Polymerases have a structurally highly conserved negatively charged amino acid motif that is strictly required for Mg 2+ cation-dependent catalytic incorporation of (d)NTP nucleotides into nucleic acids. Based on these characteristics, a nucleoside monophosphonate scaffold, α-carboxy nucleoside phosphonate (α-CNP), was designed that is recognized by a variety of polymerases. Kinetic, biochemical, and crystallographic studies with HIV-1 reverse transcriptase revealed that α-CNPs mimic the dNTP binding through a carboxylate oxygen, two phosphonate oxygens, and base-pairing with the template. In particular, the carboxyl oxygen of the α-CNP acts as the potential equivalent of the α-phosphate oxygen of dNTPs and two oxygens of the phosphonate group of the α-CNP chelate Mg 2+ , mimicking the chelation by the β-and γ-phosphate oxygens of dNTPs. α-CNPs (i) do not require metabolic activation (phosphorylation), (ii) bind directly to the substrate-binding site, (iii) chelate one of the two active site Mg 2+ ions, and (iv) reversibly inhibit the polymerase catalytic activity without being incorporated into nucleic acids. In addition, α-CNPs were also found to selectively interact with regulatory (i.e., allosteric) Mg 2+ -dNTP-binding sites of nucleos(t)ide-metabolizing enzymes susceptible to metabolic regulation. α-CNPs represent an entirely novel and broad technological platform for the development of specific substrate active-or regulatory-site inhibitors with therapeutic potential. The polymerization of nucleotides by Escherichia coli DNA polymerase I represents a general model for catalytic action of nucleic acid polymerases (SI Appendix, Fig. S1) (1, 2). According to this model, there is a universal role for the Mg 2+ cation to interact with three phosphate oxygens of dNTP. The highly conserved consensus motifs in every polymerase active site consist of either aspartate or glutamate residues that chelate Mg 2+ through three additional coordination bonds during polymerization (2, 3). The crucial role of the metal cofactor and structurally conserved active site architecture in polymerases has also been demonstrated by validating Mg 2+ as a target for the design of antiviral drugs, not only against HIV RT but also, among others, against HIV integrase, HIV ribonuclease H (RNase H), and influenza-encoded endonuclease (4, 5). Hence, it should be feasible to design a universal but simplified (d)NTP mimic that binds efficiently to a wide variety of DNA/RNA polymerases.It was hypothesized that a universal nucleoside triphosphate mimic should contain three major indispensable entities: (i) a nucleobase part (i.e., to achieve optimal Watson-Crick basepairing with the template overhang), (ii) a replacement of the triphosphate moiety that should enable efficient Mg 2+ -directed coordination, and (iii) a variable linker between the nucleobase and the modified triphosphate to mimic the pentose entity present in natural (d)NTPs. For the triphosphate part, we chose an α-carboxy phosphonate entity that is chemically stable in physiolog...
