First evidence that blocking key energy protein kills cancer cells
Researchers in Taiwan report for the first time that blocking a key energy-supplying protein kills cancer cells. The finding, described as the first to test possible medical uses of so-called ATP-synthase inhibitors, may lead to new and more effective anti-cancer medications, according to their report, which is scheduled for the April 4 issue of ACS' monthly Journal of Proteome Research.
In the new study, Hsueh-Fen Juan and colleagues focused on ATP synthase, a key protein involved in producing the energy-rich molecules of ATP that power all life processes. For years researchers thought that the protein existed only in mitochondria, structures located inside cells that convert nutrients into energy. Recent studies found high levels of ATP synthase on the surface of cancer cells, but until now the medical implications went unexplored.
The researchers analyzed tissue samples from breast cancer patients and found for the first time that the surface of breast cancer cells contains high levels of ATP synthase. In cell studies, exposing breast cancer cells to a substance that blocks ATP synthase killed the cancer cells but did not harm normal cells, the researchers say. The findings suggest that ATP synthase inhibitors may represent a new approach for fighting breast cancer and other cancer types, they say. - MTS
ARTICLE: "Targeting Therapy for Breast Carcinoma by ATP Synthase Inhibitor Aurovertin B"
CONTACT:
Hsueh-Fen Juan, Ph.D.
National Taiwan University
Taipei, Taiwan
Electric shocks boost plants' production of commercially useful chemicals
Now for some "shocking" news about plants: Exposing plants to electricity can boost production of useful plant chemicals and may provide a cheaper, safer, and more efficient method for producing medicines, pesticides, and other commercially important plant-based materials, researchers in Arizona and Oklahoma report. Their study is scheduled for the April 4 issue of ACS' Biotechnology Progress, a bi-monthly journal.
Researchers have known for years that plants can produce a diverse array of substances as part of their natural response to environmental factors such as microbial infection, sunlight, and chemical exposure. To boost levels of plant chemicals for commercial purposes, scientists have often turned to synthetic chemical additives as well as genetic engineering, which can be expensive and potentially harmful. A better method is needed, scientists say.
In the new study, Hans VanEtten and colleagues studied the effects of electricity on the ability of the pea plant to produce pisatin, an antifungal substance. They found that exposing pea plants to certain sub-lethal doses of electric current produced 13 times higher amounts of pisatin than plants that were not exposed to electricity. The researchers observed similar increases in plant chemicals produced by a variety of other plants when exposed to electricity. There were no adverse effects on the plants. - MTS
ARTICLE: "Sub-lethal Levels of Electric Current Elicit the Biosynthesis of Plant Secondary Metabolites"
CONTACT:
Hans VanEtten, Ph.D.
University of Arizona
Tucson, Arizona 85721
Chemical signaling may power nanomachines
In a finding that could provide controlled motion in futuristic nanomachines used for drug delivery, fuel cells, and other applications, researchers in Pennsylvania report that chemical signaling between synthetic microcapsules can trigger and direct movement of these capsules. Their study is scheduled for the currrent isssue of ACS Nano, a monthly journal.
Researchers theorize that synthetic capsules can communicate with each other by physically shuffling chemical signals from capsule to capsule, much like passing water through a fireman's bucket brigade. Scientists recently suggested that this same signaling process also appears capable of sending cues to direct cell movement.
In the new study, Anna C. Balazs and colleagues used computer models to simulate the chemical signaling. They modeled a porous polymer microcapsule filled with nanonparticles to imitate a biological cell. When placed next to an empty capsule, nanoparticles from the filled capsule initiated the motion of the empty capsule, which in turn caused the movement of the filled "signaling" capsule. The same locomotion process could be engineered into futuristic nanomachines to help direct their movement through the body or through fuel cells, the researchers suggest. - MTS
ARTICLE:"Modeling Microcapsules That Communicate through Nanoparticles To Undergo Self-Propelled Motion"
CONTACT:
Anna C. Balazs, Ph.D.
University of Pittsburgh
Pittsburgh, Pennsylvania 15261
Elevated concentrations of metals in China's e-waste recycling workshops
In a case study on how not to recycle electronic waste (e-waste), scientists in the United States and Hong Kong have documented serious environmental contamination with potentially toxic metals from crude e-waste recycling in a village located in southeast China. Recycling methods used in family-run workshops could pose a serious health risk to residents of the area through ingestion and inhalation of contaminated dust, the researchers say. Their study is scheduled for the April 15 issue of ACS' Environmental Science & Technology, a semi-monthly journal.
The process of discarding computers and other consumer electronics has emerged as one of the fastest growing segments of the global waste stream. Known as e-waste, these scrapped electronic goods contain lead, copper and other hazardous materials, which can release dangerous toxins that cause air and water contamination. Up to 50-million tons of e-waste is generated worldwide each year - enough to fill a line of garbage collection trucks stretching halfway around the world - according to the United Nations Environment Program.
China is now the destination for 70 percent of the computers, TVs, cell phones, and other e-waste recycled globally each year. Ming H. Wong and colleagues collected dust samples from roads adjacent to e-waste processing workshops in Guiya, China, to find that lead levels were 330 and 371 times higher than non e-waste sites located 5 miles and 19 miles away. Copper levels were 106 and 155 times higher. "Currently, there are no guidelines or regulations for heavy metals in dust. It is hoped that the results can serve as a case study for similar e-waste activities in countries such as Africa, India and Vietnam where e-waste is becoming a growing problem, so that the same mistakes could be prevented." - JS
ARTICLE: "Heavy Metals Concentrations of Surface Dust from e-Waste Recycling and Its Human Health Implications in Southeast China"
CONTACT:
Ming H. Wong, Ph.D.
Hong Kong Baptist University
Hong Kong, China
Debate sharpens over fertilizing the oceans to control global warming
As millions of people prepare to fertilize their lawns and gardens this spring, scientists are still in the midst of intensive hand-wringing over the pros and cons of fertilizing the world's oceans in an effort to control global warming, according to an article scheduled for the March 31 issue of Chemical & Engineering News, ACS' weekly newsmagazine.
C&EN Associate Editor Rachel A. Petkewich explains that in theory, ocean fertilization would remove carbon dioxide from the atmosphere by spurring the growth of tiny marine plants termed plankton that need CO2 for growth. First proposed years ago, ocean fertilization has taken on new dimensions now that hundreds of start-up companies are preparing to offer ocean-fertilization services, Petkewich says.
Although fertilization can stimulate the growth of plankton and draw down atmospheric carbon dioxide, scientists do not know whether it would be effective in permanently keeping the carbon dioxide sequestered in the oceans. Environmental groups worry about safety aspects, and government agencies are concerned about the lack of laws to regulate ocean fertilization, the article suggests.
ARTICLE: "Fertilizing the ocean with iron"
The American Chemical Society - the world's largest scientific society - is a nonprofit organization chartered by the U.S. Congress and a global leader in providing access to chemistry-related research through its multiple databases, peer-reviewed journals and scientific conferences. Its main offices are in Washington, D.C., and Columbus, Ohio.
Source: Michael Woods
American Chemical Society
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