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Gene that governs toxin production in deadly mold found
April 13, 2007MADISON-For the growing number of people with diminished immune systems-cancer patients, transplant recipients, those with HIV/AIDS-infection by a ubiquitous mold known as Aspergillus fumigatus can be a death sentence.
The fungus, which is found in the soil, on plant debris and indoor air, is easily managed by the healthy immune system. But as medical advances contribute to a growing population of people whose immune systems are weakened by disease or treatment, the opportunistic fungus poses a serious risk.
Now, however, scientists may have found a master switch, an über gene, that seems to control the mold's ability to make poison. The new finding was reported today (April 12) in the journal Public Library of Science Pathogens by a team led by Nancy P. Keller, a biologist from the University of Wisconsin-Madison.
"There is a growing problem with medical fungi in the United States," says Keller, a UW-Madison professor of plant pathology and medical microbiology. "Aspergillus fumigatus is among the most important."
Like many fungi, Aspergillus fumigatus makes a variety of poisons, presumably to give the microbe a competitive advantage in the environments it inhabits. In humans with suppressed immune systems, the mold can cause a number of diseases with mortality rates of 60 percent or more.
"The infection can be treated, but not easily," Keller explains. "Once an immunocompromised individual gets any fungal disease, it's pretty hard to treat, and the treatments themselves are often toxic. There is a 60-90 percent mortality rate with invasive aspergillosis."
Thus, knowing how the fungus makes its chemical arsenal is important and opens an avenue to devising novel treatments that can disarm the pathogen before it does its dirty work.
In fungi, there are typically many genes at work making toxins and other chemical metabolites. The genes tend to be clustered in groups on the organism's genome. In Aspergillus fumigatus, there are as many as 22 such gene groupings.
How those posses of genes are triggered and governed, however, has been a mystery. But now Keller's group has found that a key gene known as LaeA controls at least half of those toxin-producing gene clusters, suggesting there may be a way to modulate the virulence of the deadly microbe.
"We now have a very good idea that (the gene) is central to the toxic nature of the fungus," Keller says.
The LaeA gene, she believes, is like a maestro, directing the mold's toxin-producing genes in an orchestrated chorus that, in the right host, can be fatal.
Knowing this, Keller explains, "suggests that if you can find a way to regulate the activity of LeaA you might have a novel target" for new therapies to treat Aspergillus fumigatus infection.
"The gene is not expressed all the time, which means there must be a signal that says 'turn me on.'"
Removing the gene from the equation, she says, may cripple the microbe's ability to infect and sicken people.
"The loss of LaeA results in a great decrease in the repertoire of secondary metabolites, which appears to impact the infection process," making the gene an ideal prospect for new ways to fight infection.
University of Wisconsin-Madison
"There is a growing problem with medical fungi in the United States," says Keller, a UW-Madison professor of plant pathology and medical microbiology. "Aspergillus fumigatus is among the most important."
Like many fungi, Aspergillus fumigatus makes a variety of poisons, presumably to give the microbe a competitive advantage in the environments it inhabits. In humans with suppressed immune systems, the mold can cause a number of diseases with mortality rates of 60 percent or more.
"The infection can be treated, but not easily," Keller explains. "Once an immunocompromised individual gets any fungal disease, it's pretty hard to treat, and the treatments themselves are often toxic. There is a 60-90 percent mortality rate with invasive aspergillosis."
Thus, knowing how the fungus makes its chemical arsenal is important and opens an avenue to devising novel treatments that can disarm the pathogen before it does its dirty work.
In fungi, there are typically many genes at work making toxins and other chemical metabolites. The genes tend to be clustered in groups on the organism's genome. In Aspergillus fumigatus, there are as many as 22 such gene groupings.
How those posses of genes are triggered and governed, however, has been a mystery. But now Keller's group has found that a key gene known as LaeA controls at least half of those toxin-producing gene clusters, suggesting there may be a way to modulate the virulence of the deadly microbe.
"We now have a very good idea that (the gene) is central to the toxic nature of the fungus," Keller says.
The LaeA gene, she believes, is like a maestro, directing the mold's toxin-producing genes in an orchestrated chorus that, in the right host, can be fatal.
Knowing this, Keller explains, "suggests that if you can find a way to regulate the activity of LeaA you might have a novel target" for new therapies to treat Aspergillus fumigatus infection.
"The gene is not expressed all the time, which means there must be a signal that says 'turn me on.'"
Removing the gene from the equation, she says, may cripple the microbe's ability to infect and sicken people.
"The loss of LaeA results in a great decrease in the repertoire of secondary metabolites, which appears to impact the infection process," making the gene an ideal prospect for new ways to fight infection.
University of Wisconsin-Madison
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The Hsp90-Antifungal Combo, please: Compromising fungi in the immunocompromised
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Anti-fungal drug offers great benefits to some with severe asthma
Some patients with severe asthma who also have allergic sensitivity to certain fungi enjoy great improvements in their quality of life and on other measures after taking an antifungal drug, according to new research from The University of Manchester in England.
Montana State University researchers find gene that regulates mold's resistance to drugs
Montana State University scientists concerned about lethal mold infections have found a gene that regulates the mold's resistance to drugs.
Predicting the risk of a common fungal infection after stem cell transplantation
In silico genetic analysis in mice has led to the discovery of a gene affecting susceptibility to a severe fungal infection in transplant recipients.
Central nervous system infections rare but devastating following heart transplantation
Central nervous system infections develop infrequently following heart transplants but are a significant predictor of death, according to an article posted online today that will appear in the December 2007 print issue of Archives of Neurology.
Genome discovery will help combat disease and lead to new drugs
An international consortium of researchers led by the University of Manchester has cracked the gene code behind a key family of fungi, which includes both the leading cause of death in leukaemia and bone marrow transplant patients and an essential ingredient of soy sauce.
Bleach Found to Neutralize Mold Allergens
Researchers at National Jewish Medical and Research Center have demonstrated that dilute bleach not only kills common household mold, but may also neutralize the mold allergens that cause most mold-related health complaints.
A Grab for Iron - Breakthrough for Innsbruck Scientists
Nearly all organisms need iron to survive, even mould. For people with a weakened immune system such fungi pose a deadly threat. Scientists from Innsbruck (Austria) have now been able to genetically block the iron metabolism of Aspergillus fumigatus mould and thus render it harmless to humans. This discovery opens up completely new paths for developing drugs against fungal infections.
Kent scientists to tackle potentially lethal fungal infections
Scientists at the University of Kent have been awarded a major grant to help in the fight against fungal infections which can be potentially lethal for people whose immune systems are compromised, such those with HIV/AIDS. The £180,000 grant from the Biotechnology and Biological Sciences Research Council (BBSRC) will enable Dr. Fritz Mühlschlegel and Professor Mick Tuite of the University's Department of Biosciences to develop a greater understanding of what actually makes fungi cause disease. With the increase in the number of immuno-compromised patients, there has consequently been a continuous rise in the number of reported cases of such severe fungal infections. The two most
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