Researchers studying more effective ways to convert woody plant matter into biofuels have identified fundamental forces that change plant structures during pretreatment processes used in the production of bioenergy. Experimental techniques including neutron scattering and x-ray analysis with supercomputer simulations revealed unexpected findings about what happens to water molecules trapped between cellulose fibers.
A research team including a Penn State chemical...
Around 3% of all plants use an advanced form of...
Researchers have developed a system that...
Watching a plant grow and develop roots can be a long and tiresome process, but watching this process closely can reveal what happens to a genetically modified organism. A recently developed system from IntelLiDrives and the Univ. of Wisconsin-Madison uses robotic cameras and computerized motion control systems to make this process easier.
Farmers who grow corn and soybeans can take advantage of government price support programs and crop insurance, but similar programs are not available for those who grow biomass crops. A new study recommends a framework for contracts between growers and biorefineries to help spell out expectations and designate who will assume the risks and costs.
Four teams of researchers in the United States and the United Kingdom recently were awarded more than $12 million to begin a program of novel research to revolutionize current farming methods by giving crops the ability to thrive without using costly, polluting artificial fertilizers.
The world’s croplands could boost food available for people by 70% without clearing more land, according to research from the Univ. of Minnesota. This could be accomplished just by shifting from producing animal feed and biofuels to producing exclusively food for human consumption, researchers say.
This summer's "dead zone" at the bottom of the Gulf of Mexico, where there's so little oxygen that starfish suffocate, is bigger than average but doesn't approach record size as scientists had predicted, according to findings released this week. The area of low oxygen covers 5,840 square miles of the Gulf floor—roughly the size of Connecticut.
All plants need nitrogen to convert into ammonia, but only a small number of plants can fix nitrogen from the atmosphere. The rest are helped by synthetic fertilizers, which have been blamed for nitrogen pollution. A scientist in the U.K., Edward Cocking, has found a specific strain of nitrogen-fixing bacteria in sugar cane which he discovered could intracellularly colonize all major crop plants. The technology is being commercialized.
Jatropha, a plant variety that has been pursued as possible source for biofuel, has seeds with high oil content. But the oil's potential as a biofuel is limited because, for large-scale production, this shrub-like plant needs the same amount of care and resources as crop plants. By focusing on the plant’s drought response and using engineered genetics, the scientists have learned more about potentially improving the plant’s function.
Researchers are now designing robots for the last frontier of agricultural mechanization: fruits and vegetables. Sensitive to bruising, these crops have resisted mechanization. But engineers from Silicon Valley have been working on the Lettuce Bot, which can thin a field of lettuce in the time it takes about 20 works to do the job by hand.
Ways to ripen, or spoil, fruit have been known for thousands of years—as the Bible can attest—but now the genes underlying these phenomena of nature have been revealed. Researchers led by the Salk Institute have traced the thousands of genes in a plant that are activated once ethylene, a gas that acts as a plant growth hormone, is released. This study is the first such comprehensive genomic analysis of ethylene's biological trigger.
An international team of scientists has developed crop models to better forecast food production to feed a growing population—projected to reach 9 billion by mid-century—in the face of climate change. The team recently unveiled an all-encompassing modeling system that integrates multiple crop simulations with improved climate change models.
Ripening fruit, vegetables, and flowers release ethylene, which works as a plant hormone. Ethylene accelerates ripening, so other unripened fruit also begins to ripen—fruit and vegetables quickly spoil and flowers wilt. researchers in Japan have now introduced a new catalytic system for the fast and complete degradation of ethylene. This could keep the air in warehouses ethylene-free, keeping perishable products fresh longer.
Starch is one of the most important components of the human diet and provides 20 to 40% of our daily caloric intake. A team of Virginia Tech researchers has succeeded in transforming cellulose into starch in a process that could provide a previously untapped nutrient source from plants not traditionally thought of as food crops. The process works with cellulose from any plant.
The Dow Chemical Company and Dow AgroSciences officially opened a new 175,000-square-foot R&D facility this week. Part laboratory, part greenhouse, the laboratory is part of a global growth plan for Dow AgroSciences’ research efforts for the development and commercialization of new crop protection and seed, traits, and oils products for growers around the world.
