 |
|
Orientation of antenna protein in photosynthetic bacteria described
April 03, 2009'Taco shell' protein
Researchers at Washington University in St. Louis have figured out the orientation of a protein in the antenna complex to its neighboring membrane in a photosynthetic bacterium, a key find in the process of energy transfer in photosynthesis.
Robert Blankenship, Ph.D., Markey Distinguished Professor of biology and chemistry in Arts & Sciences, led a team that for the first time combined chemical labeling with mass spectroscopy to verify the orientation. The team also included Michael Gross, Ph.D., Washington University professor of chemistry, immunology and medicine, and chemistry graduate students Jianzhong Wen and Hao Zhang. A paper describing this work appeared recently in the Proceedings of the National Academy of Sciences USA.
In green sulfur bacteria, which live in extremely dim environments with scarce visible light, the membrane-attached Fenna-Matthews-Olson (FMO) antenna protein serves as a sort of wire connecting the large peripheral chlorosome antenna complex with the organism's reaction center. These bacteria are related to extreme heat-loving bacteria that live at thermal vents on the ocean floor. Their antenna systems are much larger and more pronounced than those of other bacteria to take advantage of whatever geothermal light they can harvest.
Blankenship fondly refers to the FMO protein as the taco shell protein because of its structure: its ribbon-like backbone wraps around three clusters of seven chlorophylls, just like a taco shell around ground beef. The structure also is referred to as trimeric because of the three clusters.
The taco shell is a sort of "middleman" in the antenna system, sandwiched in between a larger antenna and a complex called the reaction center, where all the electron transfer chemistry takes place. Most of the absorption of light is carried out by a complex called the chlorosome that then transfers the energy to the trimeric protein that in turn transfers to the reaction center.
Photosynthesis transforms light, carbon dioxide and water into chemical energy in plants and some bacteria. The wavelike characteristic of this energy transfer process can explain its extreme efficiency, in that vast areas of phase space can be sampled effectively to find the most efficient path for energy transfer. "We used a combination of tried and true methods, but two that hadn't been used together in the past," said Blankenship. "The surface of the protein has various amino acid residues, and some of those are reactive to the chemical probe we added into the system. The surface residues that react to the probe are then labeled, and we isolate the protein and characterize where the label is in the protein by using mass spectroscopy. That's a kind of footprinting analysis.'
This allowed the researchers to determine how the protein is oriented on the membrane. The footprinting revealed that the energy will flow from the outer part of the antenna, through the mid-part and into the membrane where the reaction center is located.
"The bacteria use the energy of the pigments as a kind of ladder," he said. "As it goes on this ladder, it goes to lower and lower energy states and is guided down to the lowest energy state. That's the funneling effect - the physical guiding of the energy to the reaction center. By knowing exactly how this orientation is on the membrane, we determined the funneling property in a more precise ways."
The biochemical aspects of the project were done in the Blankenship lab, while the mass spectrometry analysis was done in the Washington University NIH Mass Spectrometry Resource Facility that is directed by Gross.
The trimeric protein - the taco shell protein - has a symmetry axis down the middle. The protein lays on the membrane with the symmetry axis perpendicular to the membrane. The combination of labeling and mass spectroscopy enabled the researchers to determine which side of the protein was up, which down.
"It turns out that the side that is down is the one that has the pigment with the lowest energy, which is exactly what you want to facilitate the energy transfer,' Blankenship said. "That's what you would imagine if you designed it yourself."
Washington University in St. Louis
In green sulfur bacteria, which live in extremely dim environments with scarce visible light, the membrane-attached Fenna-Matthews-Olson (FMO) antenna protein serves as a sort of wire connecting the large peripheral chlorosome antenna complex with the organism's reaction center. These bacteria are related to extreme heat-loving bacteria that live at thermal vents on the ocean floor. Their antenna systems are much larger and more pronounced than those of other bacteria to take advantage of whatever geothermal light they can harvest.
Blankenship fondly refers to the FMO protein as the taco shell protein because of its structure: its ribbon-like backbone wraps around three clusters of seven chlorophylls, just like a taco shell around ground beef. The structure also is referred to as trimeric because of the three clusters.
