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No-Mow Grass May Be Coming to Your Yard Soon
May 08, 2006For anyone tethered to a lawnmower, the Holy Grail of horticultural accomplishment would be grass that never grows but is always green.
Now, that vision of suburban bliss-and more-seems plausible as scientists have mapped a critical hormone signaling pathway that regulates the stature of plants. In addition to lawns that rarely require mowing, the finding could also enable the development of sturdier, more fruitful crop plants such as rice, wheat, soybeans, and corn.
In a paper published in the May 4, 2006, issue of the journal Nature, Howard Hughes Medical Institute scientists report they have deciphered the signaling pathway for a key class of steroid hormones that regulates growth and development in plants.
"By manipulating the steroid pathway-we think we can regulate plant stature and yield," said Joanne Chory, a Howard Hughes Medical Institute investigator at the Salk Institute for Biological Studies, and the senior author of the new report.
Manipulation of plant stature has been a longstanding goal in horticulture, agronomy, and forestry. The ability to precisely control plant size would have broad implications for everything from urban forestry to crop and garden plant development. Beyond perpetually short grass, trees could be made more compact for better growth in crowded cities, and berry bushes could be made taller for ease of harvesting.
To chart the pathway, Chory and colleague Grégory Vert of the Salk Institute's Plant Biology Laboratory examined the molecular influence of a family of plant hormones known as brassinosteroids. Scientists have found brassinosteroids in all plants where they have looked for them. As critical chemical messengers of plant development, they are found in low levels in virtually all plant cells, including seeds, flowers, roots, leaves, stems, pollen, and young vegetative tissue.
"Without them, plants are tiny dwarves, with reduced vasculature and roots, and are infertile," Chory explained. "They also regulate senescence or aging. Since brassinosteroids mainly regulate cell expansion, though, they are one of the most important hormones that regulate stature."
Knowing the molecular chain of command-how the hormone acts to influence genetic events that govern development at the cellular level-gives scientists a way to reshape the steroid pathway to develop plants that grow in specified ways.
"We might be able to dwarf grass and keep it green by limiting brassinosteroids or increase the yield of rice by having more brassinosteroids in seeds," Chory said. Another recent study by Makoto Matsuoka's group in Japan, she said, showed that limiting brassinosteroids in rice affected leaf angle and improved yield in densely planted fields.
Vert and Chory's work helps trace a molecular pathway that is ancient-perhaps more than a billion years old-in both plants and animals. "Remarkably, steroid biosynthetic enzymes are highly conserved from plants to metazoans (animals), suggesting that the use of steroids as hormones preceded the plant-animal split over a billion years ago," Chory explained.
In animals, the route steroid hormones use to exert their influence in the nucleus of a cell, where gene expression is regulated, is direct, through the use of nuclear receptors. Plants, said Chory, don't have nuclear receptors, which would provide more direct access to the nucleus. Rather, plant steroids are perceived outside the cell by the extracellular domain of a cell surface receptor. Perception then regulates genetic events in the nucleus in a more roundabout way, similar to a well-studied pathway in animals known as the Wnt signaling pathway. Wnt is a secreted molecule that influences the nucleus of a cell through cell surface receptors to regulate cell-to-cell interactions and many of the events of embryogenesis in metazoans.
"Because one of the brassinosteroid signaling components was similar to a protein found in the Wnt signaling pathway, we thought that the logic for brassinosteroid signaling (in plants) would be very much like the Wnt pathway," said Chory. "We were wrong."
Instead, brassinosteroid perception leads to a cascade of biochemical events that alter the ability of key proteins to dimerize and activate gene expression within a cell's nucleus. In plants, there are scores of genes involved in growth and development that can be influenced by brassinosteroids, Chory noted.
"Many of these genes are predicted to be involved in growth, like cell wall metabolism. Their up-expression would be predicted to promote cell expansion," according to Chory.
The work of other groups, she noted, has shown that brassinosteroids can negatively regulate their own expression as part of a feedback loop that, ultimately, determines the size of a plant. In nature, that feedback loop has served plants well, helping them adjust their height and size to fit the growing conditions of any environmental niche.
Through traditional methods of plant breeding, humans have been manipulating plant stature for thousands of years. In recent years, through the methods of genetic engineering, more precise methods for altering industrial plant strains have come into play.
But access to a pathway used by plant hormones to dictate size promises broader influence over the many genes involved in the process of growth. Levers that could be used to alter a hormone pathway to influence plant development and stature, according to Chory, include modifying the levels of the hormone, manipulating the chemical structures of hormones, and recoding the signals sent along the pathway.
Howard Hughes Medical Institute
"By manipulating the steroid pathway-we think we can regulate plant stature and yield," said Joanne Chory, a Howard Hughes Medical Institute investigator at the Salk Institute for Biological Studies, and the senior author of the new report.
