 |
|
Researchers uncover molecule that keeps pathogens like salmonella in check
August 22, 2008Scientists at UT Southwestern Medical Center have found a potential new way to stop the bacteria that cause gastroenteritis, tularemia and severe diarrhea from making people sick.
The researchers found that the molecule LED209 interferes with the biochemical signals that cause bacteria in our bodies to release toxins.
"What we have here is a completely novel approach to combating illness," said Dr. Vanessa Sperandio, associate professor of microbiology and biochemistry at UT Southwestern and senior author of a study available online today and in a future issue of Science.
Though many antimicrobial drugs are already available, new ones are needed to combat the increasing microbial resistance to antibiotics. In addition, treating some bacterial infections with conventional antibiotics can cause the release of more toxins and may worsen disease outcome.
Scientists have known for decades that millions of potentially harmful bacteria exist in the human body, awaiting a signal that it's time to release their toxins. Without those signals, the bacteria pass through the digestive tract without infecting cells. What hasn't been identified is how to prevent the release of those toxins, a process that involves activating virulence genes in the bacteria.
In the new study, UT Southwestern researchers describe how LED209 blocks the bacterial receptor for these signals. In 2006, the UT Southwestern researchers were the first to identify the receptor QseC sensor kinase, which is found in the membrane of a diarrhea-causing strain of Escherichia coli. This receptor receives signals from human flora and hormones in the intestine that cause the bacteria to initiate infection.
In studies in vitro, Dr. Sperandio and her colleagues found that LED209 blocked the QseC sensors in E coli, Salmonella and Francisella tularensis bacteria, preventing them from expressing virulence traits. Using mice models of infection, the researchers also showed that LED209 blocks pathogenesis of Salmonella and F tularensis, preventing them from causing disease in these animals.
Though the researchers limited the study to three pathogens, they believe drugs that target QseC could have a broader spectrum because the sensor exists in at least 25 important animal and plant pathogens including Erwinia, which causes plant rot; Legionella pneumophila, which causes Legionnaires' disease; and Haemophilus influenzae, which causes lung infections.
Unlike conventional antibiotics, which work by killing bacteria, LED209 allows the pathogen to grow but not become virulent and make the host sick. Dr. Sperandio said killing the bacteria or inhibiting their growth just "angers" some bacteria and causes them to release toxins.
"The sensors in bacteria are waiting for the right signal to initiate the expression of virulent genes," she said. "Using LED209, we blocked those sensing mechanisms and basically tricked the bacteria to not recognize that they were within the host. When we did that, the bacterial pathogens could not effectively cause disease in the treated animals."
Allowing the pathogen to survive also makes it less likely to develop resistance to medical treatments.
"What makes this current study unique is that we showed the drug working in three different pathogens," Dr. Sperandio said. "Prior studies generally focused on one."
In early 2008, UT Southwestern received a five-year, $6.5 million grant from the National Institute of Allergy and Infectious Diseases to develop a new antimicrobial compound to target bacterial pathogens such as Salmonella, E coli and F tularensis. Dr. Sperandio is the principal investigator.
"Only a few new antibiotics have reached the market in recent years," Dr. Sperandio said. "Because LED209 has never been used as an antibiotic, it's a completely different type of drug. In addition, its target, QseC, is also different from the current antimicrobial drug targets. This study demonstrates that LED209 has promise in fighting at least three pathogens and likely many more."
Identifying LED209 was accomplished by using a high throughput screen of 150,000 compounds in UT Southwestern's Small Molecular Library. The screening process was set up to find molecules that wouldn't activate the virulence genes in a strain of E coli known as enterohemorrhagic E coli 0157:H7, or EHEC. Additional rounds of screening resulted in a pool of 75 potential inhibitors, from which LED209 was selected partly because of its potency.
The team's next step is to understand further LED209's structure and how it functions. The researchers plan to modify the drug to develop customized formulations.
"What we have right now works really well for systemic infections and it's very potent, but we also need non-absorbable molecules to treat noninvasive pathogens such as EHEC, which stays in the intestine," Dr. Sperandio said.
