 |
|
Scientists offer new view of photosynthesis
May 04, 2007During the remarkable cascade of events of photosynthesis, plants approach the pinnacle of stinginess by scavenging nearly every photon of available light energy to produce food. Yet after many years of careful research into its exact mechanisms, some key questions remain about this fundamental biological process that supports all life on earth.
Now, a large research team led by Neal Woodbury, a scientist at ASU's Biodesign Institute, has come up with a new insight into the mechanism of photosynthesis, which involves the orchestrated movement of proteins on the timescale of a millionth of a millionth of a second. Their findings are described in "Protein Dynamics Control the Kinetics of Initial Electron Transfer in Photosynthesis," in the May 4 issue of Science.
"The studies that led up to this work initiated 20 years ago when Jim Allen and I looked at one of our mutants and thought our spectrometer was broken," Woodbury said. "That mutant turned out to be the first of a long series of mutations that systematically altered the energy of the initial reaction." Since then, Woodbury and colleagues have managed to shed light on an amazing process that provides earth's primary power source.
To get a closer look at what was happening during photosynthesis, the team used a well studied purple photosynthetic bacterium called Rhodobacter sphaeroides. This type of organism was likely one of the earliest photosynthetic bacteria to evolve. The researchers focused their efforts by studying the center stage of photosynthesis, the reaction center, where light energy is funneled into specialized chlorophyll binding proteins.
The textbook picture of photosynthesis represents the reaction center proteins as a scaffold, holding chlorophyll molecules at a highly optimized distance and orientation so that electrons can hop from one chlorophyll to another. With the chlorophylls in just the right position, any systematic protein movement was thought to be merely a side product of electrons shuttling between chlorophyll molecules.
Woodbury and his colleagues tried to uncover more of the physical mechanism driving photosynthesis by creating mutants that would theoretically tweak the electron transfer relationships between molecules in the reaction center.
"After years of failure trying to break the system by changing the energetics, we were left with the nagging question of how it continued to work so well," said Woodbury, ASU professor of Chemistry and Biochemistry and director of Biodesign's Center for Bio-Optical Nanotechnology.
The researchers started to inch closer to an answer when Wang, a postdoctoral research associate in Woodbury's lab, noticed something in common with all of the different mutants. When using a new model based on reaction-diffusion kinetics, Wang saw that the curves representing how fast electrons moved in the reaction center had a similar shape. "He decided that there must be some sort of underlying physical principle involved," Woodbury said.
Not many research groups are equipped to measure the early events in photosynthesis because of the extremely short timescale -similar to the amount of time it takes a supercomputer to carry out a single flop. Wang was able to use the ultrafast laser facility (funded by the National Science Foundation), which acts like a high-speed motion picture camera that can capture data from these lightning-fast reactions.
"He tried a really hard experiment, and he was actually able to measure the protein motion and match it to electron transfer," Woodbury said. This discovery helped the researchers understand why changing the energetics didn't knock out photosynthesis.
The movement of the reaction center proteins during photosynthesis allows the plant or bacteria to harness light energy efficiently even if conditions aren't optimal. So, while Woodbury and colleagues made it difficult for photosynthesis to work, the proteins were able to compensate by moving and energetically guiding the electrons through their biological circuit.
According to Woodbury, the reaction center proteins work for electrons in a way similar to how a slow moving elevator with no doors would work for people. The electrons are able to get off at the spot that they need to because the protein motion adjusts the energetics until it is just right. Even if the elevator starts a little too high or low (initial energies are not optimal), the people (electrons) can still get off on the right floor.
This way of representing the electron transfer process successfully captured the contribution of the protein movements to the rate of the reaction. The scientists were then able to quantitatively model the effect of the mutations on the initial rate of photosynthetic electron transfer and answer questions that had been haunting them for 20 years.
The answers may be good news for the development of organic solar cells, which have been of commercial interest due to their relatively low cost compared to traditional silicon solar cells. "Some of the problems that you have with the organic photovoltaics arise from the fact that they don't work under all of the conditions you want them to," Woodbury said.
