits 17 2.1 Destructive Methods 17 2.1.1  Seed Viability .17 2.1.2  Seed Vigor Tests 18 2.2 Nondestructive Methods 21 2.2.1  X-ray Analysis 21 2.2.2  Electrical Impedance Spectroscopy (EIS) 22 2.2.3  Multispectral Imaging 22 2.2.4  Microoptrode Technique (MOT) .22 2.2.5  Infrared Thermography (IRT) 23 2.2.6 Seed Viability Measurement Using Resazurin Reagent������������������������������������������������������������������������������� 23 2.2.7  Computerized Seed Imaging 23 SECTION III CHAPTER Plant Growth Measurements 27 3.1 Measurement of Growth 27 3.2 Measurement of Below Ground Biomass 27 v vi Contents 3.3 Growth Analysis 28 3.3.1 Growth Characteristics—Definition and Mathematical Formulae�����������������������������������������������������������������������������29 CHAPTER Photosynthetic Rates 33 4.1 Net Assimilation Rate (NAR) 33 4.2 Measuring Through Infrared Gas Analyzer (IRGA) 33 4.3 Rubisco Enzyme Activity 37 4.3.1  Measurement of Rubisco Activity .37 4.4 Chlorophyll Fluorescence Ratio (Fv/Fm Values) 39 CHAPTER Drought Tolerance Traits 41 5.1 Water Use Efficiency (WUE) Traits 41 5.1.1  Carbon Isotope Discrimination 48 5.1.2 Determination of Stable Carbon Isotopes Using Isotope Ratio Mass Spectrometer (IRMS)�������������������������� 48 5.1.3 Protocol for Carbon Isotope Discrimination in Leaf Biomass������������������������������������������������������������������ 49 5.2 Root Traits 50 CHAPTER Other Drought-Tolerant Traits 53 6.1 Relative Water Content (RWC) 53 6.2 Chlorophyll Stability Index (CSI) .53 6.3 Specific Leaf Nitrogen (SLN) 54 6.4 Mineral Ash Content 55 6.5 Leaf Anatomy 55 6.6 Leaf Pubescence Density 56 6.7 Delayed Senescence or Stay-Greenness 56 6.8 Leaf Waxiness 57 6.9 Leaf Rolling 58 6.10 Leaf Thickness (mm) 58 6.11 Stomatal Index and Frequency 58 6.12 Other Indicators for Drought Tolerance .59 6.13 Phenological Traits 59 CHAPTER Tissue Water Related Traits 61 7.1 Osmotic Potential 61 7.1.1 Determination of Osmotic Potential Using Vapor Pressure Osmometer�������������������������������������������������������������������������� 62 7.2 Leaf Water Potential 63 7.3 Relative Water Content 64 Contents 7.4 Cell Membrane Injury 64 7.4.1 Cell Membrane Permeability Based on Leakage of Solutes from Leaf Samples��������������������������������������������� 64 CHAPTER Heat Stress Tolerance Traits 67 8.1 Canopy Temperature 67 8.2 Chlorophyll Stability Index (CSI) .68 8.3 Chlorophyll Fluorescence 68 8.4 Thermo Induction Response (TIR) Technique 69 8.5 Membrane Stability Index 71 8.5.1 Membrane Permeability Based on Leakage of Solutes from Leaf Samples�������������������������������������������������������������� 71 CHAPTER Oxidative Stress Tolerance Traits 73 9.1 Oxidative Damage .73 9.1.1  Antioxidant Enzymes 74 9.2 Superoxide Dismutase (SOD) 74 9.3 Catalase 75 9.4 Peroxidase (POD) 77 9.5 Free Radicals 78 CHAPTER 10 Salinity Tolerance Traits 81 10.1 Chlorophyll Stability Index 81 10.2 Proline 81 10.3 Sodium (Na) and Potassium (K) Ratio 82 10.3.1  Potassium (K) 82 10.3.2  Sodium (Na) 83 10.4 Antioxidative Enzymes 84 SECTION IV CHAPTER 11 Kernel Quality Traits 87 11.1 Proteins 87 11.1.1  Protein Estimation by Lowry Method 88 11.1.2 Protein Estimation by Bradford Method �������������������������� 89 11.2 Kernel Oil 90 11.2.1  Oil Estimation by Soxhlet Apparatus (SOCS) 90 11.3 Aflatoxins 91 11.3.1  Quantification of Aflatoxin Levels in Kernels 91 vii viii Contents CHAPTER 12 Carbohydrates and Related Enzymes 95 12.1 Reducing Sugars 95 12.2 Nonreducing Sugars .96 12.3 Total Carbohydrates .96 12.4 Estimation of Sucrose Phosphate Synthase 97 12.5 Estimation of Starch Synthase 99 12.6 Estimation of Invertases .100 CHAPTER 13 Nitrogen Compounds and Related Enzymes .103 13.1 Total Nitrogen 103 13.1.1 Kjeldhal Method for Quantifying Leaf Nitrogen Content������������������������������������������������������������ 103 13.1.2  Preparation of Reagents 104 13.1.3 Protein Percent can be Determined Indirectly Using the Following Formula�����������������������������������������104 13.2 Total Free Amino Acids .105 13.3 Nitrate Reductase 106 13.4 Nitrite Reductase 108 13.5 Leghemoglobin (Lb) 109 13.6 Glutamic Acid Dehydrogenase (GDH) 110 13.7 Glutamate Synthase (GOGAT) 111 13.8 Glutamine Synthetase (GS) 112 13.8.1 Calculation 114 CHAPTER 14 Other Biochemical Traits 115 14.1 Total Phenols 115 14.2 