Other UT Southwestern researchers involved in this research were Dr. Noelle Williams, assistant professor of biochemistry; Dr. Ron Taussig, associate professor of pharmacology; Dr. Michael Roth, professor of biochemistry; Dr. John R. Falck, professor of biochemistry and pharmacology; Drs. Cristiano Moreira and Jason Huntley, both postdoctoral researchers in microbiology; Dr. Run Li, postdoctoral research in biochemistry; Dr. Shuguang Wei, senior research scientist in biochemistry; Maggy Fina, senior research associate in pharmacology; and student research assistants Nicola Reading and David Hughes. Dr. David Rasko, former assistant professor of microbiology at UT Southwestern, was the lead author. Drs. Matthew Waldor and Jennifer Ritchie from Brigham and Women's Hospital also participated.
The work was funded by the National Institutes of Health, the Ellison Medical Foundation, Burroughs Wellcome Fund, the Welch Foundation and UT Southwestern's High Impact/High Risk Research Program. UT Southwestern has filed a U.S. patent application on this technology.
The University of Texas Southwestern Medical Center at Dallas
Though many antimicrobial drugs are already available, new ones are needed to combat the increasing microbial resistance to antibiotics. In addition, treating some bacterial infections with conventional antibiotics can cause the release of more toxins and may worsen disease outcome.
Scientists have known for decades that millions of potentially harmful bacteria exist in the human body, awaiting a signal that it's time to release their toxins. Without those signals, the bacteria pass through the digestive tract without infecting cells. What hasn't been identified is how to prevent the release of those toxins, a process that involves activating virulence genes in the bacteria.
In the new study, UT Southwestern researchers describe how LED209 blocks the bacterial receptor for these signals. In 2006, the UT Southwestern researchers were the first to identify the receptor QseC sensor kinase, which is found in the membrane of a diarrhea-causing strain of Escherichia coli. This receptor receives signals from human flora and hormones in the intestine that cause the bacteria to initiate infection.
In studies in vitro, Dr. Sperandio and her colleagues found that LED209 blocked the QseC sensors in E coli, Salmonella and Francisella tularensis bacteria, preventing them from expressing virulence traits. Using mice models of infection, the researchers also showed that LED209 blocks pathogenesis of Salmonella and F tularensis, preventing them from causing disease in these animals.
Though the researchers limited the study to three pathogens, they believe drugs that target QseC could have a broader spectrum because the sensor exists in at least 25 important animal and plant pathogens including Erwinia, which causes plant rot; Legionella pneumophila, which causes Legionnaires' disease; and Haemophilus influenzae, which causes lung infections.
Unlike conventional antibiotics, which work by killing bacteria, LED209 allows the pathogen to grow but not become virulent and make the host sick. Dr. Sperandio said killing the bacteria or inhibiting their growth just "angers" some bacteria and causes them to release toxins.
"The sensors in bacteria are waiting for the right signal to initiate the expression of virulent genes," she said. "Using LED209, we blocked those sensing mechanisms and basically tricked the bacteria to not recognize that they were within the host. When we did that, the bacterial pathogens could not effectively cause disease in the treated animals."
Allowing the pathogen to survive also makes it less likely to develop resistance to medical treatments.
"What makes this current study unique is that we showed the drug working in three different pathogens," Dr. Sperandio said. "Prior studies generally focused on one."
In early 2008, UT Southwestern received a five-year, $6.5 million grant from the National Institute of Allergy and Infectious Diseases to develop a new antimicrobial compound to target bacterial pathogens such as Salmonella, E coli and F tularensis. Dr. Sperandio is the principal investigator.
"Only a few new antibiotics have reached the market in recent years," Dr. Sperandio said. "Because LED209 has never been used as an antibiotic, it's a completely different type of drug. In addition, its target, QseC, is also different from the current antimicrobial drug targets. This study demonstrates that LED209 has promise in fighting at least three pathogens and likely many more."