The robustness of the natural system may offer some useful lessons for engineers trying to improve on current technologies. Woodbury proposed that there might be a way to increase the flexibility of the system used in organic solar cells by incorporating solvents that move on a variety of time scales that could "tune" the molecules to work in a wider variety of conditions.
Woodbury also expects that this new research will help move the study of photosynthesis forward. "It's changed the way I look at how photosynthesis works and has opened up a whole set of new questions," he said.
"One of the areas that we're particularly interested in is how the absorption of light starts protein movement," Woodbury said. The researchers are also looking for future experiments to help explain what sort of protein movements may be occurring in the reaction center and then try to match these findings with current computer models of protein movement.
Arizona State University
To get a closer look at what was happening during photosynthesis, the team used a well studied purple photosynthetic bacterium called Rhodobacter sphaeroides. This type of organism was likely one of the earliest photosynthetic bacteria to evolve. The researchers focused their efforts by studying the center stage of photosynthesis, the reaction center, where light energy is funneled into specialized chlorophyll binding proteins.
The textbook picture of photosynthesis represents the reaction center proteins as a scaffold, holding chlorophyll molecules at a highly optimized distance and orientation so that electrons can hop from one chlorophyll to another. With the chlorophylls in just the right position, any systematic protein movement was thought to be merely a side product of electrons shuttling between chlorophyll molecules.
Woodbury and his colleagues tried to uncover more of the physical mechanism driving photosynthesis by creating mutants that would theoretically tweak the electron transfer relationships between molecules in the reaction center.
"After years of failure trying to break the system by changing the energetics, we were left with the nagging question of how it continued to work so well," said Woodbury, ASU professor of Chemistry and Biochemistry and director of Biodesign's Center for Bio-Optical Nanotechnology.
The researchers started to inch closer to an answer when Wang, a postdoctoral research associate in Woodbury's lab, noticed something in common with all of the different mutants. When using a new model based on reaction-diffusion kinetics, Wang saw that the curves representing how fast electrons moved in the reaction center had a similar shape. "He decided that there must be some sort of underlying physical principle involved," Woodbury said.
Not many research groups are equipped to measure the early events in photosynthesis because of the extremely short timescale -similar to the amount of time it takes a supercomputer to carry out a single flop. Wang was able to use the ultrafast laser facility (funded by the National Science Foundation), which acts like a high-speed motion picture camera that can capture data from these lightning-fast reactions.
"He tried a really hard experiment, and he was actually able to measure the protein motion and match it to electron transfer," Woodbury said. This discovery helped the researchers understand why changing the energetics didn't knock out photosynthesis.
The movement of the reaction center proteins during photosynthesis allows the plant or bacteria to harness light energy efficiently even if conditions aren't optimal. So, while Woodbury and colleagues made it difficult for photosynthesis to work, the proteins were able to compensate by moving and energetically guiding the electrons through their biological circuit.
According to Woodbury, the reaction center proteins work for electrons in a way similar to how a slow moving elevator with no doors would work for people. The electrons are able to get off at the spot that they need to because the protein motion adjusts the energetics until it is just right. Even if the elevator starts a little too high or low (initial energies are not optimal), the people (electrons) can still get off on the right floor.
This way of representing the electron transfer process successfully captured the contribution of the protein movements to the rate of the reaction. The scientists were then able to quantitatively model the effect of the mutations on the initial rate of photosynthetic electron transfer and answer questions that had been haunting them for 20 years.
The answers may be good news for the development of organic solar cells, which have been of commercial interest due to their relatively low cost compared to traditional silicon solar cells. "Some of the problems that you have with the organic photovoltaics arise from the fact that they don't work under all of the conditions you want them to," Woodbury said.
The robustness of the natural system may offer some useful lessons for engineers trying to improve on current technologies. Woodbury proposed that there might be a way to increase the flexibility of the system used in organic solar cells by incorporating solvents that move on a variety of time scales that could "tune" the molecules to work in a wider variety of conditions.
