posted on 2002-08-24, 00:00authored byHenrik Sune Andersen, Ole H. Olsen, Lars F. Iversen, Anette L. P. Sørensen, Steen B. Mortensen, Michael S. Christensen, Sven Branner, Thomas K. Hansen, Jesper F. Lau, Lone Jeppesen, Edmond J. Moran, Jing Su, Farid Bakir, Luke Judge, Manou Shahbaz, Tassie Collins, Todd Vo, Michael J. Newman, William C. Ripka, Niels Peter H. Møller
Reversible phosphorylation and dephosphorylation of key proteins on tyrosine residues are
important parts of intracellular signaling triggered by hormones and other agents. Recent
knock-out studies in mice have identified PTP1B as a potential target for the treatment of
diabetes and obesity. As a consequence, a number of academic and industrial groups are
aggressively pursuing the development of selective PTP1B inhibitors. In addition, other protein−tyrosine phosphatases (PTPs) appear to be critically involved in major diseases such as cancer
and autoimmunity. Given the diversity of PTPs and their potential as drug targets in different
diseases, we have taken a broad approach to develop active site-directed selective inhibitors of
specific members of this family of enzymes. Using a high throughput screening, we have
previously identified 2-(oxalylamino)benzoic acid 3a as a relatively weak but classical
competitive inhibitor of several PTPs. On the basis of our early studies, indicating that 3a
might be used as a starting point for the synthesis of selective PTP inhibitors, we now present
our efforts in expansion of this concept and provide here a number of new chemical scaffolds
for the development of inhibitors of different members of the PTP family. Although the core
structure of these inhibitors is charged, good oral bioavailability has been observed in rat for
some compounds. Furthermore, we have observed enhancement of 2-deoxy-glucose accumulation
in C2C12 cells with prodrug analogues.