Proteomics is a powerful technique for examining the structure and function of the proteome. For some organisms, proteomics can uncover the relationship between DNA, RNA, and the production of proteins. For those without a sequenced genome, proteomics can finding new proteins. In a new study, researchers have demonstrated the suitability of proteomics in determining the composition of gymnosperm pollination drops.
Sandia National Laboratories is developing a suite of complementary technologies to help the emerging algae industry detect and quickly recover from algal pond crashes, an obstacle to large-scale algae cultivation for future biofuels. The research draws upon Sandia's longstanding expertise in microfluidics technology, its strong bioscience research program and significant internal investments.
In 2011, Lake Erie experienced a record-breaking algae bloom that began in the lake's Western region in mid-July and eventually covered an area of 230 square miles. At its peak in October, the bloom had expanded to more than 1,930 square miles, three times greater than any other bloom on record. According to recent research, the bloom was triggered by long-term agricultural practices coupled with extreme precipitation, followed by weak lake circulation and warm temperatures.
Scientists have shown that an enzyme in corn responsible for reading information from DNA can prompt unexpected changes in gene activity—an example of epigenetics that breaks accepted rules of genetic behavior. Though some evidence has suggested that epigenetic changes can bypass DNA’s influence to carry on from one generation to the next, this is the first study to show that this epigenetic heritability can be subject to selective breeding.
Isolation of DNA from some organisms is a routine procedure. For example, you can buy a kit at your local pharmacy or grocery store that allows you to swab the inside of your cheek and send the sample for DNA sequencing. However, for other organisms, DNA extraction is much more problematic. Researchers at Desert Botanical Garden in Phoenix, Arizona, have developed a novel procedure that greatly simplifies genomic DNA isolation from cactus tissue.
According to Michigan State University plant biologist Carolyn Malmstrom, when we start combining the qualities of different types of plants into one, there can be unanticipated results. In the domestication of wild plants for bioenergy, for example, long-lived plants are being selected for fast growth like annuals. In contrast, perennial plants in nature grow slower, but are usually better equipped to fight off invading viruses. When wild-growing perennials do get infected they can serve as reservoirs for viruses.
With help from a wind tunnel and the latest DNA technology, U.S. Department of Agriculture scientists are shedding light on the travel patterns of microbes in soils carried off by strong winds. The work has implications for soil health and could lead to management practices that minimize the damage to soils caused by wind erosion.
A curious characteristic of willows is that when they are cultivated for green energy they can yield five times more biofuel if they grow diagonally, compared with those that grow naturally straight up. Scientists were previously unable to explain why some willows produced more biofuel than others, but researchers have now identified a genetic trait that causes this effect and is activated in some trees when they sense they are at an angle, such as where they are blown sideways in windy conditions.
Spoilage of harvests on their way to market is a major contribution to food shortages in India. A university-industry partnership has produced an innovative solar chiller container and distribution plan to change that. The SolerCool container and business venture has been developed as a solar generator that can store energy.
Beyond recent warnings from the United Nations about climate change tipping points, researchers are beginning to make practical insights about the effects a greater concentration of greenhouse gas has on areas of industry like agriculture. Researchers have recently found that certain high-yield dwarf varieties of plants such as rice are actually struggling to meet yield predictions because high carbon dioxide levels prevent them from producing a vital acid.
Scientists from the United States, United Kingdom and Germany recently completed the first analysis of the bread wheat genome, one of the "big three" global crops upon which mankind depends for nutrition. The work is a major breakthrough in understanding an exceptionally large and complex genome, and it lays strong foundations for improving wheat through breeding practices and genetic engineering, say researchers.
The natural decay of organic carbon contributes more than 90% of the yearly carbon dioxide released into Earth's atmosphere and oceans. Understanding the rate at which leaves decay can help scientists predict this global flux of carbon dioxide. But a single leaf may undergo different rates of decay depending on a number of variables. Researchers have just built a mathematical model that incorporates these variables, and have discovered a commonality within the diversity of leaf decay.
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