 |
|
Texas A&M researchers examine 'invading' bacteria in DNA
June 03, 2009Call it advanced warfare on the most elemental of levels.
Researchers at Texas A&M University's Artie McFerrin Department of Chemical Engineering have discovered how certain types of bacteria integrate the DNA that they have captured from invading enemies into their own genetic makeup to increase their chances of survival.
To be more accurate, the genetic material isn't really captured as much as it is simply utilized after it's injected into the bacteria by an invading virus, says Professor Thomas K. Wood, who along with colleagues Xiaoxue Wang and Younghoon Kim has published the findings in Nature's 2009 International Society for Microbial Ecology Journal.
Wood's findings shed light on a millions-of-years-old battle between bacteria and bacteria-eating viruses known as "phages." Locked in an epic struggle, the two life forms, Woods explains, are constantly developing new ways to win the war. One such approach undertaken by a phage is to attach to a bacterial cell and, using a syringe-like tail apparatus, inject its genetic material into the bacterial cell. Once inside, the phage replicates itself and eventually exits the cell to find new bacteria to infect.
But as is the case with men, the best-laid plans of phages can also go astray.
Examining E. coli bacteria, Wood found that the bacteria developed a means of not allowing the phage to replicate and leave the cell of its own volition. Once the phage was effectively "captured," the bacteria incorporated the phage's DNA material into its own chromosomes. This new diverse blend of genetic material, Wood says, has helped the bacteria not only overcome the phage but also flourish at a greater rate than similar bacteria that have not incorporated the phage DNA.
"The bacteria are alive and doing well, and in fact the bacteria are doing better because it captured its enemy," Wood said. "Our research shows that if these bacteria didn't have this particular set of 25 genes that belonged to the old phage it wouldn't be able to grow as fast. If you removed the phage remnant, the bacteria grows five times slower on some carbon sources."
This distinct advantage is helping scientists understand why bacteria carry about 10-20 percent of genes that aren't their own. Simply put, carrying the virus DNA allows bacteria to increase their chances of survival by producing diverse progeny - something Wood says is extremely important when the bacteria choose to move to a new environment through a process known as dispersal.
Dispersal occurs, Woods says, when the bacterium can no longer glean the nutrients it needs from its surroundings or when other environmental conditions, such as temperature, have become unfavorable. Wood found that through an elaborate regulation method, the bacteria are able to retain the virus DNA or expel it. It's an interesting trade off, as retaining the virus DNA helps the bacteria grow faster but reduces its motility, which is needed when seeking out new environments, Wood explains.
Further exploring this dynamic, Wood and his research group were able to link this regulation process to the formation of bacterial communities called biofilms.
A biofilm, Wood says, is a protective, adhesive slime created by bacteria that have joined together to form a community and reap the benefits of a "strength-in-numbers" approach. Biofilms can grow on a variety of living and nonliving surfaces, including submerged rocks, food, teeth (as plaque) and biomedical implants such as knee and hip replacements.
The National Institutes of Health estimate that about 90 percent of infections in humans are caused by biofilms, and the Centers for Disease Control estimate biofilm to be present in 65 percent of hospital-acquired (nosocomial) infections. Biofilms typically are the cause of fatal infections that develop post surgery. More commonly, they are the source of persistent ear infections among children.
In addition to finding that biofilm formation relies heavily on virus genes present within the bacteria, Wood's research has shown the mechanism for how this takes place. A protein within the bacterium called Hha has the ability to control whether virus genes are kept within the bacterium or jettisoned. When Hha is basically "turned on," the bacteria expel the virus genes, opting for motility over the ability to form biofilms. Likewise, when Hha is not expressed, the bacteria move slower but grow biofilms at a much faster rate, Wood explains.
It's a finding that could impact everything from health care to research into alternative fuel production.
"If we can understand how biofilms are formed, we can begin to manipulate forming them where we want and getting them to not form where we don't want them," Wood says. "We have found a regulator - this Hha - that controls the genes related to biofilm formation. Now we can begin to envision ways to turn on that Hha gene if we want to get rid of biofilms, and that is what we are working on. That's the long-term goal - as engineers to make biofilms where we want them.
