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COURSE OBJECTIVES: to gain knowledge about. - plant responses to environmental stress (physiological, biochemical, genetic) - research approaches for study of environmental stresses. biochemical, genetic and molecular on one hand mechanisms responsible for environmental stress tolerance
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COURSE OBJECTIVES: to gain knowledge about - plantresponses to environmental stress (physiological, biochemical, genetic) - research approaches for study of environmental stresses. • biochemical, genetic and molecular on one hand mechanisms responsible for environmental stress tolerance on the other hand the factors causing injury during stress. • integrateconcepts from related disciplines To sharpen written and oral communication skills associated with research
Detailed outline of the Plant Stress course 72637 - גנטיקה מולקולרית של תגובות צמחים לעקות סביבתיות(ד"ר אלכס לוין חדר 2-468, טל: 86543 (שעות קבלה יום ב' מ-14:00 • Plant interactions with surrounding environment • Plasma membrane as the barrier and stress sensor • Oxygen and Reactive Oxygen Species in environmental stress response (ROS chemistry, reactions, antioxidants, signaling) • Free radicals & antioxidants: Nitric oxide, oxidative stress, hypoxia • Stress signal transduction pathways: Biochemical vs. genetic analysis and the novel genomics/functional/ comparative genomics approaches • Major regulatory signaling molecules (stress hormones, ABA, ethylene) Intracellular messengers: a) Ca2+ as a general and specific signaling molecule b) Phospholipids in regulating stress signal transduction chapter 18 (Trawewas:Signal Perception and Transduction) Buchanan et al, eds. (2000). Biochemistry &Molecular Biology of Plants http://www.aspb.org/downloads/BiotextCH18.pdf • Molecular genetics of Specific stresses: a) salt stress b) other stresses (temperature/UV/ozone/polution) • Genetic engineering of abiotic stress resistance
Environmental stimuli that affect plant growth Plant response to environmental stimuli involves perception, transduction, adaptation Sensing changes in the surrounding environment Responding to gravity and direction of light, etc. Adjusting their growth pattern and development Control systems in plants involve adaptations, adaptations, adaptations Plants need to monitor everything in order to optimize growth (i.e. to adapt)toenvironmental conditions, endogenous present & future
Plants have to exploit their immediate environment to maximum effect. Their inability to move means that the best way of dealing with stress is by physiological or morphological changes. Abiotic stresses, and ways to adapt to them are numerous and interlinked there’s more than one way to skin a cat
Abiotic Water Oxygen Nutrients Temperature Salt stress Pollutants excess or deficit Biotic Insects Weeds Pathogens Plant competition mutations In biology, stress is the driving force behind the process of adaptation and evolution
Example of elucidating stress responses כל חץ משמעו מנגנון SIGNAL TRANSDUCTION Inputs for ionic and osmotic signaling pathways are ionic (excess Na+) and osmotic (turgor) changes. The output of ionic and osmotic signaling is cellular and plant homeostasis. Annual Review of Plant Biology 53: 247
Na+ UPTAKE/EXTRUSION IN THE PLANT CELL Plasma Membrane Na+ Na+ PPi H+ K+ H+ High-affinity K+ transporters V-PPase H+ Na+ Na+/H+ antiport Vacuole Na+ Na+ Tonoplast V-ATPase K+ K+/Na+ selectiveVICs H+ ATP ATP K+/Na+ ratio H+ P-ATPase Adapted from Mansour et al. 2003
SOS3 SOS2 ASPECTS OF SALT TOLERANCE IN PLANTS Ion homeostasis Ionic stress Ion transporters SALT STRESS Homeostasis Osmotic stress MAPK cascade ? Osmotic homeostasis Osmolytes COLD DROUGHT ABA Detoxification Stress proteins Secondary stresses CBF/DREB Cell division and expansion Adapted from J-K Zhu 2001
Discovery vs. Hypothesis-Driven Science scientific projects test a hypothesis or a model that arises during analysis of experimental data. Hypothesis is formulated and experiments support or refute the hypothesis. While this approach is valid, it can preclude discovery of variables, and mechanisms that are unknown during the study design. An alternate approach is to nonselectively gather information about a particular biological system; the results are then analyzed with the hope that significant characteristics will emerge, providing insight into the mechanism. This approach is known as discovery science. Discovery science and hypothesis-driven science are complementary approaches. Discovery science is a high throughput method that can screen fast many genes for potential involvement in a biological process. in contrast, Hypothesis-driven science is low throughput method
Discovery and Hypothesis approaches to Science The Genome Projects are the first modern practice of discovery science, now followed by other omics The objective of discovery science is to define all elements in a system and to create a database containing that information.For example, discovery approaches provide the complete sequences & expression of the organism genes. The transcriptomes and proteomes of all cell types Discovery science lies in contrast to hypothesis-driven science, which creates hypotheses and attempts to distinguish among them experimentally. Integration of the discovery and hypothesis approaches is area of systems biology.