Manipulation of plant stature has been a longstanding goal in horticulture, agronomy, and forestry. The ability to precisely control plant size would have broad implications for everything from urban forestry to crop and garden plant development. Beyond perpetually short grass, trees could be made more compact for better growth in crowded cities, and berry bushes could be made taller for ease of harvesting.
To chart the pathway, Chory and colleague Grégory Vert of the Salk Institute's Plant Biology Laboratory examined the molecular influence of a family of plant hormones known as brassinosteroids. Scientists have found brassinosteroids in all plants where they have looked for them. As critical chemical messengers of plant development, they are found in low levels in virtually all plant cells, including seeds, flowers, roots, leaves, stems, pollen, and young vegetative tissue.
"Without them, plants are tiny dwarves, with reduced vasculature and roots, and are infertile," Chory explained. "They also regulate senescence or aging. Since brassinosteroids mainly regulate cell expansion, though, they are one of the most important hormones that regulate stature."
Knowing the molecular chain of command-how the hormone acts to influence genetic events that govern development at the cellular level-gives scientists a way to reshape the steroid pathway to develop plants that grow in specified ways.
"We might be able to dwarf grass and keep it green by limiting brassinosteroids or increase the yield of rice by having more brassinosteroids in seeds," Chory said. Another recent study by Makoto Matsuoka's group in Japan, she said, showed that limiting brassinosteroids in rice affected leaf angle and improved yield in densely planted fields.
Vert and Chory's work helps trace a molecular pathway that is ancient-perhaps more than a billion years old-in both plants and animals. "Remarkably, steroid biosynthetic enzymes are highly conserved from plants to metazoans (animals), suggesting that the use of steroids as hormones preceded the plant-animal split over a billion years ago," Chory explained.
In animals, the route steroid hormones use to exert their influence in the nucleus of a cell, where gene expression is regulated, is direct, through the use of nuclear receptors. Plants, said Chory, don't have nuclear receptors, which would provide more direct access to the nucleus. Rather, plant steroids are perceived outside the cell by the extracellular domain of a cell surface receptor. Perception then regulates genetic events in the nucleus in a more roundabout way, similar to a well-studied pathway in animals known as the Wnt signaling pathway. Wnt is a secreted molecule that influences the nucleus of a cell through cell surface receptors to regulate cell-to-cell interactions and many of the events of embryogenesis in metazoans.
"Because one of the brassinosteroid signaling components was similar to a protein found in the Wnt signaling pathway, we thought that the logic for brassinosteroid signaling (in plants) would be very much like the Wnt pathway," said Chory. "We were wrong."
Instead, brassinosteroid perception leads to a cascade of biochemical events that alter the ability of key proteins to dimerize and activate gene expression within a cell's nucleus. In plants, there are scores of genes involved in growth and development that can be influenced by brassinosteroids, Chory noted.
"Many of these genes are predicted to be involved in growth, like cell wall metabolism. Their up-expression would be predicted to promote cell expansion," according to Chory.
The work of other groups, she noted, has shown that brassinosteroids can negatively regulate their own expression as part of a feedback loop that, ultimately, determines the size of a plant. In nature, that feedback loop has served plants well, helping them adjust their height and size to fit the growing conditions of any environmental niche.
Through traditional methods of plant breeding, humans have been manipulating plant stature for thousands of years. In recent years, through the methods of genetic engineering, more precise methods for altering industrial plant strains have come into play.
But access to a pathway used by plant hormones to dictate size promises broader influence over the many genes involved in the process of growth. Levers that could be used to alter a hormone pathway to influence plant development and stature, according to Chory, include modifying the levels of the hormone, manipulating the chemical structures of hormones, and recoding the signals sent along the pathway.
Howard Hughes Medical Institute
Brassinosteroids Current Events and Brassinosteroids News RSSGetting plants to rid themselves of pesticide residues
Scientists in China have discovered that a natural plant hormone, applied to crops, can help plants eliminate residues of certain pesticides. The study is in the current issue of ACS' Journal of Agricultural and Food Chemistry, a bi-weekly publication.
Getting plants to rid themselves of pesticide residues
Scientists in China are reporting the "intriguing" discovery that a natural plant hormone, applied to crops, can help plants eliminate residues of certain pesticides.
Plants on steroids: Key missing link discovered
Researchers at the Carnegie Institution's Department of Plant Biology have discovered a key missing link in the so-called signaling pathway for plant steroid hormones (brassinosteroids).
ISU researcher identifies genetic pathway responsible for much of plant growth
Researchers at Iowa State University have discovered a previously unknown pathway in plant cells that regulates plant growth.
Researchers learn what sparks plant growth
A secret long held by plants has been revealed by Howard Hughes Medical Institute researchers. The new discovery, which builds on more than a decade of painstaking surveillance of cellular communication between different types of plant tissues, shows clearly for the first time how plants "decide" to grow.
