Abstract: Novel analogs of epothilone A, epothilone B, and epothilone C are synthesized by Stille coupling thazole-stannanes to macrolactone intermediates. The synthetic epothilone analogs selectively prevent mitosis in cancer cells through the induction and stabilization of microtubulin assembly. Selected synthetic epothilone analogs are demonstrated to have greater bioactivity than their corresponding native compound.

Abstract: Sarcodictyin A and B, eleutherobin, and bioactive analogs thereof synthesized using solid phase and solution phase chemistries. The synthetic method employs an attachment of common precursors, e.g., compounds 1880 or 200, on a solid support for generating conjugates 230 and 240, followed by standard chemical manipulations. A combinatorial library of sarcodictyins and eletherobin analogs was constructed with modified C-8 ester, C-15 ester and C-4 ketal functionalities and was screened for activity with respect to tubulin polymerization and cytotoxic activity against tumor cells, including Taxol-resistant lines. Compounds 600, 610, 630, 660-700, 730, 760, 850, and 920 were identified to be of equal or superior biological activities as compared to their corresponding natural product.

Abstract: A silyloxy aromatic derivative capable of alkylating a target biological molecule when activated by ionic strength. A sequence directed reagent may be constructed by conjugating a methyl silyloxy aromatic derivative to a hexamethylamino linker attached to either the 5' or 3' terminus of an oligonucleotide. Annealing this modified fragment of DNA to its complementary sequence allows for target modification subsequent to ionic activation. The product of this reaction is a covalent crosslink between the reagent and target strands resulting from an alkylation of DNA by the activated silyloxy aromatic derivative. In a preferred embodiment, a nitrophenyl or bromo group is attached to a methyl group of the silyloxy aromatic derivative. This reagent may be similarly linked to an oligonucleotide probe. Activation of the alkylating agent by an ionic signal (X) which may naturally occur, or may be introduced into the media containing the target molecule, such as by the introduction of a salt (MX).

Abstract: A silyloxy aromatic derivative capable of alkylating a target biological molecule when activated by ionic strength. A sequence directed reagent may be constructed by conjugating a methyl silyloxy aromatic derivative to a hexamethyiamino linker attached to either the 5' or 3' terminus of an oligonucleotide. Annealing this modified fragment of DNA to its complementary sequence allows for target modification subsequent to ionic activation. The product of this reaction is a covalent crosslink between the reagent and target strands resulting from an alkylation of DNA by the activated silyloxy aromatic derivative. In a preferred embodiment, a nitrophenyl or bromo group is attached to a methyl group of the silyloxy aromatic derivative. This reagent may be similarly linked to an oligonucleotide probe. Activation of the alkylating agent by an ionic signal (X) which may naturally occur, or may be introduced into the media containing the target molecule, such as by the introduction of a salt (MX).

Abstract: A sequence directed reagent is constructed by conjugating a methyl silyloxy aromatic derivative to a hexamethylamino linker attached to either the 5' or 3' terminus of an oligonucleotide. Annealing this modified fragment of DNA to its complementary sequence allows for target modification subsequent to ionic activation. The product of this reaction is a covalent crosslink between the reagent and target strands resulting from an alkylation of DNA by the activated silyloxy aromatic derivative. In a preferred embodiment, a nitrophenyl group is attached to the methyl group of the silyloxy aromatic derivative. This reagent is similarly linked to an oligonucleotide probe. Activation of this probe linked alkylating agent by an ionic signal, (X) which may naturally occur, or may be introduced into the media containing the target molecule, such as by the introduction of a salt (MX).