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New possibilities for hydrogen-producing algae
March 25, 2009Stanford, CA- Photosynthesis produces the food that we eat and the oxygen that we breathe ― could it also help satisfy our future energy needs by producing clean-burning hydrogen? Researchers studying a hydrogen-producing, single-celled green alga, Chlamydomonas reinhardtii, have unmasked a previously unknown fermentation pathway that may open up possibilities for increasing hydrogen production.
C. reinhartii, a common inhabitant of soils, naturally produces small quantities of hydrogen when deprived of oxygen. Like yeast and other microbes, under anaerobic conditions this alga generates its energy from fermentation. During fermentation, hydrogen is released though the action of an enzyme called hydrogenase, powered by electrons generated by either the breakdown of organic compounds or the splitting of water by photosynthesis. Normally, only a small fraction of the electrons go into generating hydrogen. However, a major research goal has been to develop ways to increase this fraction, which would raise the potential yield of hydrogen.
In the new study by Dubini et al*, published in the Journal of Biological Chemistry, researchers at the Carnegie Institution's Department of Plant Biology, the National Renewable Energy Laboratory (NREL), and the Colorado School of Mines (CSM), examined metabolic processes in a mutant strain that was unable to assemble an active hydrogenase enzyme. The researchers, who include Alexandra Dubini (NREL), Florence Mus (Carnegie), Michael Seibert (NREL), Matthew Posewitz (CSM), and Arthur Grossman (Carnegie), expected the cell's metabolism to compensate by increasing metabolite flow along other known fermentation pathways, such as those producing formate and ethanol as end products. Instead, the algae activated a pathway leading to the production of succinate, which was previously not associated with fermentation metabolism in C. reinhardtii. Notably, succinate, a widely used industrial chemical normally synthesized from petroleum, is included in the Department of Energy's list of the top 12 value added chemicals from biomass.
"We actually didn't know that this particular pathway for fermentation metabolism existed in the alga until we generated the mutant," says Carnegie's Arthur Grossman. "This finding suggests that there is significant flexibility in the ways that soil-dwelling green algae can metabolize carbon under anaerobic conditions. By blocking and modifying some of these metabolic pathways, we may be able to augment the donation of electrons to hydrogenase under anaerobic conditions and produce elevated levels of hydrogen."
Grossman points out that it makes evolutionary sense that a soil organism such as Chlamydomonas would have a variety of metabolic pathways at its disposal. Oxygen levels, nutrient availability, and levels of metals and toxins can be extremely variable in soils, over both the short and long term. "In such an environment", Grossman says, "these organisms must evolve flexible metabolic circuits; the variety of conditions to which the organisms are exposed might favor one pathway for energy metabolism over another, which would help the organism compete in the soil environment over evolutionary time."
Grossman led the effort to generate a fully sequenced Chlamydomonas genome, which has allowed researchers to identify key genes encoding proteins involved in both fermentation and hydrogen production. Grossman feels that it is of immediate importance to generate new mutant strains to help us understand how we may be able to alter fermentation metabolism and the production of hydrogen. NREL's Michael Seibert, the project's Principal Investigator, observed that "the overarching goal of the work is to gain a fundamental understanding of the total suite of metabolic processes occurring in Chlamydomonas and how they interact; this discovery effort will lead to the development of novel ways to produce renewable hydrogen and other biofuels, which will benefit all of us".
"These are really exciting times in the field," says Matthew Posewitz. "The tools developed at Carnegie and by other groups in the field are presenting unprecedented opportunities for scientists to make important advances in our understanding of the basic biology of organisms such as Chlamydomonas."
As an energy source to potentially replace fossil fuels, hydrogen would greatly reduce the emission of greenhouse gases. Proponents of algal-based hydrogen production point out that, unlike ethanol produced from crops, it would not compete with food production for agricultural land.
Carnegie Institution
"We actually didn't know that this particular pathway for fermentation metabolism existed in the alga until we generated the mutant," says Carnegie's Arthur Grossman. "This finding suggests that there is significant flexibility in the ways that soil-dwelling green algae can metabolize carbon under anaerobic conditions. By blocking and modifying some of these metabolic pathways, we may be able to augment the donation of electrons to hydrogenase under anaerobic conditions and produce elevated levels of hydrogen."