Identifying LED209 was accomplished by using a high throughput screen of 150,000 compounds in UT Southwestern's Small Molecular Library. The screening process was set up to find molecules that wouldn't activate the virulence genes in a strain of E coli known as enterohemorrhagic E coli 0157:H7, or EHEC. Additional rounds of screening resulted in a pool of 75 potential inhibitors, from which LED209 was selected partly because of its potency.
The team's next step is to understand further LED209's structure and how it functions. The researchers plan to modify the drug to develop customized formulations.
"What we have right now works really well for systemic infections and it's very potent, but we also need non-absorbable molecules to treat noninvasive pathogens such as EHEC, which stays in the intestine," Dr. Sperandio said.
Other UT Southwestern researchers involved in this research were Dr. Noelle Williams, assistant professor of biochemistry; Dr. Ron Taussig, associate professor of pharmacology; Dr. Michael Roth, professor of biochemistry; Dr. John R. Falck, professor of biochemistry and pharmacology; Drs. Cristiano Moreira and Jason Huntley, both postdoctoral researchers in microbiology; Dr. Run Li, postdoctoral research in biochemistry; Dr. Shuguang Wei, senior research scientist in biochemistry; Maggy Fina, senior research associate in pharmacology; and student research assistants Nicola Reading and David Hughes. Dr. David Rasko, former assistant professor of microbiology at UT Southwestern, was the lead author. Drs. Matthew Waldor and Jennifer Ritchie from Brigham and Women's Hospital also participated.
The work was funded by the National Institutes of Health, the Ellison Medical Foundation, Burroughs Wellcome Fund, the Welch Foundation and UT Southwestern's High Impact/High Risk Research Program. UT Southwestern has filed a U.S. patent application on this technology.
The University of Texas Southwestern Medical Center at Dallas
Salmonella Current Events and Salmonella News RSSExploring the final frontier: Disease proposed as major barrier to Mars and beyond
New research published in the Journal of Leukocyte Biology suggests that prolific virulence and growth of bacteria, coupled with reduced production of antibodies could limit future space travel.
Propolis has proved to be a product with ability to have beneficial effects for health
Growing concerns about health has caused the scientific community to focus their interest on investigating functional foods which contribute to boosting the prevention and reduction of the risk of suffering from certain illnesses.
TraDIS technique tackles typhoid
For the first time, researchers are able to look at the need for every gene in a bacterial cell in a single experiment. The new method will transform the study of gene activity and the search for weaknesses in bacterial armouries.
Light, photosynthesis help bacteria invade fresh produce
Exposure to light and possibly photosynthesis itself could be helping disease-causing bacteria to be internalized by lettuce leaves, making them impervious to washing, according to research published in the October issue of the journal Applied and Environmental Microbiology.
How Good Are Indicator Bacteria at Predicting Pathogens in Recreational Water?
Bacteria commonly used to indicate health risks in recreational waters might not be so reliable after all. Pathogenic E. coli were pervasive in stream-water samples with low concentrations of fecal indicator bacteria.
New biosensor can detect bacteria instantaneously
A research group from the Rovira i Virgili University (URV) in Tarragona has developed a biosensor that can immediately detect very low levels of Salmonella typhi, the bacteria that causes typhoid fever.
Casting out devils
In the scientific journal PLoS ONE, Sara Bartels and Siegfried Weiss of the Helmholtz Centre for Infection Research (HZI) in Braunschweig, Germany now show how the bacteria migrate into tumours.
Eating less red meat can prevent cancer, heart attacks and global warming
Raising livestock also accounts for around 18% of greenhouse gases. It is therefore possible to act against climate change and reduce cardiovascular and cancer deaths, by cutting the production and consumption of 'red meat' from these animals.
Typhoid fever cases in US linked to foreign travel
Infection with an antimicrobial-resistant strain of typhoid fever among patients in the United States is associated with international travel, especially to the Indian subcontinent (India, Pakistan, and Bangladesh).
'Killer spices' provide eco-friendly pesticides for organic fruits and veggies
Mention rosemary, thyme, clove, and mint and most people think of a delicious meal. Think bigger-acres bigger.