Ascorbic Acid 116 14.3 Alcohol Dehydrogenase (ADH) 118 14.4 Glycine Betaine 119 CHAPTER 15 Plant Pigments 121 15.1 Chlorophylls 121 15.1.1  Estimation of Chlorophyll .121 15.2 Carotenoids 123 15.2.1  Quantification of Carotenoids in Green Leaves .123 15.3 Lycopene 126 15.4 Anthocyanin .127 CHAPTER 16 Growth Regulators .129 16.1 Estimation of Indole Acetic Acid (IAA) 129 16.2 Estimation of Gibberellins 130 Contents 16.3 Estimation of Abscisic Acid (ABA) 131 16.4 Estimation of Ethylene 133 SECTION V CHAPTER 17 Analytical Techniques .137 17.1 Ultraviolet Visible (UV–VIS) Spectrophotometer .137 17.2 Thin Layer Chromatography (TLC) 138 17.3 Gas Chromatography (GC) 140 17.3.1 Introduction 140 17.3.2 Principle 140 17.3.3 Detectors 141 17.4 High-Performance Liquid Chromatography (HPLC) 142 17.4.1  Role of Five Major HPLC Components 143 17.5 Liquid Chromatography–Mass Spectrometry (LC–MS, or Alternatively HPLC–MS)���������������������������������������144 17.5.1  Flow Splitting 145 17.5.2  Mass Spectrometry (MS) 145 17.5.3  Mass Analyzer 146 17.5.4 Interface 146 17.5.5 Applications 146 17.6 Inductively Coupled Plasma Spectrometry (ICP) (Soil & Plant Analysis Laboratory University of Wisconsin–Madison http://uwlab.soils.wisc.edu)�����������������������147 17.6.1 Introduction 147 17.6.2  Summary of Method 147 17.6.3 Safety 148 17.6.4 Interference 148 17.6.5  Measurement by ICP-OES 148 17.6.6 Measurement 148 17.6.7  Measurement by ICP-MS 148 17.6.8 Measurement 149 Appendices���������������������������������������������������������������������������������������151 Common Buffers 151 Appendix I: Citrate Buffer 151 Appendix II: Sodium Phosphate Buffer 152 Appendix III: Potassium Phosphate Buffer 152 Appendix IV: Sodium Acetate Buffer 153 Appendix V: Tris–HCl Buffer (Tris–Hydroxymethyl Aminomethane Hydrochloric Acid Buffer) 153 ix References Dwyer, L., Anderson, M.A.M., Ma, B.L., Stewart, 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submitted to the University of Agricultural Sciences, Bangalore, India Sternberg, L.S.L., De Niro, M.J., Savidge, R.A., 1986 Oxygen isotope exchange between metabolites and water during biochemical reactions leading to cellulose synthesis Plant Physiol 82, 423–427 Stobiecki, M., Skirycz, A., Kerhoas, L., Kachlicki, P., Muth, D., Einhorn, J., Mueller-Roeber, B., 2006 Profiling of phenolic glycosidic conjugates in leaves of Arabidopsis thaliana using LC/MS Metabolomics (4), 197 Sudhakar, P., Babitha, M., Latha, P., Prasanthi, L., Reddy, P.V., 2006 Thermostability of cell membrane and photosynthesis in blackgram genotypes differing in heat tolerance J Arid Legumes (2), 11–16 References Sudhakar, P., Latha, P., Babita, M., Prasanthi, L., Reddy, P.V., 2006 Physiological traits contributing to grain yields under drought in black gram and green gram Indian J Plant Physiol PP 11, 391–396 Sudhakar, P., Latha, P., Muneendrababu, A., 2010 Evaluation of sugarcane genotypes for high water use efficiency and thermo stability tolerance under imposed moisture stress at formative stage Sugar Tech 12 (1), 72–75 Sudhakar, P., Latha, P., Ramesh Babu, P., Sujatha, K., Raja Reddy, K., 2012 Identification of thermotolerant rice genotypes at seedling stage using TIR technique in pursuit of global warming Indian J Plant Physiol 17 (2), 185–188 Sun, W., Bernard, C., van de Cotte, B.M., Van Montagu, M., Verbruggen, N., 2001 AtHSP17.6A, encoding a small heat shock protein in Arabidopsis can enhance osmotolerance upon overexpression Plant J 27, 407–415 Swaminathan, M.S., 2005 Towards an ever-green revolution In: Tuberosa, R., Phillips, R.L., Gale, M (Eds.), In: Proceedings of the International Congress: In the Wake of the Double Helix: From the Green Revolution to the Gene Revolution 27–31 Avenue Media, Bologna, Italy, pp 25–36 Takebe, M., Yoneyama, T., Inada, K., Murakam, T., 1990 Spectral reflectance of rice canopy for estimating crop nitrogen status Plant Soil 122, 295–297 Tandon, H.L.S Ed., 1993 Methods of analysis of soils, Plants, waters and fertilizers Fertilisers Development and Consultation Organisation, New Delhi, India 144 Tang, G.Q., Luscher, M., Sturm, A., 1999 Antisense repression of vacuolar and cell wall invertase in transgenic carrot alters early plant development and sucrose partitioning Plant Cell 11, 177–189 Tangpremsri, T., Fukai, S., Fische, K.S., 1995 Growth and yield of sorghum