Heat Shock Proteins and Plants provides the most up-to-date and concise reviews and progress on the role of heat shock proteins in plant biology, structure and function and is subdivided into chapters focused on Small Plant HSPs (Part I), Larger Plant HSPs (Part II) and HSPs for Therapeutic Gain (Part III). This book is written by eminent leaders and experts from around the world and is an important reference book and a must-read for undergraduate, postgraduate students and researchers in the fields of Agriculture, Botany, Crop Research, Plant Genetics and Biochemistry, Biotechnology, Drug Development and Pharmaceutical Sciences.
Scientific progress hinges on continual discovery and the extension of previous discoveries. The important series of volumes Discoveries in Plant Biology is specially compiled to provide a microcosmic atlas of the landmark discoveries that span the breadth of plant biology. Written by renowned plant biologists, the papers describe how classic discoveries were made and how they have served as the basis for subsequent breakthroughs. The 24 chapters in this third volume describe discoveries which contribute to the foundations of modern plant biology. The contributors, many of whom personally lit the way, bring readers back in time as if on a journey to retrace the paths and rethink the ideas they followed. These guided tours on how to decipher the natural laws will lead to an appreciation of the development of each field from simple concepts to an advanced multidisciplinary field of today. This volume will be of special interest to botanists, biochemists, plant physiologists and geneticists, and of general interest to those who are still fascinated by how discoveries are made. Contents:The Discovery of the Essential Elements (E Epstein)The Discovery of 1-Aminocyclopropane-1-Carboxylic Acid as the Immediate Precursor of Ethylene (D O Adams)Discovery of Auxin (Y Masuda & S Kamisaka)Non-Reducing Saccharides: Floridosides and Sucrose (J-C Su)Chlorophyll Biosynthesis I: From Analysis of Mutants to Genetic Engineering of the Pathway (D von Wettstein)Chlorophyll Biosynthesis II: Adventures with Native and Recombinant Enzymes (D von Wettstein)Discovery of the Two Parallel Pathways for Isoprenoid Biosynthesis in Plants (H K Lichtenthaler)Structure and Biosynthesis of Cellulose. Part I: Structure (A D French)Structure and Biosynthesis of Cellulose. Part II: Biosynthesis (D P Delmer)The Discovery of Starch Biosynthesis (J Preiss & M N Sivak)Seed Storage Proteins from the 1700s to the Present (M Ogawa & T W Okita)The Discovery of 2S Albumins as Abundant Storage Proteins in Seeds (A H C Huang & R J Youle)The Discovery of Maternal Inheritance of Large Subunit of Rubisco (S-D Kung)Chloroplast Cytochromes: Discovery and Characterization (J C Gray)Discovery of Plasma Membrane Proton Pumping ATPase: Our Point of View (R T Leonard & T K Hodges)Plant Ubiquitin (R D Vierstra)Thirty Years of Fun with Antenna Pigment-Proteins and Photochemical Reaction Centers: A Tribute to the People Who Have Influenced My Career (J P Thornber)The Discovery of the Heat Shock Response in Plants (P-F L Chang & C-Y Lin)Discovery of Photoregulated Gene Expression (J C Watson)Organization and Regulation of Nitrogen Fixation Genes: 1974–1995 (S C Shen)The Ti-Plasmid and Plant Molecular Biology (J Schell & C Koncz)Active Ion Transport in Plants (A J Bloom & A R Taylor)Discovery of Chilling Injury (M E Saltveit)In Vitro Induced Haploids in Plant Genetics and Breeding (H Hu & X-R Guo) Readership: Botanists, biologists, biochemists, geneticists, plant physiologists and students. Keywords:Plant Biology;DiscoveriesReviews: “The different chapters not only provide excellent overviews into the development of essential discoveries in plant biology, they also help the reader to better understand the background, current status and future direction of the research in each of the areas covered.” Journal of Plant Physiology
Based upon a workshop entitled “The Small HSP World” held in Québec 2-5 October 2014. Twenty-five scientists provided chapters for the book. The chapters are from the best scientists currently working in this field. These colleagues include Arrigo, Benesch, Benjamin, Buchner-Haslbeck-Weinkauf, Benndorf, Boelens, Carra, Chang, Currie, Ecroyd, Emanuelsson, Fu, Garrido, Golenhofen, Gusev, Hightower, Kampinga, Lavoie, MacRae, Quinlan, Tanguay, Vierling, Vigh, Weeks and Wu. Briefly, the book starts with the structure of small heat shock proteins, moving to their functions and finishing with their involvement in diseases. Although this is quite broad, the structural aspect will be the unifying theme of the book.
