Crystallization and preliminary X-ray diffraction studies of vitamin D3 hydroxylase, a novel cytochrome P450 isolated from Pseudonocardia autotrophica

The 16α-Hydroxylation of Progesterone by Cytochrome P450 107X1 from Streptomyces avermitilis

Cytochrome P450 enzymes (CYPs or P450s) are ubiquitous heme-dependent enzymes that catalyze the monooxygenation of non-activated C-H bonds to modify the structure of the substrate. In this study, we heterologously expressed CYP107X1 from Streptomyces avermitilis and conducted in vitro substrate screening using the alternative redox partners putidaredoxin and putidaredoxin reductase. CYP107X1 catalyzed the 16α-hydroxylation of progesterone with regio- and stereoselectivity. The spectroscopic analyses showed that CYP107X1 bound progesterone with a relatively high K_d value of 65.3±38.9 μM. The K_m and k_cat values for progesterone were estimated to be 47.7±12.0 μM and 0.30 min^-1 , respectively. Furthermore, a crystal structure was obtained of CYP107X1 bound with glycerol from the buffer solution. Interestingly, a conserved threonine was replaced with asparagine in CYP107X1, indicating that it may adopt an unnatural proton transfer process and play a crucial role in its catalytic activity.

Structural insights into the mechanism of the drastic changes in enzymatic activity of the cytochrome P450 vitamin D3 hydroxylase (CYP107BR1) caused by a mutation distant from the active site

Cytochromes P450 (P450s) are haem-containing enzymes that catalyze medically and industrially important oxidative reactions, and many P450s have been subjected to directed evolution and site-directed mutagenesis to improve their activity and substrate specificity. Nonetheless, in most cases the mechanism that leads to drastic changes in specific activity after the introduction of an amino-acid substitution distant from the active-site pocket is unclear. Here, two crystal structures of inactive mutants of the P450 vitamin D3 hydroxylase (Vdh), Vdh-F106V and Vdh-L348M, which were obtained in the course of protein-engineering experiments on Vdh, are reported. The overall structures of these mutants show an open conformation similar to that of wild-type Vdh (Vdh-WT), whereas a rearrangement of the common main-chain hydrogen bonds is observed in the CD-loop (residues 102-106), resulting in a more compactly folded CD-loop relative to that of Vdh-WT. The previously reported structures of Vdh-WT and of the highly active Vdh-T107A and Vdh-K1 mutants have a more stretched CD-loop, with partial formation of 310-helix-type hydrogen bonds, both in the open and closed states. Molecular-dynamics simulations also showed that the frequency of the 310-helix is significantly reduced in Vdh-F106V and Vdh-L348M. The closed conformation is crucial for substrate and ferredoxin binding to initiate the catalytic reaction of Vdh. Therefore, it is implied that the small local structural changes observed in this study might disrupt the conformational transition from the open to the closed state, thereby leading to a complete loss of vitamin D3 hydroxylase activity.

Molecular characterization, modeling and docking of CYP107CB2 from Bacillus lehensis G1, an alkaliphile