Woodbury also expects that this new research will help move the study of photosynthesis forward. "It's changed the way I look at how photosynthesis works and has opened up a whole set of new questions," he said.
"One of the areas that we're particularly interested in is how the absorption of light starts protein movement," Woodbury said. The researchers are also looking for future experiments to help explain what sort of protein movements may be occurring in the reaction center and then try to match these findings with current computer models of protein movement.
Arizona State University
Photosynthesis Current Events and Photosynthesis News RSSBeyond sunlight: Explorers census 17,650 ocean species between edge of darkness and black abyss
Census of Marine Life scientists have inventoried an astonishing abundance, diversity and distribution of deep sea species that have never known sunlight - creatures that somehow manage a living in a frigid black world down to 5,000 meters (~3 miles) below the ocean waves.
Oceans' uptake of manmade carbon may be slowing
The oceans play a key role in regulating climate, absorbing more than a quarter of the carbon dioxide that humans put into the air.
UT Knoxville and ORNL researchers turn algae into high-temperature hydrogen source
In the quest to make hydrogen as a clean alternative fuel source, researchers have been stymied about how to create usable hydrogen that is clean and sustainable without relying on an intensive, high-energy process that outweighs the benefits of not using petroleum to power vehicles.
Antarctica glacier retreat creates new carbon dioxide store
Large blooms of tiny marine plants called phytoplankton are flourishing in areas of open water left exposed by the recent and rapid melting of ice shelves and glaciers around the Antarctic Peninsula.
Newly Discovered Fat Molecule: An Undersea Killer with an Upside
A chemical culprit responsible for the rapid, mysterious death of phytoplankton in the North Atlantic Ocean has been found by collaborating scientists at Rutgers University and the Woods Hole Oceanographic Institution (WHOI). This same chemical may hold unexpected promise in cancer research.
Chemists describe solar energy progress and challenges, including the 'artificial leaf'
Scientists are making progress toward development of an "artificial leaf" that mimics a real leaf's chemical magic with photosynthesis - but instead converts sunlight and water into a liquid fuel such as methanol for cars and trucks.
Toward home-brewed electricity with 'personalized solar energy'
New scientific discoveries are moving society toward the era of "personalized solar energy," in which the focus of electricity production shifts from huge central generating stations to individuals in their own homes and communities.
Sun or shade: Pecan leaves' photosynthetic light response evaluated
Pecan, the most valuable nut tree native to North America, is native from northern Illinois and southeastern Iowa to the Gulf Coast of the United States, where it grows abundantly along the Mississippi River, the rivers of central and eastern Oklahoma, and Texas.
Reflective film can boost profits for apple growers
In a research report published in a recent issue of HortTechnology, scientists Ignasi Iglesias and Simó Alegre examined the effects of covering orchard floors with reflective films on fruit color, fruit quality, canopy light distribution, orchard temperature, and profitability.
Iron controls patterns of nitrogen fixation in the Atlantic
Scientists including researchers from the National Oceanography Centre, Southampton and the University of Essex have discovered that interactions between iron supply, transported through the atmosphere from deserts, and large-scale oceanic circulation control the availability of a crucial nutrient, nitrogen, in the Atlantic.
