|
|
| Author: Aaron Hall |
First discovered almost 20 years ago by Carl Woese and Ralph S. Wolfe (both of University of Illinois, Urbana), the Archaea domain (whose name means "ancient" in Greek) is believed to have separated from true bacteria over 3 billion years ago. Archaea once were thought to live only at extreme environmental conditions of temperature and pressure but now are believed to be far more common and to make up a significant part perhaps half of the world's biomass. They are suspected of playing important but still unknown roles in the earth's ecology, including its carbon and nitrogen cycles.
The single-celled, 1738-gene M. jannaschii was isolated from a sample collected in over 8000 feet of water at the base of a deep-sea thermal vent on the floor of the Pacific Ocean. It is named for Holger Jannasch of the Marine Biological Laboratory in Woods Hole, Massachusetts, who collected the sample. Thriving at pressures that would crush a conventional submarine, this heat-loving, methane-producing microbe lives without sunlight, oxygen, or organic carbon.
Instead, it uses carbon dioxide, nitrogen, and hydrogen expelled from the thermal vent for its life functions. Analysis of the microbe's genome will provide researchers with valuable information for understanding how organisms can make life's building blocks from inorganic sources and under such extreme conditions.
Practical Payoffs
With its unusual characteristics, M. jannaschii has the potential to supply fuel and other ingredients for products from plastics to pharmaceuticals. Commercial interests now have the opportunity to develop such heat-resistant products as detergent additives or stable enzymes for the textile, paper, and chemical industries. Methane (CH4) causes both ozone production and depletion but with a net production of ozone. This mean that more knowledge about bacterial/archaeal methane production could lead to better understanding of global-warming processes.
Some of the following areas may benefit from M. jannaschii applications.
* Transportation: Develop "biological" vehicles.
* Energy: Generate large supplies of safe, renewable power.
* Weather: Understand and control methane's contribution to global warming.
* Environmental cleanup: Use biological methods to clean up hazardous waste sites.
* Household use: Manufacture biodegradable detergents and cleaners. |
Author Bio:
|
| You can also reach this article by using: Archaic Overachiever Thrives in Hostile Environments, Academics & Education, Science Programs |
|
|
|
|
| |
|
In July, St. Louis schools?? Superintendent Creg Williams abruptly resigned. Since then, many member ... - Patricia Hawke |
| |
|
Like many other school districts in large, metropolitan cities, New York City Schools currently have ... - Patricia Hawke |
| |
|
Several of these great strategies were given to us by participants in our Breakthrough Strategies to ... - Ruth Wells, M.S. |
| |
|
|
| |
|
There has always been a lot of debate as to whether an online college education is as good as a trad ... - Steve Gargin |
| |
|
More than 50 complete microbial genome sequences have been deciphered since the publication of the f ... - Aaron Hall |
| |
|
The Low Dose Radiation Research Program supports basic research to help characterize risk from expos ... - Aaron Hall |
| |
|
Campus Men discusses A&F models as the new icon of youth culture and how college athletes seek t ... - Vicky Phipps |
| |
|
Compensation Resources, Inc. has released the results of its 2003-2004 College Graduate Salary Surve ... - Paul Dorf |
| |
|
| |
|
|
