Chaperone screens for DnaK inhibitors

SCRANTON, Pa.—Chaperone Technologies Inc. is using its antimicrobial drug discovery assay system to screen poten­tial drug candidates from the National Institutes of Health's library of compounds.

 

The open-ended collabora-tion, implemented through the NIH's Molecular Libraries Screening Center Network location at Emory University, requires adapting Chaperone's system for high-throughput screening. "One of the first [program benefits] is the valida­tion of DnaK as a target," says Chaperone CEO and president Ken Kovan. "And there's cer­tainly a tremendous amount of value in that, having the NIH endorse what we're doing. The second point is the scaling up of the assay itself."

 

Chaperone is investigating candidates that inhibit DnaK, a bacterial structure that "chaper­ones" survival of pathogens by by correcting misshapen pro­teins. The company uses its assay for internal drug discovery and validation of potential com­pounds.

 

It's unclear what DnaK inhibi­tors might be found by screening the 250,000 compounds in the NIH library, says Mike Sturgess, Chaperone's director of chemistry, but it's important to look at a var­ied data set. "From Chaperone's perspective, what we would like to see is a screen that has really cov­ered a broad spectrum of chemical space," he says. "We have a lot of expertise in the peptide arena from the work that we've already done, and some of our work has taken us away from peptides toward small molecules, but they have a particu­lar flavor."

 

Screening data will go into the NIH's PubChem database, says Carson Loomis, program direc­tor of the NIH's molecular library program. "The way it works," says Loomis, "is that they are working right along with the center that's doing the screening. So that's where they get access to the data, virtually as it's being generated." When data are reconfirmed, sever­al weeks later, they are submitted to PubChem for public use.

 

That window, says Sturgess, gives Chaperone an opportunity to investigate potential new DnaK inhibitors. "I suspect that our internal discovery programs will probably be running in a parallel track to this," he says. Although Sturgess doesn't expect the screen­ing to provide enough information for quick, meaningful patent appli­cations, he foresees the possibility of finding broad and diverse DnaK inhibitors for further study.

 

Chaperone also benefits from the requirement to miniaturize its assaying protocols for HTS. "They run 384-well plate high-through­put screening," says Sturgess, but Chaperone's original protocol is for 96-well plates, so Chaperone may later market the HTS version to other companies as a tool.

 

The NIH established its screen­ing network not as a drug devel­opment program but to draw government, business, and aca­demia together for developing research tools to investigate small molecules. "We are really excited that we're having for-profit orga­nizations applying to get access to this resource," says Loomis. "Chaperone is one of several bio­tech companies that have applied and is one of several that have had the quality of application and tar­get importance to be accepted into screening by the network."