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This book focuses on early germination, one of maize germplasm most important strategies for adapting to drought-induced stress. Some genotypes have the ability to adapt by either reducing water losses or by increasing water uptake. Drought tolerance is also an adaptive strategy that enables crop plants to maintain their normal physiological processes and deliver higher economical yield despite drought stress. Several processes are involved in conferring drought tolerance in maize: the accumulation of osmolytes or antioxidants, plant growth regulators, stress proteins and water channel proteins, transcription factors and signal transduction pathways. Drought is one of the most detrimental forms of abiotic stress around the world and seriously limits the productivity of agricultural crops. Maize, one of the leading cereal crops in the world, is sensitive to drought stress. Maize harvests are affected by drought stress at different growth stages in different regions. Numerous events in the life of maize crops can be affected by drought stress: germination potential, seedling growth, seedling stand establishment, overall growth and development, pollen and silk development, anthesis silking interval, pollination, and embryo, endosperm and kernel development. Though every maize genotype has the ability to avoid or withstand drought stress, there is a concrete need to improve the level of adaptability to drought stress to address the global issue of food security. The most common biological strategies for improving drought stress resistance include screening available maize germplasm for drought tolerance, conventional breeding strategies, and marker-assisted and genomic-assisted breeding and development of transgenic maize. As a comprehensive understanding of the effects of drought stress, adaptive strategies and potential breeding tools is the prerequisite for any sound breeding plan, this brief addresses these aspects.
Responses of Plants to Environmental Stresses, Second Edition, Volume II: Water, Radiation, Salt, and Other Stresses focuses on the effects of stresses on plants. This book discusses how stresses produce their damaging effects and how living organisms defend themselves against stresses. Organized into six parts encompassing 12 chapters, this edition starts with an overview of the various responses of plants to the severities of all the other environmental stresses, with emphasis on the physical and biological stresses and strains. This text then describes water stress in plants, which arise either from an excessive or from an insufficient water activity in the plant's environment. Other chapters consider the resistance to drought stress of plants. This book discusses as well the effects of flooding, which replaces gaseous air by liquid water. The final chapter deals with the comparative stress responses of plants. This book is a valuable resource for plant biologists.
Introduction - why breed for drought and low N tolerance?; Conceptual framework - breeding; Conventional approaches to improving the drought and low N tolerance of maize; Conventional approaches challenged; The challenge of breeding for drought and low N tolerance; Maize under drought and low N stress; Conceptual framework - physiology; Water and the maize plant; Nitrogen and the maize plant; Maize under drought and low N stress - consequences for breeding; Stress management; Drought; Low N stress; Statistical designs and layout of experiments; Increasing the number of replicates; Improved statistical designs; Field layout; Border effects from alleys; Secondary traits; Why use secondary traits?; How do we decide on the value of secondary traits in a drought or low N breeding program?; Secondary traits that help to identify drought tolerance; Secondary traits that help to identify low N tolerance: Selection indices - Combining information on secondary traits with grain yield; Combining information from various experiments; Breeding strategies; Choice of germplasm; Breeding schemes; Biotechnology: potential and constraints for improving drought and low N tolerance; The role of the farmer in selection; What is farmer participatory research and why is it important?; What is new about farmer participatory research?; Participatory methodologies.