The taco shell is a sort of "middleman" in the antenna system, sandwiched in between a larger antenna and a complex called the reaction center, where all the electron transfer chemistry takes place. Most of the absorption of light is carried out by a complex called the chlorosome that then transfers the energy to the trimeric protein that in turn transfers to the reaction center.
Photosynthesis transforms light, carbon dioxide and water into chemical energy in plants and some bacteria. The wavelike characteristic of this energy transfer process can explain its extreme efficiency, in that vast areas of phase space can be sampled effectively to find the most efficient path for energy transfer. "We used a combination of tried and true methods, but two that hadn't been used together in the past," said Blankenship. "The surface of the protein has various amino acid residues, and some of those are reactive to the chemical probe we added into the system. The surface residues that react to the probe are then labeled, and we isolate the protein and characterize where the label is in the protein by using mass spectroscopy. That's a kind of footprinting analysis.'
This allowed the researchers to determine how the protein is oriented on the membrane. The footprinting revealed that the energy will flow from the outer part of the antenna, through the mid-part and into the membrane where the reaction center is located.
"The bacteria use the energy of the pigments as a kind of ladder," he said. "As it goes on this ladder, it goes to lower and lower energy states and is guided down to the lowest energy state. That's the funneling effect - the physical guiding of the energy to the reaction center. By knowing exactly how this orientation is on the membrane, we determined the funneling property in a more precise ways."
The biochemical aspects of the project were done in the Blankenship lab, while the mass spectrometry analysis was done in the Washington University NIH Mass Spectrometry Resource Facility that is directed by Gross.
The trimeric protein - the taco shell protein - has a symmetry axis down the middle. The protein lays on the membrane with the symmetry axis perpendicular to the membrane. The combination of labeling and mass spectroscopy enabled the researchers to determine which side of the protein was up, which down.
"It turns out that the side that is down is the one that has the pigment with the lowest energy, which is exactly what you want to facilitate the energy transfer,' Blankenship said. "That's what you would imagine if you designed it yourself."
Washington University in St. Louis
Photosynthetic Bacteria Current Events and Photosynthetic Bacteria News RSSVibrations key to efficiency of green fluorescent protein
University of California, Berkeley, chemists have discovered the secret to the success of a jellyfish protein whose green glow has made it the darling of biologists and the subject of the 2008 Nobel Prize in Physiology or Medicine.
Early life on Earth may have developed more quickly than thought
The Earth's climate was far cooler - perhaps more than 50 degrees - billions of years ago, which could mean conditions for life all over the planet were more conducive than previously believed, according to a research team that includes a Texas A&M University expert who specializes in geobiology.
The Rise of Oxygen Caused Earth's Earliest Ice Age
Geologists may have uncovered the answer to an age-old question - an ice-age-old question, that is.
Biodesign's Rittmann offers promising perspectives on society's energy challenge
Perhaps there is no greater societal need for scientific know-how than in finding new ways to meet future energy demands. Skyrocketing gas prices, an uncertain oil supply, increasing demand from around the world, and the looming threat of climate change have made identifying and developing realistic energy alternatives a national priority.
New twist on life's power source
A startling discovery by scientists at the Carnegie Institution puts a new twist on photosynthesis, arguably the most important biological process on Earth.
Small-scale parasitic battles may have epic evolutionary proportions
Scientists at MIT's Department of Civil and Environmental Engineering and the Technion Israel Institute of Technology have for the first time recorded the entire genomic expression of both a host bacterium and an infecting virus over the eight-hour course of infection.
Nasty bacteria need sunlight to do their worst
Certain types of bacteria have sunlight-sensing molecules similar to those found in plants, according to a new study. Surprisingly, at least one species-responsible for causing the flu-like disorder Brucellosis-needs light to maximize its virulence. The work suggests an entirely new model for bacterial virulence based on light sensitivity.
Scientists offer new view of photosynthesis
During 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.
Green Plants Share Bacterial Toxin
A toxin that can make bacterial infections turn deadly is also found in higher plants, researchers at UC Davis, the Marine Biology Laboratory at Woods Hole, Mass.
Freeze-dried mats of microbes awaken in Antarctic streambed, says U. of Colorado study
An experiment in a dry Antarctic stream channel has shown that a carpet of freeze-dried microbes that lay dormant for two decades sprang to life one day after water was diverted into it, said a University of Colorado at Boulder researcher.