lines extracted from a population for differences in Philippines Osmotic adjustment Aust J Agric Res 46, 61–74 Tempest, D.W., Meers, J.C., Brown, C.M., 1970 Synthesis of glutamate in aerobactor aerogenes by a hitherto known roots Biochem J 117, 405 Thomas, H., Smart, C.M., 1993 Crops that stay green Ann Appl Biol 123, 193–219 Towill, L.E., Mazur, P., 1975 Studies on the reduction of 2,3,5-triphenyltetrazolium chloride as a viability assay for plant tissue culture Canad J Botany 53, 1097–1102 Tuberosa, R., Salvi, S., 2004 QTLs and genes for tolerance to abiotic stress in cereals In: Gupta, P.K., Varshney, R (Eds.), Cereal Genomics Kluwer, Dordrecht, The Netherlands, pp 253–315 Turner, N.C., Wright, G.C., Siddque, K.H.M., 2001 Adaptation of grain legumes (pulses) to water limited environments Adv Agronomy 71, 193–231 Udayakumar, M., Bhojaraja, R., Sheshshayee, M.S., Gopalakrishsna, R., Jacob, J., 1999 How plants cope with excess light? The role of ferritin J Plant Biol 26, 135–142 Udayakumar, M., Rao, R.C.N., Wright, G.C., Ramaswamy, G.C., Ashok Roy, S., Gangadhar, G.C., Aftab Hussain, I.S., 1998 Measurement of transpiration efficiency in field condition J Plant Biol 1, 69–75 Vasanthi, R.P., Reddy, P.V., Jaya lakshmi, V., Sudhakar, P., Asalatha, M., Sudhakar Reddy, P., Harinatha Naidu, P., Muralikrishna, T., Venkateswarulu, O., John, K., Basu, M.S., Nigam, S.N., Nageswara Rao, R.C., Wright, G.C., 2006 A high-yielding drought-tolerant ground variety Abhaya Int Arachis Lett 26, 15–16, 2006 Vega, J.M., Jacobo, C., Manuel, L., 1980 In: Anthony San Pietro (Ed.), Methods in Enzymology Academic Press, New York, 255 165 166 References Venuprasad, R., Shashidhar, H.E., Hittalmani, S., Hemamalini, G.S., 2002 Tagging quantitative trait loci associated with grain yield and root morphological traits in rice (Oryza sativa L) under contrasting moisture regimes Euphytica 128, 293–300 Verma, D.P.S., 1999 Osmotic stress tolerance in plants: role of proline and sulphur metabolism In: Shinozaki, K., Yamaguchi Shinozaki, K (Eds.), Molecular Response to Cold Drought Heat Salt Stress in Higher Plants R G lands Company, Texas, USA, pp 153–168 Watson, D.J., 1952 The physiological basis of variation in yield Advances in Agronomy Williams, R.F., 1964 The quantitative description of growth In: Barnard, C (Ed.), Grasses and Grasslands Macmillan, London, pp 89–101 Wogan, G.N., 1999 Aflatoxin as a human carcinogen Hepatology 30, 573–575 Wright, G.C., Hammer, L., 1994 Distribution of nitrogen and radiation use efficiency in peanut canopies Austral J Agric Res 45, 565–574 Wright, G.C., Rao, R.C.N., Farquhar, G.D., 1994 Water-use efficiency and carbon isotope discrimination in peanut under water deficit conditions Crop Sci 34, 92–97 Xia Xin, Wan, Y., Wang, W., Yin, G., McLamore, E.S., Lu, X., 2013 A real-time, non-invasive, microoptrode technique for detecting seed viability by using oxygen influx Scientific Reports 3, Article number: 3057: Nature publishing group Zeevaart, J.A.D., 1980 Change in the level of abscisic acid and its metabolites in excised leaf blades of Xanthium strumarium during and after stress Plant Physiol 66, 672–678 Index A B ABA See Abscisic acid (ABA) Abscisic acid (ABA), 131 calculation, 132 chemicals required, 131 estimation in leaves, 131, 132 extraction, 132 preparation of reagents, 132 sample collection, 131 sample preparation, 132 solvents, 132 ADH See Alcohol dehydrogenase (ADH) Aflatoxins, 91 chromatogram showing standard aflatoxin peaks, 93 permissible value in India, 92 quantification of levels in kernels, 91–94 chemicals required, 92 extraction of sample, 92 HPLC instrument set-up protocol for estimation of aflatoxin, 93 immune-affinity column clean-up, 93 instrument set-up protocol for aflatoxin estimation, 94 types of afl atoxins reported, 91 Alcohol dehydrogenase (ADH), 118–119 measurement, 118 calculation, 119 estimation, 119 extraction, 119 preparation of reagents, 119 principle, 118 required chemicals, 118 Analytical techniques See various techniques Anthocyanins, 127 calculation, 127 chemicals required, 127 extraction, 127 measurement, 127 reagent preparation, 127 Anthrone reagent, 97 Antioxidant enzymes, 74 Anti oxidative enzymes, 84 Ascorbic acid, 116–118 method for estimation, 116 colorimetric method, 117–118 titration method, 116–117 Aspergillus flavus, 91 Biochemical tests, 20 