"For example, if we want to remediate soil, we'd form a biofilm on the roots of plants, plant the tree, and wherever the tree root goes we clean the soil. That's a beneficial biofilm. If I want to make hydrogen with E. coli, I'll probably want to do it in a biofilm, so I would want to promote the growth of the biofilm.
"We're one of the first labs in the world that has begun to not only try to understand how biofilms form but to control them."
Texas A&M University
Wood's findings shed light on a millions-of-years-old battle between bacteria and bacteria-eating viruses known as "phages." Locked in an epic struggle, the two life forms, Woods explains, are constantly developing new ways to win the war. One such approach undertaken by a phage is to attach to a bacterial cell and, using a syringe-like tail apparatus, inject its genetic material into the bacterial cell. Once inside, the phage replicates itself and eventually exits the cell to find new bacteria to infect.
But as is the case with men, the best-laid plans of phages can also go astray.
Examining E. coli bacteria, Wood found that the bacteria developed a means of not allowing the phage to replicate and leave the cell of its own volition. Once the phage was effectively "captured," the bacteria incorporated the phage's DNA material into its own chromosomes. This new diverse blend of genetic material, Wood says, has helped the bacteria not only overcome the phage but also flourish at a greater rate than similar bacteria that have not incorporated the phage DNA.
"The bacteria are alive and doing well, and in fact the bacteria are doing better because it captured its enemy," Wood said. "Our research shows that if these bacteria didn't have this particular set of 25 genes that belonged to the old phage it wouldn't be able to grow as fast. If you removed the phage remnant, the bacteria grows five times slower on some carbon sources."
This distinct advantage is helping scientists understand why bacteria carry about 10-20 percent of genes that aren't their own. Simply put, carrying the virus DNA allows bacteria to increase their chances of survival by producing diverse progeny - something Wood says is extremely important when the bacteria choose to move to a new environment through a process known as dispersal.
Dispersal occurs, Woods says, when the bacterium can no longer glean the nutrients it needs from its surroundings or when other environmental conditions, such as temperature, have become unfavorable. Wood found that through an elaborate regulation method, the bacteria are able to retain the virus DNA or expel it. It's an interesting trade off, as retaining the virus DNA helps the bacteria grow faster but reduces its motility, which is needed when seeking out new environments, Wood explains.
Further exploring this dynamic, Wood and his research group were able to link this regulation process to the formation of bacterial communities called biofilms.
A biofilm, Wood says, is a protective, adhesive slime created by bacteria that have joined together to form a community and reap the benefits of a "strength-in-numbers" approach. Biofilms can grow on a variety of living and nonliving surfaces, including submerged rocks, food, teeth (as plaque) and biomedical implants such as knee and hip replacements.
The National Institutes of Health estimate that about 90 percent of infections in humans are caused by biofilms, and the Centers for Disease Control estimate biofilm to be present in 65 percent of hospital-acquired (nosocomial) infections. Biofilms typically are the cause of fatal infections that develop post surgery. More commonly, they are the source of persistent ear infections among children.
In addition to finding that biofilm formation relies heavily on virus genes present within the bacteria, Wood's research has shown the mechanism for how this takes place. A protein within the bacterium called Hha has the ability to control whether virus genes are kept within the bacterium or jettisoned. When Hha is basically "turned on," the bacteria expel the virus genes, opting for motility over the ability to form biofilms. Likewise, when Hha is not expressed, the bacteria move slower but grow biofilms at a much faster rate, Wood explains.
It's a finding that could impact everything from health care to research into alternative fuel production.
"If we can understand how biofilms are formed, we can begin to manipulate forming them where we want and getting them to not form where we don't want them," Wood says. "We have found a regulator - this Hha - that controls the genes related to biofilm formation. Now we can begin to envision ways to turn on that Hha gene if we want to get rid of biofilms, and that is what we are working on. That's the long-term goal - as engineers to make biofilms where we want them.
