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Midget plant gets makeover
June 23, 2009Palo Alto, CA-A tiny plant with a long name (Arabidopsis thaliana) helps researchers from over 120 countries learn how to design new crops to help meet increasing demands for food, biofuels, industrial materials, and new medicines. The genes, proteins, and other traits of this fast-growing, tiny mustard plant reside in a vast database dubbed the Arabidopsis Information Resource (TAIR), which has over 1.6 million page hits each month. The TAIR group, headed by Dr. Eva Huala at Carnegie's Department of Plant Biology, just released a new version of the genome sequence of this model plant, which includes an array of improvements and novel features that promise to accelerate this critical research.
The new TAIR9 genome release contains detailed information on all 33,518 genes that make up this tiny plant (including 114 newly discovered genes and 168 new pseudogenes), the proteins produced by these genes, and extensive new experimental and computationally predicted gene-function information.
Huala highlighted the advances: "We now have a ranking system that provides a measure of our confidence that the structure of a specific gene is correct; we've overhauled information on pseudogenes-the evolutionary remnants that start out as copies of conventional protein-coding genes and sometimes take on interesting new functions; and we've made extensive updates to the genome sequence based on new sequence data submitted to TAIR."
In 2000, Arabidopsis was the first plant genome to be sequenced. Partly due to the vast experimental data on gene function, which TAIR has painstakingly extracted from the literature and associated to the genes, and because of an extensive set of molecular tools developed for this plant, the Arabidopsis genome is the most advanced plant genome in the world and is the most commonly used experimental plant today. Its small size and fast growth allow large-scale experiments on drought and salt tolerance, resistance to plant diseases, and other topics with a direct impact on economic and food quality issues to be carried out quickly and economically, and the results applied to important crop species.
"TAIR is a crucial resource for plant sciences, but its impact goes far beyond," remarked Dr. Wolf Frommer, director of Carnegie's Department of Plant Biology. "TAIR9, as the 'green' reference database, is crucial for understanding the function and engineering of algae as well as crop plants. It is the basis for all improvement of crop plants to meet the challenges of a growing population as well as climate change."
Carnegie Institution
In 2000, Arabidopsis was the first plant genome to be sequenced. Partly due to the vast experimental data on gene function, which TAIR has painstakingly extracted from the literature and associated to the genes, and because of an extensive set of molecular tools developed for this plant, the Arabidopsis genome is the most advanced plant genome in the world and is the most commonly used experimental plant today. Its small size and fast growth allow large-scale experiments on drought and salt tolerance, resistance to plant diseases, and other topics with a direct impact on economic and food quality issues to be carried out quickly and economically, and the results applied to important crop species.
"TAIR is a crucial resource for plant sciences, but its impact goes far beyond," remarked Dr. Wolf Frommer, director of Carnegie's Department of Plant Biology. "TAIR9, as the 'green' reference database, is crucial for understanding the function and engineering of algae as well as crop plants. It is the basis for all improvement of crop plants to meet the challenges of a growing population as well as climate change."
Carnegie Institution
Arabidopsis Current Events and Arabidopsis News RSSIt's a gas: New discovery may lead to heartier, high-yielding plants
In a research report published in the November 2009 issue of the journal GENETICS, scientists show how a family of genes (1-aminocyclopropane-1-carboxylate synthase, or ACS genes) are responsible for production of ethylene.
Maize cell wall genes identified, giving boost to biofuel research
Purdue University scientists have helped identify and group the genes thought to be responsible for cell wall development in maize, an effort that expands their ability to discover ways to produce the biomass best suited for biofuels production.
Pathogen protection and virulence: Dark side of fungal membrane protein revealed
Researchers at the Virginia Bioinformatics Institute (VBI) at Virginia Tech and Montana State University have discovered a fungal protein that plays a key role in causing disease in plants and animals and which also shields the pathogen from oxidative stress.
Common weed could provide clues on aging and cancer
A common weed and human cancer cells could provide some very uncommon details about DNA structure and its relationship with telomeres and how they affect cellular aging and cancer, according to a team led by scientists from Texas A&M University and the University of Cincinnati (UC).
Popping the cork on biofuel agriculture
Scientists at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory have identified a novel enzyme responsible for the formation of suberin - the woody, waxy, cell-wall substance found in cork.
Oh, brother, it's true: Plants can recognize their siblings and now we know how
Plants may not have eyes and ears, but they can recognize their siblings, and researchers at the University of Delaware have discovered how.
When you've doubled your genes, what's 1 chromosome more or less?
An individual with Down syndrome and a male calico cat have one thing in common-each has an extra chromosome. For animals, most instances of an extra chromosome result in birth defects or even death, but plants are another matter entirely.
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).