Biofortification, 87 Bradford method, 89 Bradford reagent, 90 calculation, 90 chemicals required, 89 estimation, 90 extraction, 90 preparation of reagents, 90 principle, 89 C Canopy temperature, 67–68 Carbohydrates, 95 measurement, 96 calculation, 97 chemicals required, 97 estimation, 97 extraction, 97 preparation of reagents, 97 principle, 96 Carbon isotope discrimination, 48, 49 collection of soil sample, 49 preparation of sample, 49 ratios, 48 Carboxylation, 48 Carotenoids, 123 quantification in green leaves, 123 by HPLC method, 123–126 by UV–VIS spectrophotometer method, 126 Catalase, 75–77 Cell membrane injury, 64 Cell membrane permeability, 64 based on leakage of solutes from leaf samples, 64–65 Checklist, with recommended basic and additional data, 11 Chlorophyll fluorescence, 68 Chlorophyll fluorescence ratio (FV/FM values), 39 Chlorophylls, 121 estimation of, 121 by acetone method, 121–122 By DMSO (dimethyl sulfoxide) method, 122 167 168 Index Chlorophyll stability index (CSI), 53, 68, 81 calculation, 54 chemicals required, 54 estimation, 54 principle, 54 CO2 cartridge, 34 Coefficient of velocity of germination (CV), 19 Computerized seed imaging, 23 CSI See Chlorophyll stability index (CSI) D Dehydrogenase activity, 20 Delayed senescence or stay-greenness, 56 Drought index (DI), 59 Drought tolerance in crop genotypes, 41 indicators for, 59 E EC See Electrical conductivity (EC) EIS See Electrical impedance spectroscopy (EIS) Electrical conductivity (EC), 20 Electrical impedance spectroscopy (EIS), 22 Ethylene, 133 estimation of, 133 gas chromatograph, ideal operating conditions for, 133 sample collection, 133 Experiments under green houses, demerits, in growth chambers, demerits, F Field experiments, demerits of field experiments, implications in row and plot experiments, phenotyping in the field, plot experiments, row plantings, weather measurements, merits of field experiments, plot type and size, with Rainout Shelter facility, selection of site, weather measurements portable weather station, stable weather station, Field vs controlled environments in relation to physiological traits advantages and disadvantages of, 12 Flame photometry, 82–83 Folin–Ciocalteau reagent, 115 Free radicals, 78–79 hydrogen peroxide (H2O2 ), 79 superoxide (O2–) ion, 78 FV/FM values See Chlorophyll fluorescence ratio (FV/FM values) G Gas chromatography (GC), 140 detectors, 141 electron capture detector, 142 flame ionization detector, 141 thermal conductivity detector, 141 principle, 140–141 GC See Gas chromatography (GC) GDH See Glutamic acid dehydrogenase (GDH) Genotypic variability, 17 Germination value (GV), 19 Gibberellins, 130 quantitative estimation of, 130 calculation, 132 chemicals required, 130 extraction, 131 gas liquid chromatography, 131 preparation of reagents, 130 Glutamate synthase (GOGAT), 103, 111 chemicals required, 111 estimation, 112 extraction, 112 measurement, 111 preparation of reagents, 111 Glutamic acid dehydrogenase (GDH), 110 calculation, 111 chemicals required, 110 estimation, 111 extraction, 110 preparation of reagents, 110 Glutamic acid dehyrogenase (GDH), 103 Glutamine synthetase (GS), 103, 112 calculation, 114 chemicals required, 113 estimation, 113 extraction, 113 preparation of reagents, 113 principle, 112 g-Glutamyl hydroxamate, 112, 114 Glycine betaine, 119–120 chemicals required, 120 estimation, 120 extraction, 120 preparation of reagents, 120 principle, 120 Index GOGAT See Glutamate synthase (GOGAT) GS See Glutamine synthetase (GS) GV See Germination value (GV) H Hetero atomic molecules, 33 High-performance liquid chromatography (HPLC), 142 components, role of, 143–144 autosampler (injector), 143 column, 143 detectors, 144 pump, 143 principle, 142 HPLC See High-performance liquid chromatography (HPLC) HPLC-MS See Liquid chromatography-mass spectrometry (LC-MS) Hydroponics, experiment, precautions, Hydroxyl radical (OH−), 73 Hydroxymethyl furfural, 96 I IAA See Indole acetic acid (IAA) ICP See Inductively coupled plasma spectrometry (ICP) ICP-MS See Inductively coupled plasma mass spectrometry (ICP-MS) ICP-OES See Inductively coupled plasma optical emission spectrometry (ICP-OES) Indole acetic acid (IAA), 129 chemicals required, 129 estimation, 130 estimation of, 129 extraction, 129 preparation of reagents, 129 Inductively coupled plasma mass spectrometry (ICP-MS), 