"For example, if we want to remediate soil, we'd form a biofilm on the roots of plants, plant the tree, and wherever the tree root goes we clean the soil. That's a beneficial biofilm. If I want to make hydrogen with E. coli, I'll probably want to do it in a biofilm, so I would want to promote the growth of the biofilm.
"We're one of the first labs in the world that has begun to not only try to understand how biofilms form but to control them."
Texas A&M University
Bacteria Current Events and Bacteria News RSSOn the Trail of a Vaccine for Lyme Disease: Yale Researchers Target Tick Saliva
A protein found in the saliva of ticks helps protect mice from developing Lyme disease, Yale researchers have discovered. The findings, published in the November 19 issue of Cell Host & Microbe, may spur development of a new vaccine against infection from Lyme disease, which is spread through tick bites.
Cigarettes Harbor Many Bacteria Harmful to Human Health
Cigarettes are "widely contaminated" with bacteria, including some known to cause disease in people, concludes a new international study conducted by a University of Maryland environmental health researcher and microbial ecologists at the Ecole Centrale de Lyon in France.
ORNL, Los Alamos pioneer new approach to assist scientists, farmers
Sustainable farming, initially adopted to preserve soil quality for future generations, may also play a role in maintaining a healthy climate, according to researchers at the Department of Energy's Oak Ridge and Los Alamos national laboratories.
UAB Researchers Discover Antibody Receptor Identity, Propose Renaming Immune-System Gene
Researchers at the University of Alabama at Birmingham (UAB) have uncovered the genetic identity of a cellular receptor for the immune system's first-response antibody, a discovery that sheds new light on infection control and immune disorders.
Scientists find molecular trigger that helps prevent aging and disease
Researchers at Mount Sinai School of Medicine set out to address a question that has been challenging scientists for years: How do dietary restriction-and the reverse, overconsumption-produce protective effects against aging and disease?
Texas A&M Researchers Examine How Viruses Destroy Bacteria
Viruses are well known for attacking humans and animals, but some viruses instead attack bacteria. Texas A&M University researchers are exploring how hungry viruses, armed with transformer-like weapons, attack bacteria, which may aid in the treatment of bacterial infections.
A Second Skin
Despite advances in treatment regimens and the best efforts of nurses and doctors, about 70% of all people with severe burns die from related infections.
Study reveals why certain drug combinations backfire
Combination drug therapy has become a staple for treating many infections. For instance, doctors treat extensively drug resistant forms of tuberculosis with one drug that breaks down the pathogen's protective barriers and opens the door for another to deliver the deathblow.
Simple test could offer cheap solution to detecting landmines
Scientists have developed a simple, cheap, accurate test to find undetected landmines.
New explanation for nature's hardiest life form
Got food poisoning? The cause might be bacterial spores, en extremely hardy survival form of bacteria, a nightmare for health care and the food industry and an enigma for scientists.