Cytochrome P450s are a superfamily of heme monooxygenases which catalyze a wide range of biochemical reactions. The reactions involve the introduction of an oxygen atom into an inactivated carbon of a compound which is essential to produce an intermediate of a hydroxylated product. The diversity of chemical reactions catalyzed by cytochrome P450s has led to their increased demand in numerous industrial and biotechnology applications. A recent study showed that a gene sequence encoding a CYP was found in the genome of Bacillus lehensis G1, and this gene shared structural similarity with the bacterial vitamin D hydroxylase (Vdh) from Pseudonocardia autotrophica. The objectives of present study was to mine, for a novel CYP from a new isolate B. lehensis G1 alkaliphile and determine the biological properties and functionalities of CYP in this bacterium. Our study employed the usage of computational methods to search for the novel CYP from CYP structural databases to identify the conserved pattern, functional domain and sequence properties of the uncharacterized CYP from B. lehensis G1. A computational homology model of the protein's structure was generated and a docking analysis was performed to provide useful structural knowledge on the enzyme's possible substrate and their interaction. Sequence analysis indicated that the newly identified CYP, termed CYP107CB2, contained the fingerprint heme binding sequence motif FxxGxxxCxG at position 336-345 as well as other highly conserved motifs characteristic of cytochrome P450 proteins. Using docking studies, we identified Ser-79, Leu-81, Val-231, Val-279, Val-383, Ala-232, Thr-236 and Thr-283 as important active site residues capable of stabilizing interactions with several potential substrates, including vitamin D3, 25-hydroxyvitamin D3 and 1α-hydroxyvitamin D3, in which all substrates docked proximally to the enzyme's heme center. Biochemical analysis indicated that CYP107CB2 is a biologically active protein to produce 1α,25-dihydroxyvitamin D3 from 1α-hydroxyvitamin D3. Based on these results, we conclude that the novel CYP107CB2 identified from B. lehensis G1 is a putative vitamin D hydroxylase which is possibly capable of catalyzing the bioconversion of parental vitamin D3 to calcitriol, or related metabolic products.

Cytochrome P450-mediated metabolism of vitamin D

The vitamin D signal transduction system involves a series of cytochrome P450-containing sterol hydroxylases to generate and degrade the active hormone, 1α,25-dihydroxyvitamin D3, which serves as a ligand for the vitamin D receptor-mediated transcriptional gene expression described in companion articles in this review series. This review updates our current knowledge of the specific anabolic cytochrome P450s involved in 25- and 1α-hydroxylation, as well as the catabolic cytochrome P450 involved in 24- and 23-hydroxylation steps, which are believed to initiate inactivation of the vitamin D molecule. We focus on the biochemical properties of these enzymes; key residues in their active sites derived from crystal structures and mutagenesis studies; the physiological roles of these enzymes as determined by animal knockout studies and human genetic diseases; and the regulation of these different cytochrome P450s by extracellular ions and peptide modulators. We highlight the importance of these cytochrome P450s in the pathogenesis of kidney disease, metabolic bone disease, and hyperproliferative diseases, such as psoriasis and cancer; as well as explore potential future developments in the field.

Identification of a cyclosporine-specific P450 hydroxylase gene through targeted cytochrome P450 complement (CYPome) disruption in Sebekia benihana

It was previously proposed that regio-specific hydroxylation of an immunosuppressive cyclosporine (CsA) at the 4th N-methyl leucine is mediated by cytochrome P450 hydroxylase (CYP) in the rare actinomycete Sebekia benihana. This modification is thought to be the reason for the hair growth-promoting side effect without the immunosuppressive activity of CsA. Through S. benihana genome sequencing and in silico analysis, we identified the complete cytochrome P450 complement (CYPome) of S. benihana, including 21 CYPs and their electron transfer partners, consisting of 7 ferredoxins (FDs) and 4 ferredoxin reductases (FDRs). Using Escherichia coli conjugation-based S. benihana CYPome-targeted disruption, all of the identified CYP, FD, and FDR genes in S. benihana were individually inactivated. Among the 32 S. benihana exconjugant mutants tested, only a single S. benihana CYP mutant, ΔCYP-sb21, failed to exhibit CsA hydroxylation activity. The hydroxylation was restored by CYP-sb21 gene complementation. Since all S. benihana FD and FDR disruption mutants maintained CsA hydroxylation activity, it can be concluded that CYP-sb21, a new member of the bacterial CYP107 family, is the only essential component of the in vivo regio-specific CsA hydroxylation process in S. benihana. Moreover, expression of an extra copy of the CYP-sb21 gene increased CsA hydroxylation in wild-type S. benihana and an NADPH-enriched Streptomyces coelicolor mutant, by 2-fold and 1.5-fold, respectively. These results show for the first time that regio-specific hydroxylation of CsA is carried out by a specific P450 hydroxylase present in S. benihana, and they set the stage for the biotechnological application of regio-specific CsA hydroxylation through heterologous CYP-sb21 expression.

