News Release

UC researcher peeks at sex life of Pneumocystis pneumonia pathogen

Grant and Award Announcement

University of Cincinnati

Melanie Cushion, University of Cincinnati

image: Melanie Cushion, PhD, is shown in the University of Cincinnati College of Medicine. view more 

Credit: Colleen Kelley/UC Creative Services

CINCINNATI--"Let's Talk About Sex."

That catchy playful hip-hop tune from artists Salt-N-Pepa tackled a serious subject and ruled 90s radio for a decade. That earworm also stays on the mind of one University of Cincinnati (UC) College of Medicine researcher who is trying to find a better treatment for pneumocystis pneumonia.

It turns out the yeast-like fungus and human pathogen needs sex to thrive.

When the pathogen revs up it attacks the lungs, multiplies and can be transmitted to other hosts through a cough. Pneumocystis pneumonia plays havoc on the fragile immune systems of patients living with HIV, individuals undergoing cancer treatment or those receiving an organ transplant, says Melanie Cushion, PhD, senior associate dean for research in the UC College of Medicine.

Cushion has snagged a $1.9 million four-year grant from the National Heart, Lung and Blood Institute (1R01HL146266-01) to figure out how to stop the fungi that cause pneumocystis pneumonia from reproducing. She will be testing whether anti-fungal agents known as echinocandins could be used as part of a therapy to block the formation of asci, a life cycle stage that results from sexual replication and is needed for transmission of the pathogen to a new host.

Her research aligns with UC President Neville Pinto's innovation agenda, one of the platforms of the university's strategic direction, Next Lives Here.

"We have found in mouse models that without the formation of asci, the infection cannot be transmitted to uninfected mice," says Cushion, also a professor in the UC Division of Infectious Diseases. "It provides strong evidence that these asci are the agents of the infection--a concept suspected, but heretofore not proven. Our analysis has shown that these echinocandin-treated fungi were trying to proceed with sexual replication but could not due to a lack of beta-glucan, an integral cell wall component in asci."

Cushion says the echinocandins don't attack non-beta glucan producing life cycles in pneumocystis pneumonia, which can remain in the lungs despite treatment of up to three weeks. Researchers hope their knowledge will help us understand how long-term use of echinocandins may affect the bodies of immune-compromised patients and if it will eventually rid their systems of pneumocystis pneumonia.

"In a clinic setting, the echinocandin should not be given as a monotherapy as cessation of therapy allows the asci to return," says Cushion. "Patients are going to need something else to kill the trophic life forms that linger behind in the lungs. Three weeks of treatment with echinocandins is the standard regimen, but what if we take it out to three months? Will it go away?"

"If the fungi that remain after extended treatment with an echinocandin disappear, this would provide the evidence that sexual replication is obligatory for pneumocystis," says Cushion.

Cushion is working with co-investigator Alexey Porollo, PhD, associate professor in the UC Department of Pediatrics and researcher at Cincinnati Children's.

"Pneumocystis species live a parasitic life style and are not cultivable outside their mammalian hosts," says Porollo. "This severely limits studies of these fungi at molecular level and hinders the design of new drugs against this pathogen."

"A vast majority of genes of this fungus are not functionally annotated, which also presents a huge challenge to investigate this organism using standard omics tools," says Porollo. "However, it makes it more interesting to study such an organism, as many areas of its biology still lie in an uncharted territory. In addition to probing the extended therapy with echinocandins, our collaborative efforts tackle such riddles in pneumocystis biology as metabolic strategies, tolerance to excessive cytotoxic labile copper environment, and host specificity."

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