Expression and Characterization of the Two Flavodoxin Proteins of

Zhi-Qiang Wang, Rachel J. Lawson, Madhavan R. Buddha, Chin-Chuan Wei, Brian R. Crane, Andrew W. Munro, Dennis J. Stuehr. Bacterial Flavodoxins ...
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12390

Biochemistry 2004, 43, 12390-12409

Expression and Characterization of the Two Flavodoxin Proteins of Bacillus subtilis, YkuN and YkuP: Biophysical Properties and Interactions with Cytochrome P450 BioI† Rachel J. Lawson,‡ Claes von Wachenfeldt,§ Ihtshamul Haq,⊥ John Perkins,| and Andrew W. Munro*,‡ Department of Biochemistry, UniVersity of Leicester, The Adrian Building, UniVersity Road, Leicester LE1 7RH, U.K., Department of Cell and Organism Biology, Lund UniVersity, So¨lVegatan 35, SE-223 62 Lund, Sweden, Centre for Chemical Biology, Department of Chemistry, UniVersity of Sheffield, Brook Hill, Sheffield, S3 7HK, U.K., and Biotechnology Research and DeVelopment, DSM Nutritional Products, P.O. Box 3255, Building 203/20A, CH-4002, Basel, Switzerland ReceiVed April 29, 2004; ReVised Manuscript ReceiVed July 23, 2004

ABSTRACT: The two flavodoxins (YkuN and YkuP) from Bacillus subtilis have been cloned, overexpressed in Escherichia coli and purified. DNA sequencing, mass spectrometry, and flavin-binding properties showed that both YkuN and YkuP were typical short-chain flavodoxins (158 and 151 amino acids, respectively) and that an error in the published B. subtilis genome sequence had resulted in an altered reading frame and misassignment of YkuP as a long-chain flavodoxin. YkuN and YkuP were expressed in their blue (neutral semiquinone) forms and reoxidized to the quinone form during purification. Potentiometry confirmed the strong stabilization of the semiquinone form by both YkuN and YkuP (midpoint reduction potential for oxidized/semiquinone couple ) -105 mV/-105 mV) with respect to the hydroquinone (midpoint reduction potential for semiquinone/hydroquinone couple ) -382 mV/-377 mV). Apoflavodoxin forms were generated by trichloroacetic acid treatment. Circular dichroism studies indicated that flavin mononucleotide (FMN) binding led to considerable structural rearrangement for YkuP but not for YkuN. Both apoflavodoxins bound FMN but not riboflavin avidly, as expected for short-chain flavodoxins. Structural stability studies with the chaotrope guanidinium chloride revealed that there is moderate destabilization of secondary and tertiary structure on FMN removal from YkuN, but that YkuP apoflavodoxin has similar (or slightly higher) stability compared to the holoprotein. Differential scanning calorimetry reveals further differences in structural stability. YkuP has a lower melting temperature than YkuN, and its endotherm is composed of a single transition, while that for YkuN is biphasic. Optical and fluorimetric titrations with oxidized flavodoxins revealed strong affinity (Kd values consistently 90% pure. To produce electrophoretically homogeneous YkuN and YkuP proteins, a final gel filtration step using Sephadex S-200 resin (column dimensions ∼4 cm × 1 m) was used. Small aliquots of the concentrated flavodoxin preparations (ca. 1 mL) were run through the column in buffer A (0.10 mL/min). Fractions were collected, pooled, and analyzed spectrophotometrically

Biochemistry, Vol. 43, No. 39, 2004 12393 as before. YkuN with an A280/A461 nm ratio of ∼6:1 were regarded as pure (as confirmed by SDS-PAGE), and similarly pure YkuP had an A280/A461 nm ratio of ∼3.5:1. The final protein solutions were concentrated as previously described to ∼1 mM and dialyzed against buffer A containing 50% v/v glycerol at 4 °C. Pure flavodoxins were stored in small aliquots (∼ 50-100 µL) at -80 °C. All purification steps were done in a cold room (at 4 °C), and all solutions contained phenylmethylsulfonyl fluoride (1 mM) and benzamidine hydrochloride (1 mM) to minimize proteolysis. Expression and Purification of E. coli FlaVodoxin NADP+ Oxidoreductase (FLDR). E. coli FLDR was purified to provide a NADPH-dependent reductase system for mediation of electron transfer to YkuN and YkuP for transient kinetic and steady-state studies. FLDR was expressed and purified largely as described previously (32). Induction with IPTG was found to be unnecessary for high levels of production of FLDR. Following purification by ion exchange chromatography on DEAE Sepharose and Q-Sepharose resins, a final affinity purification step on a 2′,5′-ADP Sepharose column was used to prepare homogeneous FLDR. Fractions from the affinity purification process with A280/A456 ratios of