This books provides the most up-to-date reviews on current advances in our understanding of the regulation of heat shock protein responses. Key basic scientists and clinical research laboratories from major universities, academic medical centers and pharmaceutical companies around the world have contributed chapters that review present research activity and importantly project this field into the future. For easy readability, the book is sub divided into four sections, including, Section I - HSP and Stress Responses; Section II - Chaperone Functions of HSP; Section III - HSP in Human Diseases; Section IV - Prognosis & Diagnosis of HSP. The book is a must read for researchers involved in biomedical research, drug discovery and design to improve human health.
Demystifies the genetic, biochemical, physiological, and molecular mechanisms underlying heat stress tolerance in plants Heat stress—when high temperatures cause irreversible damage to plant function or development—severely impairs the growth and yield of agriculturally important crops. As the global population mounts and temperatures continue to rise, it is crucial to understand the biochemical, physiological, and molecular mechanisms of thermotolerance to develop ‘climate-smart’ crops. Heat Stress Tolerance in Plants provides a holistic, cross-disciplinary survey of the latest science in this important field. Presenting contributions from an international team of plant scientists and researchers, this text examines heat stress, its impact on crop plants, and various mechanisms to modulate tolerance levels. Topics include recent advances in molecular genetic approaches to increasing heat tolerance, the potential role of biochemical and molecular markers in screening germplasm for thermotolerance, and the use of next-generation sequencing to unravel the novel genes associated with defense and metabolite pathways. This insightful book: Places contemporary research on heat stress in plants within the context of global climate change and population growth Includes diverse analyses from physiological, biochemical, molecular, and genetic perspectives Explores various approaches to increasing heat tolerance in crops of high commercial value, such as cotton Discusses the applications of plant genomics in the development of thermotolerant ‘designer crops’ An important contribution to the field, Heat Stress Tolerance in Plants is an invaluable resource for scientists, academics, students, and researchers working in fields of pulse crop biochemistry, physiology, genetics, breeding, and biotechnology.
Researchers from North America and Western Europe discuss the state of the art research on gene expression in plants as affected by various stresses such as water deficit, seed dessication, anoxia, salinity, temperature extremes, heavy metals, air pollutants, and infection by pathogens. They also look at the possibilities of exploiting genes that regulate ozone resistance and the ingenious molecular strategies that have been developed by plants for dealing with pathogen attack. Annotation copyright by Book News, Inc., Portland, OR
Environmental stresses, such as high and low temperature, salinity, and drought, represent limiting factors to agricultural productivity worldwide. Their impact is not only on crops that are presently being cultivated, but they are also significant barriers to the introduction of crop plants into noncultivated areas. The book describes the cellular, biochemical, and molecular mechanisms in plants that regulate tolerance to stresses. Also discussed are prospects of engineering stress-tolerant plants through the modification of germplasm.
Box 9E. 1 Continued FIGURE 2. The C–S–R triangle model (Grime 1979). The strategies at the three corners are C, competiti- winning species; S, stress-tolerating s- cies; R,ruderalspecies. Particular species can engage in any mixture of these three primary strategies, and the m- ture is described by their position within the triangle. comment briefly on some other dimensions that Grime’s (1977) triangle (Fig. 2) (see also Sects. 6. 1 are not yet so well understood. and 6. 3 of Chapter 7 on growth and allocation) is a two-dimensional scheme. A C—S axis (Com- tition-winning species to Stress-tolerating spe- Leaf Economics Spectrum cies) reflects adaptation to favorable vs. unfavorable sites for plant growth, and an R- Five traits that are coordinated across species are axis (Ruderal species) reflects adaptation to leaf mass per area (LMA), leaf life-span, leaf N disturbance. concentration, and potential photosynthesis and dark respiration on a mass basis. In the five-trait Trait-Dimensions space,79%ofallvariation worldwideliesalonga single main axis (Fig. 33 of Chapter 2A on photo- A recent trend in plant strategy thinking has synthesis; Wright et al. 2004). Species with low been trait-dimensions, that is, spectra of varia- LMA tend to have short leaf life-spans, high leaf tion with respect to measurable traits. Compared nutrient concentrations, and high potential rates of mass-based photosynthesis. These species with category schemes, such as Raunkiaer’s, trait occur at the ‘‘quick-return’’ end of the leaf e- dimensions have the merit of capturing cont- nomics spectrum.