Water STRESS stress Temperature Light Nutrients time The Four Elements of Abiotic Stress in general, performance below optimal genetic potential is indicative of stress
Plant Responses to Stress Mechanical concept of stress Stress is a force per unit area Strain is a change in dimension in response to stress(in other words, deformation of a physical body under the action of applied forces) Failure of a material occurs when the material cannot strain sufficiently to resist stress
Plant Responses to Stress Biological concept of stress Abiotic (physical or chemical) or biotic factor adversely affecting an organism Measured as effect on growth rate and productivity
average losses Crop record yield* average yield* disease insect weed other (abiotic) corn 19,300 4,600 750 691 511 12,700 wheat 14,500 1,880 336 134 256 11,900 soybean 7,390 1,610 269 67 330 5,120 sorghum 20,000 2,830 314 314 423 16,200 oats 10,600 1,720 465 107 352 7,960 barley 11,400 2,050 377 108 280 8,590 potatoes 94,100 28,300 8,000 5,900 875 50,900 sugar beets 121,000 42,600 6,700 6,700 3,700 61,300 % of record yield 21.6% 4.1% 2.6% 2.6% 69.1% A comparison of the record yields and the average yields indicates that mostly crops are only reaching 20% of their genetic potentialdue tobioticcategories: disease, insect and weeds. The major reduction in yield (~ 70%)is due to abiotic stress.The most significant abiotic stress is water stress, both deficit stress (drought) and excess stress (flooding, anoxia).
Strategies of stress tolerance in plants • Susceptibility -slowed growth--senescence--death • Avoidance -deep rooting -short life cycle -leaf modifications • Resistance -ex. can survive desiccation of protoplasm “resurrection plants” constitutive deep roots constitutive succulent If plants can induce stress resisting genes Why these genes are not constitutively on? induced freezing toleranceresistance Drought avoidance
I. Important concepts of stress physiology • Stress– external factor that is disadvantageous to plants; survival, growth, development, yield • Acclimated (Hardened)- increased stress tolerance as a result of prior exposureto a stress condition • Cross Resistance- tolerance to a stress based on exposure to a previous stress event of a different nature • Adaptation- is a genetically determined level of resistance acquired by a process of selection over many generations
Assignment 1 • Define what are the hottest topics in plant research today • Start with general definitions, and identify the details • Define what is already known • Relevance to other systems and/or applicative aspects
Responses to Environmental Stresses • A minimum of 300 genes are required to produce a bacterial cell (based on the number of genes in Mycoplasma).Escherichia coli contain 3000 genes. The apparently inessential 2700 (90%!) are thought necessary to provide bacteria with the ability to tolerate randomly fluctuating environmental variation • How many genes are likely to be involved with the specification of signaling components. • Signaling, in its broadest sense, is now the major area of plant and environmental sciences research
I. SIGNAL TRANSDUCTION AND PLANT RESPONSES • Signal-transduction pathways link cellular responses • to environmental stimuli • Signal transduction pathway • = A mechanism linking a mechanical or chemical stimulus to a cellular response. • Three steps: reception, transduction, and induction
about the Signals and Signaling A molecule in a biological system encodes information in its shape, charge, hydrophobicity, and reactivity. Any change in a molecule’s composition encodes new information in the amount, rate, and duration of that change and where in the cell or organism the change occurs So, the signaling information is present in what, where, how much and when note that a signal is a signal only when there is a receptor to decipher the information
Plants respond to stress on a cellular and on the whole plant levels link between biotic and abiotic stress signal transduction and plant development Responses to Biotic and Abiotic stresses are connected genetically: bon1 are miniature at 22oC but like wild-type at 28oC growth regulation by BON1 is mediated through defense responses. BON1 is a negative regulator of a Resistance (R) gene SNC1. The bon1-1 loss-of-function mutation activates SNC1, leading to constitutive defense responses and, consequently, reduced cell growth
Plant Response to Stress • Plants adapt to changing environmental conditions through changes in expression patternsof numerous genes. • There is a group of genes whose expression confers resistance to a given stress. • There is a common core of defense genes, which responds to several different stresses (general stress-response genes) versus stress-specific genes. • Increase in expression of protective genes is co-regulated and is correlated with resistance to oxidative stress.
