Lipophilic bisphosphonates as dual farnesyl/geranylgeranyl diphosphate synthase inhibitors: an X-ray and NMR investigation.

Considerable effort has focused on the development of selective protein farnesyl transferase (FTase) and protein geranylgeranyl transferase (GGTase) inhibitors as cancer chemotherapeutics. Here, we report a new strategy for anticancer therapeutic agents involving inhibition of farnesyl diphosphate synthase (FPPS) and geranylgeranyl diphosphate synthase (GGPPS), the two enzymes upstream of FTase and GGTase, by lipophilic bisphosphonates. Due to dual site targeting and decreased polarity, the compounds have activities far greater than do current bisphosphonate drugs in inhibiting tumor cell growth and invasiveness, both in vitro and in vivo. We explore how these compounds inhibit cell growth and how cell activity can be predicted based on enzyme inhibition data, and using X-ray diffraction, solid state NMR, and isothermal titration calorimetry, we show how these compounds bind to FPPS and/or GGPPS.

Bisphosphonate inhibitors of ATP-mediated HIV-1 reverse transcriptase catalyzed excision of chain-terminating 3'-azido, 3'-deoxythymidine: a QSAR investigation.

We report the results of an investigation of the inhibition of the ATP-mediated HIV-1 reverse transcriptase catalyzed phosphorolysis in vitro of AZT from AZT-terminated DNA primers by a series of 42 bisphosphonates. The four most active compounds possess neutral, halogen-substituted phenyl or biphenyl sidechains and have IC(50) values < 1 microM in excision inhibition assays. Use of two comparative molecular similarity analysis methods to analyze these inhibition results yielded a classification model with an overall accuracy of 94%, and a regression model having good accord with experiment (q(2)=0.63, r(2)=0.91), with the experimental activities being predicted within, on average, a factor of 2. The most active species had little or no toxicity against three human cell lines (IC(50)(avg) > 200 microM). These results are of general interest since they suggest that it may be possible to develop potent bisphosphonate-based AZT-excision inhibitors with little cellular toxicity, opening up a new route to restoring AZT sensitivity in otherwise resistant HIV-1 strains.

Activity of sulfonium bisphosphonates on tumor cell lines.

We investigated three series of sulfonium bisphosphonates for their activity in inhibiting the growth of three human tumor cell lines. The first series consisted of 6 cyclic sulfonium bisphosphonates, the most active species having an (average) IC50 of 89 microM. The second consisted of 10 phenylalkyl and phenylalkoxy bisphosphonates, the most active species having an IC50 of 18 microM. The third series consisted of 17 n-alkyl sulfonium bisphosphonates, the most active species having an IC50 of approximately 240 nM. Three QSAR models showed that the experimental cell growth inhibition results could be well predicted. We also determined the structures of one sulfonium bisphosphonate bound to farnesyl diphosphate synthase, finding that it binds exclusively to the dimethylallyl diphosphate binding site. These results are of interest since they show that sulfonium bisphosphonates can have potent activity against a variety of tumor cell lines, the most active species having IC50 values much lower than conventional nitrogen-containing bisphosphonates.