Grossman points out that it makes evolutionary sense that a soil organism such as Chlamydomonas would have a variety of metabolic pathways at its disposal. Oxygen levels, nutrient availability, and levels of metals and toxins can be extremely variable in soils, over both the short and long term. "In such an environment", Grossman says, "these organisms must evolve flexible metabolic circuits; the variety of conditions to which the organisms are exposed might favor one pathway for energy metabolism over another, which would help the organism compete in the soil environment over evolutionary time."
Grossman led the effort to generate a fully sequenced Chlamydomonas genome, which has allowed researchers to identify key genes encoding proteins involved in both fermentation and hydrogen production. Grossman feels that it is of immediate importance to generate new mutant strains to help us understand how we may be able to alter fermentation metabolism and the production of hydrogen. NREL's Michael Seibert, the project's Principal Investigator, observed that "the overarching goal of the work is to gain a fundamental understanding of the total suite of metabolic processes occurring in Chlamydomonas and how they interact; this discovery effort will lead to the development of novel ways to produce renewable hydrogen and other biofuels, which will benefit all of us".
"These are really exciting times in the field," says Matthew Posewitz. "The tools developed at Carnegie and by other groups in the field are presenting unprecedented opportunities for scientists to make important advances in our understanding of the basic biology of organisms such as Chlamydomonas."
As an energy source to potentially replace fossil fuels, hydrogen would greatly reduce the emission of greenhouse gases. Proponents of algal-based hydrogen production point out that, unlike ethanol produced from crops, it would not compete with food production for agricultural land.
Carnegie Institution
Chlamydomonas Current Events and Chlamydomonas News RSSSynchronized swimming of algae
Using high-speed cinematography, scientists at Cambridge University have discovered that individual algal cells can regulate the beating of their flagella in and out of synchrony in a manner that controls their swimming trajectories.
Discovery about fertilization points way to possible malaria vaccine
International investigations of an organism that one UT Southwestern Medical Center researcher calls a "silly little green scum" have led to key insights into the basic mechanisms of reproduction.
Green algae -- the nexus of plant/animal ancestry
Genes of a tiny, single-celled green alga called Chlamydomonas reinhardtii may contain scores more data about the common ancestry of plants and animals than the richest paleontological dig.
Green alga genome project catalogs carbon capture machinery
The genome analysis of a tiny green alga has uncovered hundreds of genes that are uniquely associated with carbon dioxide capture and generation of biomass.
Study involving more than 100 scientists provides new insights on green algae
Culminating a three-year research project, 115 scientists from around the world report in the Oct. 12 issue of the journal Science a "gold mine" of data on a tiny green alga called Chlamydomonas, with implications for human diseases.
Unicellular microRNA discovery
In the May 15th issue of Genes & Development, an international collaboration of researchers, led by Dr. Yijun Qi (National Institute of Biological Sciences, China), report on their discovery of microRNAs in the unicellular green alga, Chlamydomonas reinhardtii. This is the first finding of microRNAs in a unicellular organism.
Common algae helps illustrate mammalian brain electrical circuitry
Mice whose brain cells respond to a flash of light are providing insight into the complexities of the sense of smell and may ultimately yield a better understanding of how the human brain works.
Algae provide new clues to cancer
A microscopic green alga helped scientists at the Salk Institute for Biological Studies identify a novel function for the retinoblastoma protein (RB), which is known for its role as a tumor suppressor in mammalian cells.
'Cellular antennae' on algae give clues to how human cells receive signals
By studying microscopic hairs called cilia on algae, researchers at UT Southwestern Medical Center have found that an internal structure that helps build cilia is also responsible for a cell's response to external signals.