More Bacteria Current Events and Bacteria News Articles
 |
A Field Guide to Bacteria (Comstock Book) by Betsey Dexter Dyer (Author) Pocket-guide to observing bacteria without a laboratory or fancy equipment. Presents all the major taxonomic groups of bacteria in a useable, accessible format for amateur naturalists who may or may not have access to a microscope. Includes ideas for planning field trips to explore bacteria in their natural environments. Illustrated, some color. Softcover, hardcover available. |
 |
Ein-O Science BioSigns Bacteria by Tedco The hands on cell and microbiology models provide magnified and cross section details. The set includes Virus, Bacteria, Plant Cell, White Blood Cell, Red Blood Cell and Animal Cell. Ein-O's I Know Guides and storage box are included. Consider using these models with a display of your own making - featuring the intricacies of cell structure, comparing and contrasting differences, investigating functions & interactions, or describing the efforts of modern medicine... a neat Science Fair Project. Virus - This hands-on interactive model provides magnified and cross-sectioned detailing of a Virus. Animal Cell - This hands-on interactive model provides magnified and cross-sectioned detailing of an Animal Cell. White Blood Cell - This hands-on interactive model provides... |
 |
Bacteria (Discovery Channel School Science) by Lynn Brunelle (Author), Barbara Ravage (Author), Lynn Brunelle (Editor), Barbara Ravage (Editor), Gareth Stevens Publishing (Editor) |
 |
60 Minutes - Superbug (November 11, 2007) Airdate 11/11/07 MRSA is a superbug, a staff infection that has moved out of hospitals and nursing homes and is now infecting healthy people, sometimes killing them. That's because once the MRSA infection gets into the blood stream, it is largely resistant to antibiotics. For now, the best medicine is prevention. What does this mean? Scrubbing down school desks? Hosing down team locker rooms? Sending infected kids home? Lesley Stahl reports. This product is manufactured on demand using DVD-R recordable media. Amazon.com's standard return policy will apply. |
 |
Disposable EARLOOP Face MASK, Filters Bacteria 3 Ply - (Box of 50) by EVERREADY FIRST AID Tie-on surgical face mask with high bacterial filtration efficiency (BFE), low breathing resistance, soft, odorless, non-irritating, comfortable superior fit, fiberglass free. |
 |
Essick Air #1970 Quart Bacteria Treatment by ESSICK AIR PRODUCTS QT, Humidifier Bacteria Treatment, Helps Fight Bacteria & Algae Build Up, Keeps Water Smelling Clean, EPA Registered, For Use In All Evaporative Console & Room Size Humidifiers. |
 |
Watersafe WS-359RC Pool & Spa Bacteria Water Test 10-pack by Watersafe A do-it-yourself Pool and Spa bacteria test strips. Revolutionary way to test your pool and spa for harmful bacteria in just 20 minutes. Contains 10 tests. Now there is a simple test that detects bacteria in swimming pools and spas in less than 20 minutes, with a simple procedure that requires no instrumentation or user training. This Bacteria Test has all the accuracy and reliability of a lab test, but in a disposable test strip. How to use Pool and Spa Bacteria Test: * Open box * Sample water * Read results - immediate visual readout, no instruments required Detection Range: * Pseudomonas, Aeromonas, E.coli, species of Salmonella, Shigella, Enterobacter, Klebsiella and many other Coliform and non-Coliform bacteria. * 10^3 cfu/ml |
 |
Good Germs, Bad Germs: Health and Survival in a Bacterial World by Jessica Snyder Sachs (Author) Making Peace with Microbes Public sanitation and antibiotic drugs have brought about historic increases in the human life span; they have also unintentionally produced new health crises by disrupting the intimate, age-old balance between humans and the microorganisms that inhabit our bodies and our environment. As a result, antibiotic resistance now ranks among the gravest medical problems of modern times. Good Germs, Bad Germs addresses not only this issue but also what has become known as the “hygiene hypothesis”— an argument that links the over-sanitation of modern life to now-epidemic increases in immune and other disorders. In telling the story of what went terribly wrong in our war on germs, Jessica Snyder Sachs explores our emerging understanding of the symbiotic... |
 |
Professioal Lab #BA110 Pro Bacteria/WTR Kit by PROFESSIONAL LAB INC Professional Bacteria & Water Test Kit, Easy To Use, Do It Yourself Test Identifies Dangerous Bacteria In 48 Hours, Offers 2 Types Of Analytical Methods, The First Method Simply Involves Counting The Number Of Colonies That Are Growing On The Petri Dish, The Second Method Optional Requires Sending The Petri Dish To Pro-Lab For A More Detailed Analysis Which Will Identify The Bacteria Present In Your Water, EPA Approved Lab Methods, Contains Petri Dish, Bacteria Medium, Calibrated Pipette/Dropper, Information Form. |
 |
SciEd Coliform Bacteria Test Kit; 25-50 Student-Kit by Kemtec Educational Corporation Kit, Coliform Bacteria Test Kit, Educational; Test water samples for animal waste contamination by observing the presence of waterborne E. coli; 25-50 Student-Kit |
| © 2009 BrightSurf.com |