The role of vitamin D in pulmonary disease: COPD, asthma, infection, and cancer

The role of vitamin D (VitD) in calcium and bone homeostasis is well described. In the last years, it has been recognized that in addition to this classical function, VitD modulates a variety of processes and regulatory systems including host defense, inflammation, immunity, and repair. VitD deficiency appears to be frequent in industrialized countries. Especially patients with lung diseases have often low VitD serum levels. Epidemiological data indicate that low levels of serum VitD is associated with impaired pulmonary function, increased incidence of inflammatory, infectious or neoplastic diseases. Several lung diseases, all inflammatory in nature, may be related to activities of VitD including asthma, COPD and cancer. The exact mechanisms underlying these data are unknown, however, VitD appears to impact on the function of inflammatory and structural cells, including dendritic cells, lymphocytes, monocytes, and epithelial cells. This review summarizes the knowledge on the classical and newly discovered functions of VitD, the molecular and cellular mechanism of action and the available data on the relationship between lung disease and VitD status.

Bioconversion of vitamin D to its active form by bacterial or mammalian cytochrome P450

Bioconversion processes, including specific hydroxylations, promise to be useful for practical applications because chemical syntheses often involve complex procedures. One of the successful applications of P450 reactions is the bioconversion of vitamin D₃ to 1α,25-dihydroxyvitamin D₃. Recently, a cytochrome P450 gene encoding a vitamin D hydroxylase from the CYP107 family was cloned from Pseudonocardia autotrophica and is now applied in the bioconversion process that produces 1α,25-dihydroxyvitamin D₃. In addition, the directed evolution study of CYP107 has significantly enhanced its activity. On the other hand, we found that Streptomyces griseolus CYP105A1 can convert vitamin D₃ to 1α,25-dihydroxyvitamin D₃. Site-directed mutagenesis of CYP105A1 based on its crystal structure dramatically enhanced its activity. To date, multiple vitamin D hydroxylases have been found in bacteria, fungi, and mammals, suggesting that vitamin D is a popular substrate of the enzymes belonging to the P450 superfamily. A combination of these cytochrome P450s would produce a large number of compounds from vitamin D and its analogs. Therefore, we believe that the bioconversion of vitamin D and its analogs is one of the most promising P450 reactions in terms of practical application.

Structural evidence for enhancement of sequential vitamin D3 hydroxylation activities by directed evolution of cytochrome P450 vitamin D3 hydroxylase

Vitamin D(3) hydroxylase (Vdh) isolated from actinomycete Pseudonocardia autotrophica is a cytochrome P450 (CYP) responsible for the biocatalytic conversion of vitamin D(3) (VD(3)) to 1α,25-dihydroxyvitamin D(3) (1α,25(OH)(2)VD(3)) by P. autotrophica. Although its biological function is unclear, Vdh is capable of catalyzing the two-step hydroxylation of VD(3), i.e. the conversion of VD(3) to 25-hydroxyvitamin D(3) (25(OH)VD(3)) and then of 25(OH)VD(3) to 1α,25(OH)(2)VD(3), a hormonal form of VD(3). Here we describe the crystal structures of wild-type Vdh (Vdh-WT) in the substrate-free form and of the highly active quadruple mutant (Vdh-K1) generated by directed evolution in the substrate-free, VD(3)-bound, and 25(OH)VD(3)-bound forms. Vdh-WT exhibits an open conformation with the distal heme pocket exposed to the solvent both in the presence and absence of a substrate, whereas Vdh-K1 exhibits a closed conformation in both the substrate-free and substrate-bound forms. The results suggest that the conformational equilibrium was largely shifted toward the closed conformation by four amino acid substitutions scattered throughout the molecule. The substrate-bound structure of Vdh-K1 accommodates both VD(3) and 25(OH)VD(3) but in an anti-parallel orientation. The occurrence of the two secosteroid binding modes accounts for the regioselective sequential VD(3) hydroxylation activities. Moreover, these structures determined before and after directed evolution, together with biochemical and spectroscopic data, provide insights into how directed evolution has worked for significant enhancement of both the VD(3) 25-hydroxylase and 25(OH)VD(3) 1α-hydroxylase activities.