147 interference, 148 sample preparation, 148 Inductively coupled plasma optical emission spectrometry (ICP-OES), 147 interference, 148 sample preparation, 148 Inductively coupled plasma spectrometry (ICP), 147 Infrared gas analyzer, 35 working procedure (LI 6400), 34 parameters recorded from, 37 shutdown, 36 starting, 34–36 Infrared gas analyzers (IRGA), 33 Infrared thermography (IRT), 22 Infrared thermometer (IRT), 67 Interference, 148 Invertases estimation, 100, 102 cell wall invertase, 101 chemicals required, 101 extraction, 101 preparation of reagents, 101 principle, 100 soluble invertase, 101 IRGA See Infrared gas analyzers (IRGA) K Kernel oil, 90 Kjeldhal method chemicals required, 103 preparation of reagents, 104 calculation, 104 digestion, 104 distillation, 104 receiver solution, 104 principle, 103 protein percent determined indirectly using following formula, 104 for quantifying leaf nitrogen content, 103 L Laboratory safety procedures, 148 LB See Leghaemoglobin (LB) LC-MS See Liquid chromatography-mass spectrometry (LC-MS) Leaf anatomy, 55 Leaf proline content (LPC), 81 Leaf pubescence density, 56 Leaf rolling, 58 Leaf thickness, 58 Leaf water potential, 63 determination by pressure bomb, 63 principle, 63 procedure, 64 Leaf waxiness, 57–58 wax content determination colorimetric analysis, 57 gravimetric analysis, 57 LED See Light-emitting diode (LED) Leghemoglobin (LB), 109 chemicals required, 109 estimation, 110 extraction, 109 functions of, 109 preparation of reagents, 109 principle, 109 169 170 Index Light-emitting diode (LED), 34 Lipid peroxidation, 21 Liquid chromatography–mass spectrometry (LC-MS), 144 applications, 146 pharmacokinetics, 146 proteomics/metabolomics, 146 flow splitting, 145 interface, 146 mass analyzer, 146 mass spectrometry (MS), 145 Lowry method, 88 calculation, 89 chemicals required, 88 estimation, 89 extraction, 88 preparation of reagents, 88 principle, 88 Lycopene, 126 calculation, 127 chemicals required, 126 estimation, 127 extraction, 126 principle, 126 Lysine, 87 M Malondialdehyde (MDA), 21 Mass-to-charge ratio (m/z), 52 Mean daily germination, 19 Mean days of germination, 19 Membrane stability index, 71 membrane permeability based on leakage of solutes from leaf samples, 71 percentage leakage calculation, 71 Micro-optrode technique (MOT), 22 Mineral ash content, 55 Multispectral imaging, 22 N NADH-dependent NR, 106 NAR See Net assimilation rate (NAR) Net assimilation rate (NAR), 33 Ninhydrin agent, 105 Nitrate reductase, 106 calculation, 108 chemicals required, 107 estimation, 107 extraction, 107 measurement, 106 preparation of reagents, 107 Nitrite reductase, 108 calculation, 109 chemicals required, 108 estimation, 108 extraction, 108 preparation of reagents, 108 Nondestructive methods, 21 Nonreducing sugars, 96 Nutrient availability, 10 Nutritional quality, 87 O OA See Osmotic adjustment (OA) Oil estimation by soxhlet apparatus (SOCS), 90–91 chemicals required, 91 procedure, 91 Osmotic adjustment (OA), 61 Osmotic potential, 61 determination using vapor pressure osmometer, 62 procedure, 62 protocol sample loading and measurement, 63 sample preparation, 63 Oxidative damage, 73 P Peak value, 19 Peroxidase (POD), 77–78 Phenological traits, 59 flowering date, 59 flowering delay, 60 Phenotypic responses, of plants, pH, of hydroponic solution, Photochemical energy, 73 Photosynthetic efficiency, 33 Photo system II (PS II), 73 Plant growth measurements, 27 growth analysis, 28 growth characteristics, 29 crop growth rate (CGR), 29 harvest index (HI), 31 leaf area duration (LAD), 30 leaf area index (LAI), 30 leaf area ratio (LAR), 30 leaf weight ratio (LWR), 30 net assimilation rate (NAR), 29 relative growth rate (RGR), 29 specific leaf area (SLA), 30 specific leaf weight (SLW), 30 measurement of below ground biomass, 27 Index process of root biomass, 28 extraction of root, 28 measurement of dry weight, 28 removal of dead material, 28 washing, 28 parameters, 27 area, 27 dry weight, 27 fresh weight, 27 length, 27 Portable photosynthesis system, 34 Potassium (K), 82 determination, 82 di-acid digestion, 83 estimation in plant samples, 83 instrumentation, 83 standard curve, 83 standard stock solution, 83 Pot culture, experiment, overlooked factors in, precautions, 10 Proline, 81 calculation, 82 chemicals required, 82 estimation, 82 extraction, 82 preparation of