Abstract: A method for inhibiting therapeutic drug resistance within a cell over-expressing a membrane protein is provided. The method comprises synthesizing a dimeric prodrug inhibitor of a monomeric therapeutic agent; administering the dimeric prodrug inhibitor to the membrane protein together with the monomeric therapeutic agent; and occupying at least one substrate binding site of the membrane protein with the synthesized dimeric prodrug to allow the monomeric therapeutic agent to accumulate within the cell. The dimeric prodrug inhibitor contains a crosslinking agent that is adapted to breakdown under reducing conditions within the cytosol of the cell to cause the dimeric prodrug to revert back to a form equivalent to the monomeric therapeutic agent.

Abstract: ATP-binding cassette (ABC) transporters generally contain a number of transmembrane helices. The present invention provides synthetic peptides derived from these transmembrane helices. The peptides inhibit ABC transporter function, presumably by disrupting the structure of the ABC transporter. Negatively charged residues are added at the extracellular terminus to promote correct orientation of the peptide in the membrane, and residues considered to aid solubility may be added at that terminus to increase solubility. Exemplary ABC transporters that can be inhibited by these peptides include MDR1, MRP1, MRP2 and BCRP. The invention further provides nucleic acids encoding the peptides, expression cassettes comprising the nucleic acids, and host cells expressing the expression cassettes. The invention further provides a simple and inexpensive assay for determining whether a potential chemotherapeutic agent can inhibit the activity of P-gly-coprotein.

Abstract: Bioanalytical device that includes a biofunctional component and an optional sensor component. The device includes arrays of addressable, durable, asymmetric biofunctional membranes containing protein transducers capable of unidirectional transport of analytes. Suitable protein transducers include members of the ATP-binding cassette family, such as P-glycoprotein.

Abstract: The present invention relates to a novel method for the treatment of neoplasia, including cancer and other diseases and conditions in humans and mammals. More particularly, in preferred aspects, the present invention provides a method for the use of prenylcysteine analogs for the treatment of neoplasia, hyperproliferative cell growth including psoriasis, restenosis following cardiovascular surgery, hyperplasia, including renal hyperplasia, chronic inflammatory diseases including rheumatoid and osteoarthritis, among others.

Abstract: Bioanalytical device that includes a biofunctional component and an optional sensor component. The device includes arrays of addressable, durable, asymmetric biofunctional membranes containing protein transducers capable of unidirectional transport of analytes. Suitable protein transducers include members of the ATP-binding cassette family, such as P-glycoprotein.