More Photosynthesis Current Events and Photosynthesis News Articles
 |
Photosynthesis (Science Concepts, Second Series) by Alvin Silverstein (Author), Virginia B. Silverstein (Author), Laura Silverstein Nunn (Author) Explains photosynthesis, the process responsible for providing the material and energy for all living things, and discusses such related issues as respiration, the carbon cycle, acid rain, and the greenhouse effect. |
 |
What Is Photosynthesis? DVD Starring: Artist Not Provided Photosynthesis is a biological process that benefits all living things. The chemical reactions that occur during the process of photosynthesis are described with the help of graphics and easy-to-follow explanations. This video makes learning about plants and how they function both fun and interesting. |
 |
Molecular Mechanisms of Photosynthesis by Robert E Blankenship (Author) Molecular Mechanisms of Photosynthesis stands as an ideal introduction to this subject. Robert Blankenship, a leading authority in photosynthesis research, offers a modern approach to photosynthesis in this accessible and well-illustrated text. The book provides a concise overview of the basic principles of energy storage and the history of the field, then progresses into more advanced topics such as electron transfer pathways, kinetics, genetic manipulations, and evolution. Throughout, Blankenship includes an interdisciplinary emphasis that makes this book appealing across fields. Leading authority in Photosynthesis and the the President of the International Society of Photosynthesis Research. First authoritative text to enter the market in 10 years. Stresses an... |
 |
Photosynthesis: Changing Sunlight into Food (Nature's Changes) by Bobbie Kalman (Author) This title contains a book & CD. Photosynthesis is the basis for all life on Earth! This exciting and sensitive book looks at how plants use a gas that is poisonous to people and animals to create food and oxygen for all creatures with the help of the Sun. The CD's approximate running time is 30 minutes. |
 |
Phonosynthesis by DJ Irene |
 |
Photosynthesis Rhyme, Results Rhythm (Primary Contributor) |
 |
Eating the Sun: How Plants Power the Planet by Oliver Morton (Author) Wherever there is greenery, photosynthesis is working to make oxygen, release energy, and create living matter from the raw material of sunlight, water, and carbon dioxide. Without photosynthesis, there would be an empty world, an empty sky, and a sun that does nothing more than warm the rocks and reflect off the sea. Eating the Sun is the story of a world in crisis; an appreciation of the importance of plants; a history of the earth and the feuds and fantasies of warring scientists; a celebration of how the smallest things, enzymes and pigments, influence the largest things, the oceans, the rainforests, and the fossil fuel economy. Oliver Morton offers a fascinating, lively, profound look at nature's greatest miracle and sounds a much-needed call to arms—illuminating a... |
 |
Photosynthesis Also With: Josh Kalis (Primary Contributor), Rob Dyrdek (Primary Contributor), Jason Dill (Primary Contributor), Danny Way (Primary Contributor), Anthony van Engelen (Primary Contributor), Anthony Pappalardo (Primary Contributor), Pat Corcoran (Primary Contributor), Kerry Getz (Primary Contributor), Fred Gall (Primary Contributor), Tim O'Connor (Primary Contributor) Skater list Anthony Pappalardo Anthony Van Engelen Danny Garcia Fred Gall Jason Dill Josh Kalis Kerry Getz Mark Appleyard Pat Corcoran Rob Dyrdek Tim O'Connor |
 |
Photosynthesis Subject Art Poster Print, 24x18 by AllPosters.com AllPosters.com is the world's #1 seller of posters, prints, photographs, specialty products and framed art. We're dedicated to bringing our customers the best selection of high quality wall décor that is perfect for their home or office. Browse our catalog of over 300,000 items that include entertainment and specialty posters, decorative prints, and art reproductions. Whether you're looking for your favorite movie or music poster, a framed Monet reproduction, or a print of the Eiffel Tower you will find it at AllPosters.com. Visit our Amazon store today at www.amazon.com/allposters to find Special Offers and search by subject category or artist. AllPosters.com provides unmatched service with a 100% satisfaction guarantee. We ship internationally to over 80 countries. Decorate your... |
 |
Vintage Photosynthesis Biochemistry Science Film DVD: Classic Water, Oxygen Cycle, Plant Life, Sunlight & Carbon Video Photosynthesis is pretty much the most important biological process that takes place on this planet, because almost everything living depends on photosynthesis to survive. Gift of Green is a vintage science film dealing with the process of photosynthesis. Now, this digitized film is available on DVD for the first time ever! Table Of Contents: (1) Gift of Green (1946) - This is a vintage science class film featuring animation that shows the process of photosynthesis. Highly recommended and well-made for its era! - 16 Minutes |
| © 2009 BrightSurf.com |