New insights into DHFR interactions: analysis of Pneumocystis carinii and mouse DHFR complexes with NADPH and two highly potent 5-(omega-carboxy(alkyloxy) trimethoprim derivatives reveals conformational correlations with activity and novel parallel ring stacking interactions.

Structural data are reported for two highly potent antifolates, 2,4-diamino-5-[3',4'-dimethoxy-5'-(5-carboxy-1-pentynyl)]benzylpyrimidine (PY1011), with 5000-fold selectivity for Pneumocystis carinii dihydrofolate reductase (pcDHFR), relative to rat liver DHFR, and 2,4-diamino-5-[2-methoxy-5-(4-carboxybutyloxy)benzyl]pyrimidine (PY957), that has 80-fold selectivity for pcDHFR. Crystal structures are reported for NADPH ternary complexes with PY957 and pcDHFR, refined to 2.2 A resolution; with PY1011 and pcDHFR, refined to 2.0 A resolution; and with PY1011 and mouse DHFR (mDHFR), refined to 2.2 A resolution. These results reveal that the carboxylate of the omega-carboxyalkyloxy side chain of these inhibitors form ionic interactions with the conserved Arg in the substrate binding pocket of DHFR. These data suggest that the enhanced inhibitory activity of PY1011 compared with PY957 is, in part, due to the favorable contacts with Phe69 of pcDHFR by the methylene carbons of the inhibitor side chain that are oriented by the triple bond of the 1-pentynyl side chain. These contacts are not present in the PY957 pcDHFR complex, or in the PY1011 mDHFR complex. In the structure of mDHFR the site of Phe69 in pcDHFR is occupied by Asn64. These data also revealed a preference for an unusual parallel ring stacking interaction between Tyr35 of the active site helix and Phe199 of the C-terminal beta sheet in pcDHFR and by Tyr33 and Phe179 in mDHFR that is independent of bound ligand. A unique His174-His187 parallel ring stacking interaction was also observed only in the structure of pcDHFR. These ring stacking interactions are rarely found in any other protein families and may serve to enhance protein stability.

Purification and characterization of human-derived Pneumocystis jirovecii dihydrofolate reductase expressed in Sf21 insect cells and in Escherichia coli.

Pneumonia caused by Pneumocystis jirovecii is still a major opportunistic infection among patients with AIDS. This opportunitistic pathogen is susceptible to therapy with inhibitors of the enzyme dihydrofolate reductase (DHFR) that target cell growth. Recent studies have shown that recombinant human-derived Pneumocystis DHFR (pDHFR) differs from rat-derived pDHFR by 38% in amino acid sequence. However, characterization of drug susceptibility, kinetics, and the three-dimensional structure of human-derived pDHFR has been hampered by the limited availability of purified material. The present study was undertaken to develop procedures to prepare sufficient enzyme for structure/function studies. Protein yield was limited when human-derived pDHFR was expressed in Escherichia coli using a pET28a(+) vector with an N-terminal His-tag for the 25 kDa protein. Therefore, the protein was expressed in Sf21 insect cells by baculovirus infection. The soluble enzyme was purified from cell lysates via Ni-chelated chromatographic columns, yielding about 5.1 mg of human-derived pDHFR fusion protein per liter of Sf21 culture. The purified protein had the expected mass as determined from Western blots with antibody for the N-terminal His-tag. This His-tagged recombinant DHFR from human-derived Pneumocystis was catalytically active and demonstrated kinetics similar to the recombinant enzyme from rat-derived Pneumocystis. The present studies for production of soluble human-derived pDHFR indicated that the baculovirus expression system supported production of significantly purer catalytically active enzyme in higher yields than that expressed in bacterial cultures. These protocols now make it possible to facilitate screening of antifolates with selectivity for human-derived pDHFR and to determine its three-dimensional structure.