Computational analysis shows that plant hormones often go it alone
or years, debate swirled around whether pathways activated by growth-regulating plant hormones converge on a central growth regulatory module.
Salk scientists untangle steroid hormone signaling in plants
When given extra shots of the plant steroid brassinolide, plants "pump up" like major league baseball players do on steroids.
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Brassinosteroids: Chemistry, Bioactivity, and Applications (Acs Symposium Series) by Horace G. Cutler (Editor), Gunter Adam (Editor), Takao Yokota (Editor) This is the first and only comprehensive reference on brassinosteroids, a new class of plant hormones. It provides a survey of the chemistry, synthesis, physiology, and practical applications of brassinosteroids, in experimental and agricultural references alike. With contributions from all over the world, including Africa, Asia, Europe, and North America, this volume presents an accurate and comprehensive picture of the present state of research and development in brassinosteroids. Of special interest is the presentation of results of large-scale field trials in China, which strongly indicate the economic potential of these compounds as environmentally benign agricultural chemicals to significantly increase crop yields. | |
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Brassinosteroids: Bioactivity and Crop Productivity by S. Hayat (Editor), A. Ahmad (Editor) Brassinosteroids are plant hormones with significant growth-promoting capacity. Moreover, brassinosteroids influence seed germination, rhizogenesis, flowering, senescence, abscission and maturation. Brassinosteroids also confer resistance to plants against abiotic stresses. Brassinosteroids are, therefore, considered as plant hormones with pleotropic effects. This book provides a comprehensive and up to date account of the brassinosteroids, incorporating both theoretical and practical aspects. The contributors to this book are experts of international repute. Each chapter presents a review of the available literature and provides insight into current thinking by pointing out the limitations and gaps in the present knowledge and directing the way forward for further research. ... |
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Brassinosteroids: A New Class of Plant Hormones by V. A. Khripach (Author), V. N. Zhabinskii (Author), A. E. de Groot (Author) Plants possess the ability to biosynthesize a large variety of steroids, but it was not until 1979 that a hormonal function was demonstrated in plants. Today, about 40 structurally and functionally related steroids, known as brassinosteroids, have been isolated from natural sources. Brassinosteroids demonstrate various kinds of regulatory activities in the growth and development of plants. This book is based on a 1990 Russian monograph, but includes all important subsequent literature and developments, including unpublished data from the authors' laboratories. Key Features * BRASSINOSTEROIDS: A New Class of Plant Hormones covers: * Structures and classification * Isolation and spectroscopic determination * Biosynthesis and... |
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Cell: Volume 90 Number 5 September 5, 1997; Brassinosteroid Signal Transduction by Cell Press (Publisher) | |
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Herbicide Resistance-Brassinosteroids, Gibberellins, Plant Growth Regulators (Chemistry of Plant Protection) by G. Adam (Author), Stephen O. Duke (Author), D. Gross (Contributor) Chemistry of Plant Protection, Volume 7, provides critical review articles on new aspects of herbicide resis- tance, serving the needs of research scientists, pesticide manufacturers, government regulators, agricultural practitioners. | |
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Brassinosteroids: Steroidal Plant Hormones by A. Sakurai (Editor), Takao Yokota (Editor), S. D. Clouse (Editor) Brassinosteroids are plant-growth-promoting natural products similar in structure to animal and insect steroid hormones. Considered a new class of plant hormone, along with auxins, gibberellins, cytokinins, abscisic acid, and ethylene, brassinosteroids are present throughout the plant kingdom. They show distinct physiological effects on plant growth including improvement of stress tolerance in crop production. These discoveries, together with advances in molecular and biosynthetic studies of brassinosteroids, open new aspects of research in understanding the growth and development of plants. This book presents a comprehensive view of the related chemistry, biochemistry, physiology, agricultural applications, and most recent research in molecular biology. Written by scientists who are... |
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Fortschritte der Chemie organischer Naturstoffe / Progress in the Chemistry of Organic Natural Products / Volume 78 by A. Akhila (Contributor), G. Adam (Contributor), K. Rani (Contributor), J. Schmidt (Contributor), B. Schneider (Contributor) The volumes of this classic series, now referred to simply as Zechmeister after its founder, L. Zechmeister, have appeared under the Springer Imprint ever since the series inauguration in 1938. The volumes contain contributions on various topics related to the origin, distribution, chemistry, synthesis, biochemistry, function or use of various classes of naturally occurring substances ranging from small molecules to biopolymers. Each contribution is written by a recognized authority in his field and provides a comprehensive and up-to-date review of the topic in question. Addressed to biologists, technologists, and chemists alike, the series can be used by the expert as a source of information and literature citations and by the non-expert as a means of orientation in a rapidly developing... |
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