Early seedling vigor and juvenile vegetative growth are important traits that allow the strong establishment of plants and access to nutrients and water, providing competition against weeds, and allowing mechanical cultivation in production systems that do not use herbicides. Drought stress at this early growth stage may be lethal or damaging. We used to the plant Digital Biomass as predicted from digital images to track plant growth under both well-watered and water-stressed conditions. To achieve these goals, we developed a manual imaging system that allowed us to track the plant growth over a period of 32 days. We imaged 30,36 plants representing 449 inbred lines daily from 13 to 32 days after planting with both a top and a side image. The drought treatment started 23 days after planting by completely withholding water from the water-stress treatment. Using Integrated Analysis Platform (IAP) software, we extracted 137 traits from the images including plant architectural traits and color traits. Phenotypic analysis of several traits showed variability across inbreds. Digital Biomass, for example, showed a great variability across inbreds with a 6.6-fold difference at the beginning of the experiment. Digital Biomass, estimated from the top and side images, was shown to be a good measure of plant vigor and strongly correlated with plant shoot weight at harvest. Vigorous seedling utilized more water, reflecting their ability to take advantage of available resources. The value of image-based traits of young plants was evaluated as a predictive tool for adult phenotypes grown in the field. Weak to moderate correlations were obtained between Digital Biomass at the seedling stage, with r-squared values of -0.35, -0.31 for GDD to Anthesis, and GDD to Silking respectively. The correlation between early maize growth and flowering time may suggest a common genetic control of growth and development of both stages with some possible genes with pleiotropic effects. To identify genomic regions associated with the several phenotypic traits, we utilized a dataset of 436,576 SNP markers to conduct Genome-wide Association (GWAS) using the GAPIT package in R. Several candidate genes were identified for growth rate and total leaf area at specific growth stages, as well as for other correlated traits. GWAS of image-derived plant color traits detected genes associated with plant pigments such as anthocyanin and chlorophyll, which confirms earlier reports on the utility of plant imaging in identifying plant pigments. We wanted to test whether growth, as measured by Digital Biomass, was controlled by a fixed or a dynamic set of genes, so we carried out GWAS analysis of Digital Biomass for each day as a separate phenotype. Results have shown that variation for early vegetative growth in maize is controlled by a dynamic set of genes over time, highlighting the importance of repeated measurement over time in GWAS and QTL studies designed to characterize the genetic architecture of plant development. The analysis of the drought-stressed plants showed variability in different drought tolerance traits ranging from 1.2 to 12.2-fold difference. The several measured traits included traits such as 1) leaf expansion sensitivity to water content and traits related to the ability to recover after drought such as 2) surviving green tissue after drought stress, 3) water use efficiency, and 4) growth rate after recovery with. No or weak correlations were found between the plant's ability to tolerate drought and its ability to recover. Photosynthesis Efficiency measured as Fv/Fm on a subset of 140 plants at three time-points during drought stress, showed that photosynthetic efficiency is less sensitive to drought stress than leaf growth. The candidate genes identified in this study, as well as correlations with field agronomic traits, may provide an insight that helps future understanding of the genetic control of biomass-related traits under both well-watered and drought stress conditions.
This topic is a unique attempt to simultaneously tackle theoretical and practical aspects in drought phenotyping, through both crop-specific and cross-cutting approaches. It is designed for – and will be of use to – practitioners and postgraduate students in plant science, who are grappling with the challenging task of evaluating germplasm performance under different water regimes. In Part I, different methodologies are presented for accurately characterising environmental conditions, implementing trials, and capturing and analysing the information this generates, regardless of the crop. Part II presents the state-of-art in research on adaptation to drought, and recommends specific protocols to measure different traits in major food crops (focusing on particular cereals, legumes and clonal crops). The topic is part of the CGIAR Generation Challenge Programme’s efforts to disseminate crop research information, tools and protocols, for improving characterisation of environments and phenotyping conditions. The goal is to enhance expertise in testing locations, and to stimulate the development and use of traits related to drought tolerance, as well as innovative protocols for crop characterisation and breeding.
With near-comprehensive coverage of new advances in crop breeding for drought and salinity stress tolerance, this timely work seeks to integrate the most recent findings about key biological determinants of plant stress tolerance with modern crop improvement strategies. This volume is unique because is provides exceptionally wide coverage of current knowledge and expertise being applied in drought and salt tolerance research.
World maize production; Meteorological requirements of the maize crop: temperature; Techniques for measuring and observing maize growth; Water use and requirements of maize; Maize physiology and weather: radiation; Modelling of weather/maize production relationships; Simulation of maize; Application of agroclimatic information to maize production; Weather and maize: a look ahead.
Environmental insults such as extremes of temperature, extremes of water status, and deteriorating soil conditions pose major threats to agriculture and food security. Employing contemporary tools and techniques from all branches of science, attempts are being made worldwide to understand how plants respond to abiotic stresses with the aim to manipulate plant performance that is better suited to withstand these stresses. This book searches for possible answers to several basic questions related to plant responses towards abiotic stresses. Synthesizing developments in plant stress biology, the book offers strategies that can be used in breeding, including genomic, molecular, physiological, and biotechnological approaches that have the potential to develop resilient plants and improve crop productivity worldwide.
An understanding of crop physiology and ecophysiology enables the horticulturist to manipulate a plant’s metabolism towards the production of compounds that are beneficial for human health when that plant is part of the diet or the source of phytopharmaceutical compounds. The first part of the book introduces the concept of Controlled Environment Horticulture as a horticultural production technique used to maximize yields via the optimization of access to growing factors. The second part describes the use of this production technique in order to induce stress responses in the plant via the modulation of these growing factors and, importantly, the way that this manipulation induces defence reactions in the plant resulting in the production of compounds beneficial for human health. The third part provides guidance for the implementation of this knowledge in horticultural production.