At Cold Spring Harbor Laboratory (CSHL), scientists report a discovery that they hope will lead to the development of a powerful new way of treating an aggressive form of breast cancer.
The breast cancer subtype in question is commonly called "HER2-positive"; it's a subset of the disease affecting about one patient in four, in which tumor cells overexpress a signaling protein called HER2. The blockbuster drug Herceptin is a treatment of choice for many women with HER2-positive breast cancer, but in most cases, resistance to the treatment develops within several years.
The prognosis for HER2-positive breast cancer patients is worse than for those with other subtypes of the illness. In a paper appearing online today in Nature Chemical Biology, a multi-institution team led by CSHL Professor Nicholas Tonks reports that it has found a means of inhibiting another protein, called PTP1B, whose expression is also upregulated in HER2-positive breast cancer. PTP1B has been shown to play a critical role in the development of tumors in which HER2 signaling is aberrant.
"The result was an extensive inhibition of tumor growth and prevention of metastasis to the lung in HER2-positive animal models of breast cancer," notes Navasona Krishnan, Ph.D., a postdoctoral investigator in the Tonks lab who performed many of the experiments and is lead author on the paper reporting the results.
Dr. Tonks discovered PTP1B some 25 years ago. It is an enzyme - one in a "superfamily" of 105 called protein tyrosine phosphatases (PTPs) -- that perform the essential biochemical task of removing phosphate groups from amino acids called tyrosines in other proteins. Adding and removing phosphate groups is one of the means by which signals are sent among proteins.
PTP1B for many years has been a target of interest among drug developers. It is well known to be a negative regulator of insulin - an antagonist of insulin signaling -- and of signaling by leptin, the hormone that helps regulate appetite. Drugs that can block or inhibit the action of PTP1B have great potential in controlling diabetes and obesity. Yet properties of the molecule -- involving both its charged active binding site and its shape - have stymied potential developers of inhibitory drugs.
The new paper by Tonks and collaborators importantly reveals an alternative binding site, called an allosteric site, that does not present the biochemical difficulties that the active, or "catalytic," binding site does. This allosteric site is a target of the candidate drug trodusquemine.
Later this year early-stage human trials will begin for the drug, a collaboration of CSHL and North Shore-Long Island Jewish Hospital. Dr. Tonks and CSHL have interests in a joint venture called DepYmed Inc., in partnership with Ohr Pharmaceutical (NasdaqCM: OHRP). The venture seeks to develop trodusquemine and related analogs.