More Photosynthetic Bacteria Current Events and Photosynthetic Bacteria News Articles
 |
Anoxygenic Photosynthetic Bacteria (Advances in Photosynthesis and Respiration) by R.E. Blankenship (Editor), M.T. Madigan (Editor), C.E. Bauer (Editor) Anoxygenic Photosynthetic Bacteria is a comprehensive volume describing all aspects of non-oxygen-evolving photosynthetic bacteria. The 62 chapters are organized into themes of: Taxonomy, physiology and ecology; Molecular structure of pigments and cofactors; Membrane and cell wall structure: Antenna structure and function; Reaction center structure and electron/proton pathways; Cyclic electron transfer; Metabolic processes; Genetics; Regulation of gene expression, and applications. The chapters have all been written by leading experts and present in detail the current understanding of these versatile microorganisms. The book is intended for use by advanced undergraduate and graduate students and senior researchers in the areas of microbiology, genetics, biochemistry,... |
![Characteristics of anaerobic ammonia removal by a mixed culture of hydrogen producing photosynthetic bacteria [An article from: Bioresource Technology]](http://ecx.images-amazon.com/images/I/512SA5QAAFL._SL160_.jpg) |
Characteristics of anaerobic ammonia removal by a mixed culture of hydrogen producing photosynthetic bacteria [An article from: Bioresource Technology] by H. Takabatake (Author), K. Suzuki (Author), I.B. Ko (Author), T. Noike (Author) This digital document is a journal article from Bioresource Technology, published by Elsevier in 2004. 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: It is known that the presence of ammonia inhibits hydrogen production by photosynthetic bacteria. In order to avoid it, a two-step process containing ammonia removal and hydrogen production was investigated in this study. Firstly, the effects of carbonate presence on ammonia removal by photosynthetic bacteria were investigated by the vial tests because it is known that the uptake of volatile fatty acids (VFAs) sometimes requires carbonate. The results of them showed that the presence of carbonate promoted the... |
|
Green Photosynthetic Bacteria by J.M. Olson (Author) | |
|
Photosynthetic Bacteria by E N Kondrat'eva (Author) | |
|
Antennas and Reaction Centers of Photosynthetic Bacteria: Structure, Interactions, and Dynamics (Springer Series in Chemical Physics) by M. E. Michel-Beyerle (Editor) | |
|
Strong Evidence of Galactic Cannibalism / Modeling Pain Relief on the Action of Marijuana / Photosynthetic Bacteria Bare Their DNA / Creatine Pills May Aid Memory and Cognition / Climate Change Can Slow Ocean's Gas Absorption (Science News, Volume 164, Number 7, August 16, 2003) by Julie Ann Miller (Editor) | |
|
The Reaction Center of Photosynthetic Bacteria: Structure and Dynamics by M. E. Michel-Beyerle (Editor) Results of this third Feldafing Meeting can be considered as the harvest of novel techniques in spectroscopy, biochemistry and molecular biology to the bacterial photosynthetic reaction center. New information pertains to the crystallographic and electronic structure as well as to the dynamics of primary events and the role of the protein. The answer to one long-standing problem, the mechanism of primary charge separation, converges towards a sequential scheme, supported by femtosecond spectroscopy on reaction centers with selectively modified energetics. | |
|
Reaction Centers of Photosynthetic Bacteria: Feldafing-Ii-Meeting (Springer Series in Biophysics) by M. E. Michel-Beyerle (Editor) This text is an updated record of the most recent insight into the structure/function relationship of reaction centres from photosynthetic bacteria. It addresses in particular, interactions and dynamics which determine the ultra-high quantum yield of photo-induced charge separation in these energy-transforming molecular machines. Of particular interest is the still controversial issue of the primary charge separation mechanism as well as the effects of well-defined modifications, introduced either by mutagenic replacements in the protein matrix or by chemical exchange of reaction centre pigments. Also described are the methods used for the characterization of interactions and dynamics important for electron transfer processes in the reaction centre. | |
|
Aerobic Photosynthetic Bacteria by Keiji Harashima (Author), Tsuneo Shiba (Author), Norio Murata (Editor) | |
|
The Photosynthetic Bacteria by R. Clayton (Editor) |
| © 2009 BrightSurf.com |