Plants are more exposed to toxicity by reactive oxygen species • O2 availability/accessability • high O2 concentration • 3) Multiple sources of O2.- • 4) exposure to UV • 5) rapid temperature shifts • 6) salinity, drought • 7) necrotrophic pathogens that secrete O2.-
Methods to study stress resistance • Biochemical Approach • control vs. resistant plants • control vs. induced conditions • The Genetic Approach • identify mutants with altered response • suppressor mutations • Comparative approach: complementation in yeast • The Genomic Approach • The Metabolomic Approach • The Ionomic Approach • Discovery vs. Hypothesis-Driven Science
Mendel Biotechnology was founded in 1997 to develop the idea that controlling gene expression would improve plant growth and development.Mendel focuses on a large class of genescalled transcription factors because they control the degree to which each gene in a cell is activated. The approximately27,000 genes in the Arabidopsis genome are controlled by approximately 1,800 different transcription factors. By systematically analyzing the function of all Arabidopsis transcription factors, Mendel scientists have discovered that single transcription factors can control complex traits such as freezing or drought, yield, morphology, disease resistance, nitrogen use efficiency and many other complex traits. We believe that no other company or academic institution in the world has a comparable understanding of the function of transcription factors and that Mendel is the leading company in the world in this area. The company has filed a large number of patents. We believe that the inventions described in our patent filings have placed the company in a strong position to participate in future developments in plant biotechnology, plant breeding, horticulture, and forestry. We are also using knowledge of plant gene expression to discover new ways of using chemicals to control plant growth and development.
Mendel Biotechnology Awarded SBIR Phase II Grant for Continued Research on Wide Spectrum Disease Resistance • HAYWARD, California--October 2005 • Mendel's role in Monsanto trait development program highlighted in September 2005 issue of Business 2.0 • HAYWARD, California--September 2005 Mendel Biotechnology and SweTree Technologies will jointly exploit the value of certain genes in forestryHAYWARD, California--October 29, 2004 • Both companies announced today that they will jointly exploit the value of certain transcription factor (TF) genes within the $750 billion forestry field, among them the Hercules gene. The collaboration includes a research effort to validate certain Mendel lead TF genes for the forestry field. Mendel has demonstrated that the Hercules gene and other TF genes improve growth rate in commercial plants. • Mendel Biotechnology Awarded SBIR Phase II Grant for Continued Research to Increase Production of Natural RubberHAYWARD, California--(PRNewswire)--October 7, 2003 • The Economistwrites about Mendel's offer to donate drought-protection technology to the Rockefeller Foundation. -- March 27, 2003 • Other Products • Disease resistance Abiotic stress tolerance • Yield Flowering time • Pigmentation Morphology • Mineral nutrient use Metabolite composition • Biomass composition
The complexity of stress adaptation:major targets for engineered stress tolerance
II. PLANT RESPONSES TO HORMONES Hormone = A compound produced by one part of an organism that is transported to other parts where it triggers a response in target cells and tissues. B. Plant hormones help coordinate growth, development, and responses to environmental stimuli 1) By affecting division, elongation, and differentiation of cells 2) Effects depend on site of action, stage of plant growth and hormone concentration 3) The hormone signal is amplified, perhaps by affecting gene expression, enzyme activity, or membrane properties 4) Reaction to hormones depends on hormonal balance 5) Five classes of plant hormones: (1) Auxin (such as IAA). (2) Cytokinins (such as zeatin) (3) Gibberellins (such as GA3) (4) Abscisic acid (5) Ethylene
hormones are chemical signals that are produced in one part of the body, transported to other parts, bind to specific receptors, and trigger responses in targets cells and tissues. • Only minute quantities of hormones are necessary to induce substantial change in an organism. • Often the response of a plant is governed by the interaction of two or more hormones.
Plant hormones are produced at low concentration • Signal transduction pathways amplify the hormonal signal many fold and connect it to a cell’s specific responses. • These include altering the expression of genes, by affecting the activity of existing enzymes, or changing the properties of membranes. • Response to a hormone usually depends not so much on its absolute concentration as on its relative concentration compared to other hormones
Stress physiology... Biological membranes are the primary target of many environmental stresses. Membranes are made of phospholipids and proteins. ~50:50 %, thus not just a barrier phospholipid hydrophobic interior phospholipid hydrophilic exterior