reagent, 82 principle, 81 Proteins, 87 estimation by Bradford method, 89 Lowry method, 88 Q Quality, 87 R Reactive oxygen species (ROS), 73, 74–75 Reducing sugars, 95 estimation of, 95 dinitrosalicylic acid method, 95 calculation, 96 chemicals required, 95 estimation, 96 extraction, 96 preparation of reagent, 95 Relative water content (RWC), 53, 64 Root damage, 10 Root traits, 50 phenotyping for high root traits, 50 direct method, 50–51 construction of root structures, 50 experimenting on root structures, 50 raised soil bed method (root structure), 50 indirect method, 51–52 protocol for quantification of 18O composition in leaf biomass, 52 stable oxygen isotope, 51 ROS See Reactive oxygen species (ROS) Rubisco enzyme activity, 37 measurement of, 37 calculation, 38 chemicals required, 37 estimation, 38 extraction, 38 principle, 37 RWC See Relative water content (RWC) S Salinity, 81 Seed germination test, 18 Seedling vigor index (SVI), 18 Seed viability, 17 measurement using resazurin reagent, 23 tests, 17 Seed vigor tests, 18 SLN See Specific leaf nitrogen (SLN) SOCS See Oil estimation by soxhlet apparatus (SOCS) Sodium (NA), 83 estimation in plant samples, 84 preparation of standard, 83 principle, 83 Soluble starch synthase (SSS), 99 Soybean, 87 SPAD chlorophyll meter, 47 SPAD chlorophyll meter reading (SCMR), 46 Specific leaf nitrogen (SLN), 54 Stable carbon isotopes, determination using isotope ratio mass spectrometer (IRMS), 48 Starch synthase, estimation of, 99 assay medium, 99 chemicals required, 99 estimation, 100 extraction, 99 Leloir and Goldenberg’s method, 99 preparation of reagents, 99 principle, 99 Stomatal index, 58 procedure, 59 171 172 Index Sucrose phosphate synthase, 97 chemicals required, 98 estimation, 98 estimation of, 97 extraction, 98 preparation of reagents, 98 Sulfuric acid test, 18 Superoxide dismutase (SOD), 73, 74 SVI See Seedling vigor index (SVI) T Tetrazolium test, 17 Thermo induction response (TIR) technique, 69–71 parameters recorded from seedlings, 71 procedure, 70 identification of lethal temperature treatment, 70 sublethal (induction) temperatures, 70 thermo induction response (TIR), 70 Thin layer chromatography (TLC), 138 calculation, 139 chemicals required, 139 preparation of sample, 139 preparation of silica gel and silica gel plates, 139 preparation of solvent system, 139 preparation of spraying reagent, 139 principle, 138 procedure, 139 RF value, 139 TIR technique See Thermo induction response (TIR) technique TLC See Thin layer chromatography (TLC) Total carbohydrates, 96 Total free amino acids, 105 calculation, 106 chemicals required, 105 estimation, 106 extraction, 106 measurement, 105 principle, 105 preparation of reagents, 105 Total nitrogen, 103 Total phenols, 115 calculation, 116 chemicals required, 115 estimation, 116 extraction, 115 preparation of reagent, 115 principle, 115 2,3,5-Triphenyl tetrazolium chloride (TTC), 17 U Ultraviolet visible (UV–VIS) spectrophotometer, 137, 138 objective, 137 principle, 137 wavelength, color, and complementary color, 138 V Vapor pressure deficit (VPD), 51 Vitamin C See Ascorbic acid W Water-soluble amino acids, 20 Water-soluble sugars, 20 Water use efficiency (WUE) traits, 41 grain yield, 41 variability, determined by, 42 direct method, 42–45 amount of dry soil, 43 cumulative water added (CWAP), 44 cumulative water transpired (CWT), 44 flowchart, 43 leaf area duration (LAD), 45 materials required, 42 mean transpiration rate (MTR), 45 net assimilation rate (NAR), 45 principle, 42 procedure, 42 indirect method, 42–48 procedure, 45, 47 SPAD chlorophyll meter reading, 46 specific leaf area (SLA), 45, 46 stable isotope ratio, 47 WUE traits See Water use efficiency (WUE) traits X X-ray analysis, 21 objective, 22 .. .Phenotyping Crop Plants for Physiological and Biochemical Traits Page left intentionally blank Phenotyping Crop Plants for Physiological and Biochemical Traits P Sudhakar Department of Crop. .. developing various physiological and biochemical traits in different field crops for 20 years and have established state-of-the-art laboratory and field facilities for phenotyping crop plants at Regional... various physiological traits standardized in their laboratory I congratulate the authors for bringing out their expertise in the form of this book ? ?Phenotyping crop plants for physiological and biochemical

