Protein Structure May Lead to Treatment for Infection Targeting Cystic Fibrosis Patients

The six-sided ring in the Hcp1 crystal structure provided a clue to the secretion pathway of Pseudomonas aeruginosa that is a leading killer of cystic fibrosis patients. Argonne National Laboratory image by Marianne Cuff.  

 

Argonne researchers have determined the structure of a key protein believed to play a role in a deadly infection that afflicts the lungs of patients with cystic fibrosis. This finding, published in the June 9, 2006 issue of Science, may lead to a new drug to treat the bacterial infection.

Pseudomonas aeruginosa, a pathogen that infects more than 80 percent of cystic fibrosis patients, is a leading cause of these patients' deaths. P. aeruginosa is difficult to treat because it is resistant to many drugs.

While working through a number of pathogenic proteins, Argonne protein crystallographer Marianne Cuff's keen eye caught a glimpse of a bagel-shaped pore. Closer inspection revealed a six-sided ring that she believed "might be involved in transferring toxins into cells," she said.

"I thought it would be an important structure," she said. "The ring is very stable and unusual and nature usually has a purpose for these stable forms."

Cuff, who is a co-author of the Science paper, deposited the structure of the protein, called Hcp1, into the Protein Data Bank, a resource used by biologists worldwide to find information about the proteins they are studying.

While exploring the Protein Data Bank, Harvard Medical School researchers who were also studying P. aeruginosa in the laboratory of John Mekalanos recognized that the amino acid sequence of Hcp1 in P. aeruginosa closely resembled that of Hcp1 in Vibrio cholerae. The Mekalanos lab had previously discovered that the Hcp1 protein of V. cholerae is released from the bacterium via a novel secretion pathway.

Because Hcp1 proteins from both pathogens belong to the same protein family, Science paper lead-author Joseph D. Mougous, wondered whether the P. aeruginosa Hcp1 might also be secreted via this pathway. Researchers at Harvard and Argonne quickly formed a collaboration and confirmed the hypothesis. They then turned their attention to Hcp1 in cystic fibrosis patients to gain more insight in the role of Hcp1 during infection.

Pathogenic bacteria such as P. aeruginosa use protein secretion systems to cause disease in their hosts, said Mougous, a research fellow in the Harvard Medical School Department of Microbiology and Molecular Genetics. In the case of P. aeruginosa, the host may be a cancer patient with a weakened immune system, a burn patient or a person with cystic fibrosis.

Cystic fibrosis patients are particularly susceptible to P. aeruginosa, Mougous said. The bacterium thrives in the excess mucus that accumulates in their lungs. Once the infection in a cystic fibrosis patient's lung has been established, these hardy bacteria are difficult or impossible to clear, which over many years eventually results in death of the patient.

Working with cystic fibrosis patients at Children's Hospital Boston, the Harvard Medical School researchers sought and found Hcp1 in the sputum of patients with P. aeruginosa. They also found Hcp1 antibodies in the patients' blood further proof that Hcp1 plays a critical role in the infection. The human immune system creates antibodies to pathogens it is exposed to.

"This finding provides a possible drug target to fight the infection in cystic fibrosis patients," explained Andzrej Joachimiak, director of Argonne's Structural Biology Center and of the Midwest Center for Structural Genomics based at Argonne, where the protein structure research was performed.

Determining and imaging the structure of the protein Hcp1 was part of the routine structural biology research Argonne biologists are performing on pathogens with funding from the National Institute of General Medical Science's (NIGMS) Protein Structure Initiative. This initiative funds researchers to determine a number of unique protein structures to serve as a base of knowledge from which other structures and functions can be inferred.

"This research is an example of how the Protein Structure Initiative was designed to work," explained Joachimiak. "A structure we determined led researchers to design an experiment to provide information that provides key information about how a pathogen works. New treatments could be developed from this starting point."

The protein crystallography research was performed at Argonne by researchers in the Argonne-ledMidwestCenter for Structural Genomics, funded by NIGMS. Following the protein cloning, expression, purification and crystallization, the protein crystallography data were collected at Argonne's StructuralBiologyCenter at this hemisphere's most brilliant source of X-rays for research the Advanced Photon Source. Cuff converted the data into three-dimensional models that revealed the six-sided pore with the 40-Angstrom wide center.

Source: Argonne National Laboratory

 

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