Hormone clue to root growth
Plant roots provide the crops we eat with water, nutrients and anchorage. Understanding how roots grow and how hormones control that growth is crucial to improving crop yields, which will be necessary to address food security and produce better biofuels.
Plants' internal clock can improve climate-change models
The ability of plants to tell the time, a mechanism common to all living beings, enables them to survive, grow and reproduce.
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Arabidopsis: A Laboratory Manual by Detlef Weigel (Author), Jane Glazebrook (Author) The thale cress Arabidopsis thaliana is increasingly popular among plant scientists: it is small, easy to grow, and makes flowers, and the sequence of its small and simple genome was recently completed. This is the most complete and authoritative laboratory manual to be published on this model organism and the first to deal with genomic and proteomic approaches to its biology. |
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Arabidopsis Protocols, 2nd Edition (Methods in Molecular Biology) by Julio Salinas (Editor), Jose J. Sanchez-Serrano (Editor) This collection of readily reproducible Arabidopsis protocols has been updated to reflect recent advances in plant biology, the completion of the Arabidopsis genome sequence, which is essential for studying plant function, and the development of whole systems approaches that allow global analysis of gene expression and protein and metabolite dynamics. The authors have included nearly all techniques developed in Arabidopsis, others recently adapted from the traditional work in crop species, and the most recent ones using Arabidopsis as a model system. Highlights include the most recent methods-transcriptomics, proteomics, and metabolomics - and their novel applications (phosphoproteomics, DNA microarray-based genotyping, high throughput metabolite profiling, and single-cell RNA). |
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Knowledge Now in Experimental Biology: Arabidopsis as a Model Organism [VHS] Starring: Harvey Lodish |
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Arabidopsis: Seedlings In Culture Wilt (Primary Contributor) |
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Arabidopsis (Monograph, No. 27) (Monograph No 27) by Elliot M. Meyerowitz (Editor) The cruciferous weed Arabidopsis thialiana has become a model system for the study of an unusually wide variety of aspects of plant biology. As a result, nearly all aspects of Arabidopsis biology are now under investigation, more scientists are involved, and plant science as a whole has been invigorated. This book is the first comprehensive account of what is known about the organism. The information is presented in the context of plant biology in general, with the properties of Arabidopsis mutants and the insights derived from their analysis as a unifying theme. The book's scope includes genetics, growth and development, biochemistry, physiology, and responses to pathogens and environmental stress. This unique volume, in the classic tradition of the Cold Spring Harbor... | |
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Plant Physiology, Vol. 124, No. 4: Arabidopsis Genome: a Milestone in Plant Biology (Special Issue) by Editor in Chief Natasha V. Raikhel (Author) | |
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Arabidopsis as a Model Organism [VHS] Starring: Elliot Meyerowitz | |
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Arabidopsis: A Practical Approach (Practical Approach Series) by Zoe A. Wilson (Editor) Arabidopsis has long been acknowledged as the 'Botanical Drosophila' with its small genome, low levels of repetitive DNA, small size, and fast generation time. It is an ideal molecular genetic tool for the analysis of development in higher plants. Arabidopsis: A Practical Approach provides an introduction to most of the key techniques required for the use of Arabidopsis as an experimental system. Individual chapters describe strategies for the identification, mapping (using multi-marker lines and recombinant inbreds), and characterization of different mutants by microscopy, molecular cytogenetics, and gene expression analysis. Different cloning strategies, using transposons, T-DNA and map position are also described in detail. |
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Arabidopsis, the botanical Drosophila: from mouse cress to model organism [An article from: Endeavour] by S. Leonelli (Author) This digital document is a journal article from Endeavour, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The small flowering plant Arabidopsis thaliana is the best-studied model organism in plant biology. More resources are allocated to research on this little weed than to the study of well-known favourites such as worms, fruit flies and mice. Yet, up to the early 1980s plant biologists had every good reason to ignore Arabidopsis: neither did it seem to possess the characteristics of a good model organism, nor did it have any agricultural promise. The sudden prestige acquired by Arabidopsis research thus constitutes a... |
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Arabidopsis: Webster's Timeline History, 2004 - 2007 by Icon Group International (Author) Webster's bibliographic and event-based timelines are comprehensive in scope, covering virtually all topics, geographic locations and people. They do so from a linguistic point of view, and in the case of this book, the focus is on "Arabidopsis," including when used in literature (e.g. all authors that might have Arabidopsis in their name). As such, this book represents the largest compilation of timeline events associated with Arabidopsis when it is used in proper noun form. Webster's timelines cover bibliographic citations, patented inventions, as well as non-conventional and alternative meanings which capture ambiguities in usage. These furthermore cover all parts of speech (possessive, institutional usage, geographic usage) and contexts, including pop culture, the arts, social... |
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