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  • Cover

  • Title Page

  • Copyright Page

  • Contents

  • Message

  • Foreword

  • Preface

  • Abbreviations

  • Introduction

  • Section I

    • Chapter 1 - Various methods of conducting crop experiments

      • 1.1 - Field experiments

      • 1.2 - Experiments under green houses

        • 1.2.1 - Demerits

      • 1.3 - Experiments in growth chambers

        • 1.3.1 - Demerits

      • 1.4 - Hydroponics

        • 1.4.1 - Precautions

      • 1.5 - Pot culture

  • Section II

    • Chapter 2 - Seed physiological and biochemical traits

      • 2.1 - Destructive methods

        • 2.1.1 - Seed viability

        • 2.1.2 - Seed vigor tests

      • 2.2 - Nondestructive methods

        • 2.2.1 - X-ray analysis

        • 2.2.2 - Electrical impedance spectroscopy (EIS)

        • 2.2.3 - Multispectral Imaging

        • 2.2.4 - Microoptrode technique (MOT)

        • 2.2.5 - Infrared thermography (IRT)

        • 2.2.6 - Seed viability measurement using resazurin reagent

        • 2.2.7 - Computerized seed imaging

  • Section III

    • Chapter 3 - Plant growth measurements

      • 3.1 - Measurement of growth

      • 3.2 - Measurement of below ground biomass

      • 3.3 - Growth analysis

        • 3.3.1 - Growth characteristics—definition and mathematical formulae

    • Chapter 4 - Photosynthetic rates

      • 4.1 - Net assimilation rate (NAR)

      • 4.2 - Measuring through infrared gas analyzer (IRGA)

      • 4.3 - Rubisco enzyme activity

        • 4.3.1 - Measurement of rubisco activity

      • 4.4 - Chlorophyll fluorescence ratio (Fv/Fm values)

    • Chapter 5 - Drought tolerance traits

      • 5.1 - Water use efficiency (WUE) traits

        • 5.1.1 - Carbon isotope discrimination

        • 5.1.2 - Determination of stable carbon isotopes using isotope ratio mass spectrometer (IRMS)

        • 5.1.3 - Protocol for carbon isotope discrimination in leaf biomass

      • 5.2 - Root traits

    • Chapter 6 - Other drought-tolerant traits

      • 6.1 - Relative water content (RWC)

      • 6.2 - Chlorophyll stability index (CSI)

      • 6.3 - Specific leaf nitrogen (SLN)

      • 6.4 - Mineral ash content

      • 6.5 - Leaf anatomy

      • 6.6 - Leaf pubescence density

      • 6.7 - Delayed senescence or stay-greenness

      • 6.8 - Leaf waxiness

      • 6.9 - Leaf rolling

      • 6.10 - Leaf thickness (mm)

      • 6.11 - Stomatal index and frequency

      • 6.12 - Other indicators for drought tolerance

      • 6.13 - Phenological traits

    • Chapter 7 - Tissue water related traits

      • 7.1 - Osmotic potential

        • 7.1.1 - Determination of osmotic potential using vapor pressure osmometer

          • 7.1.1.1 - Procedure

      • 7.2 - Leaf water potential

      • 7.3 - Relative water content

      • 7.4 - Cell membrane injury

        • 7.4.1 - Cell membrane permeability based on leakage of solutes from leaf samples

    • Chapter 8 - Heat stress tolerance traits

      • 8.1 - Canopy temperature

      • 8.2 - Chlorophyll stability index (CSI)

      • 8.3 - Chlorophyll fluorescence

      • 8.4 - Thermo induction response (TIR) technique

      • 8.5 - Membrane stability index

        • 8.5.1 - Membrane permeability based on leakage of solutes from leaf samples

    • Chapter 9 - Oxidative stress tolerance traits

      • 9.1 - Oxidative damage

        • 9.1.1 - Antioxidant enzymes

      • 9.2 - Superoxide dismutase (SOD)

      • 9.3 - Catalase

      • 9.4 - Peroxidase (POD)