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The Chlamydomonas Sourcebook 3-Vol set, Volume 1-3, Second Edition by David Stern (Editor), George Witman (Editor), Elizabeth H. Harris (Editor) Chlamydomonas reinhardtii (C. reinhardtii) is a unicellular green alga whose simple life cycle and ease of growth and manipulation for genetic analysis have made it a popular organism for research in diverse areas of cell biology and genetics. C. reinhardtii is important to a variety o research from studies of flagellar biogenesis and function that are highly relevant to medical research on sperm motility and ciliary function to work on chloroplast biogenesis and photosynthesis with critical importance for agriculture. In recent years it has also proved to be an outstanding model for investigation of signal transduction, rhodopsin-based vision, and the evolution of sexual processes. The Chlamydomonas Sourcebook, published in 1989 by Academic Press, summarized the development of... |
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The Chlamydomonas Sourcebook: Introduction to Chlamydomonas and Its Laboratory Use, Volume 1, Second Edition by Elizabeth H. Harris (Author) Dr. Harris has played a major role in the development of this organism as a model system. Her previous version of the Chlamydomonas Sourcebook which published in 1989 has been a classic in the field, and considered required reading for anyone working with this organism. This latest edition has been expanded to include three volumes providing molecular techniques, analysis of the recently sequenced genome, and reviews of the current status of the diverse fields in which Chlamydomonas is used as a model organism. Methods for chlamydomonas research and best practices for applications in research including methods for culture, preservation of cultures, preparation of media, lists of inhibitors and other additives to culture media are included. Additions to this volume also include help with... |
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The Chlamydomonas Sourcebook: Organellar and Metabolic Processes, Volume 2, Second Edition by David Stern (Editor) This second volume of The Chlamydomonas Sourcebook provides the background and techniques for using this important organism in plant research. From biogenesis of chloroplasts and mitochondria and photosynthesis to respiration and nitrogen assimilation, this volume introduces scientists to the functions of the organism. The volume then moves on to starch biosynthesis, sulfur metabolism, response to heavy metals, and hydrogen production. * Describes molecular techniques, analysis of the recently sequenced genome, and reviews of the current status of the diverse fields in which Chlamydomonas is used as a model organism * Includes contributions from leaders in particular areas of research * Provides methods for Chlamydomonas research and... |
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The Chlamydomonas Sourcebook: Cell Motility and Behavior, Volume 3, Second Edition by George Witman (Editor) Volume 3 reviews virtually everything that is known about cell motility and behavior in Chlamydomonas. World experts in each area focus on mitosis and cytokinesis; flagellar assembly and motility; intraflagellar transport; dynein; the structure and function of centrioles/basal bodies and their associated structures; ciliary signaling; mating and gamete fusion; photobehaviors; and Chlamydomonas as a model for understanding human diseases of the cilium. The volume is richly illustrated and is supplemented by a website containing both classic and previously unpublished videos of cell motility in Chlamydomonas. A unique and especially valuable feature is the inclusion of tables listing the known proteins (with NCBI accession numbers) for each structure discussed, and the known mutations... |
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Metal stoichiometry in predicting Cd and Cu toxicity to a freshwater green alga Chlamydomonas reinhardtii [An article from: Environmental Pollution] by W.X. Wang (Author), R.C.H. Dei (Author) This digital document is a journal article from Environmental Pollution, published by Elsevier in 2006. 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: In this study, we quantified the accumulation and toxicity of cadmium and copper in a freshwater green alga, Chlamydomonas reinhardtii, under different phosphate conditions. The accumulated Cd and Cu concentrations increased significantly with increasing ambient P concentrations and free metal ion concentrations. The metal:P ratio remained independent of the ambient P concentration. For the three pulse-amplitude-modulated parameters, the median inhibition concentrations were 1.5-1.6x and 2.0x higher, but the... |
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16 original offprints or papers. Includes: SAGER & S. GRANICK. Nutritional Control of Sexuality in Chlamydomonas Teinhardi. Offprint from: The Journal of General Physiology, vol. 37, 6, July 20. by Ruth. SAGER (Author) | |
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Group of 16 papers. Includes: LEVINE, & W. T. EBERSOLD. The Relation of Calcium and Magnesium to Crossing Over in Chlamydomonas Reinhardi. Offprint from: Zeitschrift für Vererbungslehre, bd. 89, 1958. by Robert P. LEVINE (Author) | |
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