More Salmonella Current Events and Salmonella News Articles
 |
Salmonella (Deadly Diseases and Epidemics) by Danielle A. Brands (Author), I. Edward Alcamo (Author) |
 |
Salmonella Ailmentaries Plush by Giant Microbes Salmonella (Salmonella typhimurium) - Which came first: the chicken, or the egg -- or the Salmonella bacteria? The bane of every household cook, Salmonella is taking a break from making our chicken dinners scary to instead be cute and cuddly. Now you can collect a dozen of the most adorable viruses, bacteria, mites, worms and calamities nature ever unleashed. Disturbingly cuddly, Giant Microbes are great learning tools for parents and educators, amusing gifts for anyone with a sense of humor, or just friendly plush companions for those trying to get past their Bacillophobia. Each 5-to-7 inch doll is accompanied by an image of the not-so-cute real microbe it represents, as well as quick facts about the microbe. Antibiotics not required. |
 |
Salmonella: Molecular Biology and Pathogenesis by Mikael Rhen (Author) The recent completion of the genome sequences of several Salmonella serovars, allied with the application of whole genome analyses, and the availability of meaningful infection models in target animal species have contributed greatly to recent progress in the understanding of the molecular genomics and cellular biology of this family of complex pathogens. In this book internationally acclaimed experts review cutting-edge topics in Salmonella research. Chapters are written from a molecular perspective and provide a unique insight into the current status of Salmonella research. Topics include epidemiology, molecular typing, antibiotic resistance, host-interaction in the gut, adhesins, pathogenecity islands, virulence plasmids, gene regulation, biofilms, and... |
|
Drifting by Salmonella Dub | |
 |
Salmonella (Stefan Tretau Remix) Gabriel Ferreira (Primary Contributor) |
 |
Salmonella: A Practical Approach to the Organism and its Control in Foods (Practical Food Microbiology) by Chris Bell (Author), Alec Kyriakides (Author) Gives practical and accurate information about specific organisms of concern to public health. The information is designed for use by those in the food industry working in manufacturing, retailing and quality assurance, and those in associated professional sectors. Softcover. |
|
BD BBL Dehydrated Culture Media: SS Agar (Salmonella Shigella); 2kg, by BD Diagnostic Systems, Clinical Media; Microbiology; Dehydrated; BD; SS Agar (Salmonella Shigella); Difco; 2kg | |
 |
Crystal Quest Triple 8 Stage Ceramic Countertop Water Filter. (Filters 10,000 gal) Removes bacteria such as E. Coli , Salmonella and more by Crystal Quest W11C-PLUS Triple Countertop Ceramic Water Filter Triple Ceramic Countertop Water Filter is dependable and built to last for years. This counter top system installs in seconds and sits on the counter top for water on demand. Quick and easy to use, stylish, convenient, and effectively removes harmful bacteria and hundreds of contaminants from water. Water travels through 8 stages of filtration. First, through a solid carbon cartridge for removing volatile organic carbon compounds. Next through a 6-stage cartridge Provides 10,000 gallons A diverter valve switches between filtered & unfiltered water. Adjustable spout for more convenience. |
|
eFoodAlert by Phyllis Entis Daily news and commentary on food safety issues around the world.Kindle blogs are fully downloaded onto your Kindle so you can read them even when you're not wirelessly connected. And unlike RSS readers which often only provide headlines, blogs on Kindle give you full text content and images, and are updated wirelessly throughout the day. | |
 |
Violight VIO200 Travel Toothbrush Sanitizer by Violight The VIOlight travel offers the consumer the same benefits of sanitization as the original VIOlight but in the convenience of a travel sized version. Many travellers are exposed to a higher risk of contamination of their toothbrush due to leaving it on a hotel sink or uprotected in a dopp kit. The UV germicidal light bulb kills up to 99.9% of the bacteria, such as E.Coli, salmonella, and other harmful microorganisms. Researchers have found more than 10,000,000 bacteria can be living on a single toothbrush. Bacteria, molds, and fungi love moist environments which are commonly found in most plastic travel toothbrush holders. The ADA and most dentists recommend changing toothbrushes only every 3 to 4 months; however it is important to sanitize your toothbrush every day. |
| © 2009 BrightSurf.com |