      • 9.5 - Free radicals

    • Chapter 10 - Salinity tolerance traits

      • 10.1 - Chlorophyll stability index

      • 10.2 - Proline

      • 10.3 - Sodium (Na) and potassium (K) ratio

        • 10.3.1 - Potassium (K)

        • 10.3.2 - Sodium (Na)

      • 10.4 - Antioxidative enzymes

  • Section IV

    • Chapter 11 - Kernel quality traits

      • 11.1 - Proteins

        • 11.1.1 - Protein Estimation by Lowry Method

        • 11.1.2 - Protein estimation by Bradford method

      • 11.2 - Kernel oil

        • 11.2.1 - Oil estimation by soxhlet apparatus (SOCS)

      • 11.3 - Aflatoxins

        • 11.3.1 - Quantification of aflatoxin levels in kernels

    • Chapter 12 - Carbohydrates and related enzymes

      • 12.1 - Reducing sugars

      • 12.2 - Nonreducing sugars

      • 12.3 - Total carbohydrates

      • 12.4 - Estimation of sucrose phosphate synthase

      • 12.5 - Estimation of starch synthase

      • 12.6 - Estimation of invertases

    • Chapter 13 - Nitrogen compounds and related enzymes

      • 13.1 - Total nitrogen

        • 13.1.1 - Kjeldhal method for quantifying leaf nitrogen content

        • 13.1.2 - Preparation of reagents

        • 13.1.3 - Protein percent can be determined indirectly using the following formula

      • 13.2 - Total free amino acids

      • 13.3 - Nitrate reductase

      • 13.4 - Nitrite reductase

      • 13.5 - Leghemoglobin (Lb)

      • 13.6 - Glutamic acid dehydrogenase (GDH)

      • 13.7 - Glutamate synthase (GOGAT)

      • 13.8 - Glutamine synthetase (GS)

        • 13.8.1 - Calculation

    • Chapter 14 - Other biochemical traits

      • 14.1 - Total phenols

      • 14.2 - Ascorbic acid

      • 14.3 - Alcohol dehydrogenase (ADH)

      • 14.4 - Glycine betaine

    • Chapter 15 - Plant pigments

      • 15.1 - Chlorophylls

        • 15.1.1 - Estimation of chlorophyll

      • 15.2 - Carotenoids

        • 15.2.1 - Quantification of carotenoids in green leaves

      • 15.3 - Lycopene

      • 15.4 - Anthocyanin

    • Chapter 16 - Growth regulators

      • 16.1 - Estimation of indole acetic acid (IAA)

      • 16.2 - Estimation of gibberellins

      • 16.3 - Estimation of abscisic acid (ABA)

      • 16.4 - Estimation of ethylene

  • Section V

    • Chapter 17 - Analytical techniques

      • 17.1 - Ultraviolet visible (UV–VIS) spectrophotometer

      • 17.2 - Thin layer chromatography (TLC)

      • 17.3 - Gas chromatography (GC)

        • 17.3.1 - Introduction

        • 17.3.2 - Principle

        • 17.3.3 - Detectors

          • 17.3.3.1 - Thermal conductivity detector

          • 17.3.3.2 - Flame ionization detector

          • 17.3.3.3 - Electron capture detector

      • 17.4 - High-performance liquid chromatography (HPLC)

        • 17.4.1 - Role of five major HPLC components

      • 17.5 - Liquid chromatography–mass spectrometry (LC–MS, or alternatively HPLC–MS)

        • 17.5.1 - Flow splitting

        • 17.5.2 - Mass spectrometry (MS)

        • 17.5.3 - Mass analyzer

        • 17.5.4 - Interface

        • 17.5.5 - Applications

          • 17.5.5.1 - Pharmacokinetics

          • 17.5.5.2 - Proteomics/metabolomics

      • 17.6 - Inductively coupled plasma spectrometry (ICP) (Soil & Plant Analysis Laboratory University of Wisconsin–Madison htt...

        • 17.6.1 - Introduction

        • 17.6.2 - Summary of method

        • 17.6.3 - Safety

        • 17.6.4 - Interference

        • 17.6.5 - Measurement by ICP-OES

          • 17.6.5.1 - Sample preparation

        • 17.6.6 - Measurement

        • 17.6.7 - Measurement by ICP-MS

          • 17.6.7.1 - Sample preparation

        • 17.6.8 - Measurement

    • Appendices - Common Buffers

      • Appendix I: citrate buffer

      • Appendix II: sodium phosphate buffer

      • Appendix III: potassium phosphate buffer

      • Appendix IV: sodium acetate buffer

      • Appendix V: Tris–HCl buffer (tris–hydroxymethyl aminomethane hydrochloric acid buffer)

      • Appendix VI: 1M Hepes–NaOH pH 7.5 buffer

      • Appendix VII: preparation of stocks of macro and micronutrients for hydroponics experiment

      • Appendix VIII: preparation of ‘Hoagland solution’ for hydroponics experiment

      • Appendix IX: solubility chart of plant growth regulators

    • References

    • Index

    • Back Cover

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