The regioselectively controlled introduction of chlorine into organic molecules is an important biological and chemical process. This importance derives from the observation that many pharmaceutically active natural products contain a chlorine atom. Flavin-dependent halogenases are one of the principal enzyme families responsible for regioselective halogenation of natural products. Structural studies of two flavin-dependent tryptophan 7-halogenases (PrnA and RebH) have generated important insights into the chemical mechanism of halogenation by this enzyme family. These proteins comprise two modules: a flavin adenine dinucleotide (FAD)-binding module and a tryptophan-binding module. Although the 7-halogenase studies advance a hypothesis for regioselectivity, this has never been experimentally demonstrated. PyrH is a tryptophan 5-halogenase that catalyzes halogenation on tryptophan C5 position. We report the crystal structure of a tryptophan 5-halogenase (PyrH) bound to tryptophan and FAD. The FAD-binding module is essentially unchanged relative to PrnA (and RebH), and PyrH would appear to generate the same reactive species from Cl(-), O(2), and 1,5-dihydroflavin adenine dinucleotide. We report additional mutagenesis data that extend our mechanistic understanding of this process, in particular highlighting a strap region that regulates FAD binding, and may allow communication between the two modules. PyrH has a significantly different tryptophan-binding module. The data show that PyrH binds tryptophan and presents the C5 atom to the reactive chlorinating species, shielding other potential reactive sites. We have mutated residues identified by structural analysis as recognizing the tryptophan in order to confirm their role. This work establishes the method by which flavin-dependent tryptophan halogenases regioselectively control chlorine addition to tryptophan. This method would seem to be general across the superfamily.
The gene encoding L-rhamnose isomerase (L-RhI) from Pseudomonas stutzeri was cloned into Escherichia coli and sequenced. A sequence analysis of the DNA responsible for the L-RhI gene revealed an open reading frame of 1,290 bp coding for a protein of 430 amino acid residues with a predicted molecular mass of 46,946 Da. A comparison of the deduced amino acid sequence with sequences in relevant databases indicated that no significant homology has previously been identified. An amino acid sequence alignment, however, suggested that the residues involved in the active site of L-RhI from E. coli are conserved in that from P. stutzeri. The L-RhI gene was then overexpressed in E. coli cells under the control of the T5 promoter. The recombinant clone, E. coli JM109, produced significant levels of L-RhI activity, with a specific activity of 140 U/mg and a volumetric yield of 20,000 U of soluble enzyme per liter of medium. This reflected a 20-fold increase in the volumetric yield compared to the value for the intrinsic yield. The recombinant L-RhI protein was purified to apparent homogeneity on the basis of three-step chromatography. The purified recombinant enzyme showed a single band with an estimated molecular weight of 42,000 in a sodium dodecyl sulfate-polyacrylamide gel. The overall enzymatic properties of the purified recombinant L-RhI protein were the same as those of the authentic one, as the optimal activity was measured at 60°C within a broad pH range from 5.0 to 11.0, with an optimum at pH 9.0.Unusual carbohydrates, simply termed "rare sugars," are referred to as sugars that exist in an extremely scanty amount in nature; they include,tagatose, allitol, and others. Rare sugars have been proven to be of paramount significance not only in food industries but also in pharmaceutical and nutritional industries on account of their multipurpose applications, such as their use as reducedcalorie sweeteners, inhibitors of microbial growth, bulking agents, and memory enhancers (4,(22)(23)(24)(25). Yet the unavailability and scarcity of these uncommon sugars result in their high cost and limitations in usage as starting materials or research reagents. Consequently, there has been a dearth of literature reporting on the mass production of rare sugars. In recent years, however, microbial and enzymatic reactions have become increasingly significant and have played pivotal roles in the production of unusual sugars.We are mainly working on the production and/or mass production of various kinds of rare sugars by using microorganisms screened from a variety of ecological habitats and their enzymes. For example, Pseudomonas cichorii ST-24 and Acinetobacter sp. strain DL-28, which produce D-tagatose 3-epimerase and L-ribose isomerase, respectively, were isolated from soil and utilized for the preparation of a number of uncommon sugars (1,(16)(17)(18)(19)32). In order to improve the productivity of the sugars, the enzymes were later genetically engineered (14,15,26). Furthermore, members of our laboratory recently isolated a mutant s...
Pyrrolnitrin is a commonly used and clinically effective treatment for fungal infections and provides the structural basis for the more widely used fludioxinil. The pyrrolnitrin biosynthetic pathway consists of four chemical steps, the second of which is the rearrangement of 7-chloro-tryptophan by the enzyme PrnB, a reaction that is so far unprecedented in biochemistry. When expressed in Pseudomonas fluorescens, PrnB is red in color due to the fact that it contains 1 mol of heme b per mole of protein. The crystal structure unexpectedly establishes PrnB as a member of the heme-dependent dioxygenase superfamily with significant structural but not sequence homology to the two-domain indoleamine 2,3-dioxygenase enzyme (IDO). The heme-binding domain is also structurally similar to that of tryptophan 2,3-dioxygenase (TDO). Here we report the binary complex structures of PrnB with d- and l-tryptophan and d- and l-7-chloro-tryptophan. The structures identify a common hydrophobic pocket for the indole ring but exhibit unusual heme ligation and substrate binding when compared with that observed in the TDO crystal structures. Our solution studies support the heme ligation observed in the crystal structures. Purification of the hexahistidine-tagged PrnB yields homogeneous protein that only displays in vitro activity with 7-chloro-l-tryptophan after reactivation with crude extract from the host strain, suggesting that an as yet unknown cofactor is required for activity. Mutation of the proximal heme ligand results, not surprisingly, in inactive enzyme. Redox titrations show that PrnB displays a significantly different reduction potential to that of IDO or TDO, indicating possible differences in the PrnB catalytic cycle. This is confirmed by the absence of tryptophan dioxygenase activity in PrnB, although a stable oxyferrous adduct (which is the first intermediate in the TDO/IDO catalytic cycle) can be generated. We propose that PrnB shares a key catalytic step with TDO and IDO, generation of a tryptophan hydroperoxide intermediate, although this species suffers a different fate in PrnB, leading to the eventual formation of the product, monodechloroaminopyrrolnitrin.
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