RxPG News Feed for RxPG News

Medical Research Health Special Topics World
  Home
 
   Health
 Aging
 Asian Health
 Events
 Fitness
 Food & Nutrition
 Happiness
 Men's Health
 Mental Health
 Occupational Health
 Parenting
 Public Health
 Sleep Hygiene
 Women's Health
 
   Healthcare
 Africa
 Australia
 Canada Healthcare
 China Healthcare
 India Healthcare
 New Zealand
 South Africa
 UK
 USA
 World Healthcare
 
   Latest Research
 Aging
 Alternative Medicine
 Anaethesia
 Biochemistry
 Biotechnology
 Cancer
 Cardiology
 Clinical Trials
 Cytology
 Dental
 Dermatology
 Embryology
 Endocrinology
 ENT
 Environment
 Epidemiology
 Gastroenterology
 Genetics
 Gynaecology
 Haematology
 Immunology
 Infectious Diseases
 Medicine
 Metabolism
 Microbiology
 Musculoskeletal
 Nephrology
 Neurosciences
 Obstetrics
 Ophthalmology
 Orthopedics
 Paediatrics
 Pathology
 Pharmacology
  Adrenergics
  Analgesics
  Anti Cancer Drugs
  Anti-Clotting Drugs
  Anti-Inflammatory
  Antibiotics
   Sirolimus
   Tigecycline
  Anticholesterol
  Antihypertensives
  Antivirals
  Fatty Acids
  Hypnotics
  Metals
  PPI
  Surfactants
  Varenicline
 Physiology
 Physiotherapy
 Psychiatry
 Radiology
 Rheumatology
 Sports Medicine
 Surgery
 Toxicology
 Urology
 
   Medical News
 Awards & Prizes
 Epidemics
 Launch
 Opinion
 Professionals
 
   Special Topics
 Ethics
 Euthanasia
 Evolution
 Feature
 Odd Medical News
 Climate

Last Updated: Oct 11, 2012 - 10:22:56 PM
Antibiotics Channel

subscribe to Antibiotics newsletter
Latest Research : Pharmacology : Antibiotics

   EMAIL   |   PRINT
Study of antibiotic resistance in the soil help predict future clinical emergence

Jan 20, 2006 - 3:40:00 PM , Reviewed by: Priya Saxena
"By evolving in an environment of antibiotic production, incredibly resilient bacteria must develop diverse ways to survive or resist the toxic antimicrobial compounds produced by their neighbors. Their coping tactics may be able to give us a glimpse into the future of clinical resistance to antibiotics."

 
[RxPG] Dirt may be a key to how bacteria that infect humans develop a resistance to antibiotic drugs.

In an article in the January 20 issue of the journal Science, McMaster University researchers say that study of bacteria found in dirt may be the key in identifying how and why antibiotic resistance happens in bacteria that infect people, predicting future clinical problems, and testing new antibiotics.

Antibiotic resistance has become an increasing public health concern because the organisms that cause infections in humans and animals are becoming less receptive to the healing aspect of antibiotic drugs.

The team led by professor Gerry Wright, chair of Biochemistry and Biomedical Sciences of the Michael G. DeGroote School of Medicine, found that the numerous ways soil-dwelling bacteria become resistant to antibiotics are identical to the resistance patterns seen in patients.

These soil-dwelling bacteria also play a central role in the treatment of infectious diseases. Approximately two-thirds of all known antibiotics are produced by bacteria called actinomycetes, commonly found in soils, compost, and other environmental sources.

"By evolving in an environment of antibiotic production, incredibly resilient bacteria must develop diverse ways to survive or resist the toxic antimicrobial compounds produced by their neighbors," said Wright. "Their coping tactics may be able to give us a glimpse into the future of clinical resistance to antibiotics."

"This research suggests that not only can the study of resistance in the soil help predict future clinical emergence, but it can also guide the development of therapies to counteract this resistance."

Researchers screened 480 strains of soil bacteria isolated from diverse locations for resistance to 21 clinically relevant antibiotics. At high drug concentrations, the soil-dwelling bacteria displayed a stunning level of resistance. Not only were the bacteria resistant to an average of seven to eight antibiotics, but every strain was found to be multi-drug resistant.

The bacteria showed resistance to all major classes of antibiotics, regardless of whether the compounds were naturally produced, semi-synthetic, or completely synthetic.

Researchers also found that the way bacteria was resistant to vancomycin, one of the most commonly prescribed antibiotics for drug resistant staphylococcal infections, was identical to resistance found in clinics.

Furthermore, the researchers' uncovered bacteria that produced enzymes capable of breaking down or modifying or rendering inactive two recently U.S. FDA-approved antibiotics, a situation which has yet to emerge clinically for these drugs.

"The link between clinical and soil-associated resistance to vancomycin illustrates the value of studying resistance in the soil to rationally anticipate future clinical resistance," said Wright. "It suggests that the soil serves as an under-recognized source of resistance, resistance that has the potential to reach clinics.

"This work could prove to be extremely valuable to the drug development process, complementing traditional laboratory studies of clinical situations. By screening newly developed drugs for resistance in soil bacteria, not only can pharmaceutical companies can gain a better understanding of what may emerge in the future as clinical problems, but sufficient warning can be given to hospital microbiology laboratories, physicians and the drug discovery sector to allow for the development of diagnostic techniques and alternative therapies.
Study of antibiotic resistance in the soil help predict future clinical emergence
Sporulating soil isolates. Top Left: Soil Isolate PP#15, inactivates daptomycin Top Right: Soil Isolate Cu#22 Bottom Left: Soil Isolate WMB#19 Bottom Right: Trimethoprim Resistant Soil Isolates


"Furthermore, studying enzymes that inactivate antibiotics can serve as a foundation for the development of new combination therapies for resistant bacterial strains. Studying antibiotic resistance from an evolutionary perspective is one way that researchers are attempting to stay one step ahead of resistant bacteria."

Antibiotic resistant bacteria have become a major health threat and have limited our ability to treat even common infections with antibiotics," said Dr. Bhagirath Singh, Scientific Director of the Canadian Institutes of Health Research Institute of Infection and Immunity. "Dr. Wright's exciting discovery points to the fact that in nature, bugs in the soil survive in a very hostile environment. They do this by developing resistance to the antibiotics produced by other soil bacteria. Understanding this process opens up a new avenue for finding new therapies to prevent and treat antibiotic resistance in a clinical setting.



Publication: January 20 issue of the journal Science
On the web: www.mcmaster.ca 

Advertise in this space for $10 per month. Contact us today.


Related Antibiotics News
Nanostructures lend cutting edge to antibiotics
Inhibition of protein HipA pevents cell dormancy and bacterial persistence
Study on spread of antibiotic resistance between bacteria
Two-component lantibiotic with therapeutic potential discovered
Antibiotic inhibits cancer gene activity
Rapamycin shown to inhibit angiogenesis
Tigecycline, world’s first glycylcycline expanded broad-spectrum antibiotic, launched in UK
FDA Warns of Liver Failure With Telithromycin
What is the optimal duration of antibiotic therapy?
Should children with suspected meningitis be given antibiotics before transfer to hospital?

Subscribe to Antibiotics Newsletter

Enter your email address:


 Additional information about the news article
This research was funded by the Canadian Institutes of Health Research and by a Canadian Research Chair.
 Feedback
For any corrections of factual information, to contact the editors or to send any medical news or health news press releases, use feedback form

Top of Page

 
Contact us

RxPG Online

Nerve

 

    Full Text RSS

© All rights reserved by RxPG Medical Solutions Private Limited (India)