Enzymatic Late-Stage Halogenation of Peptides.

The late-stage site-selective derivatisation of peptides has many potential applications in structure-activity relationship studies and postsynthetic modification or conjugation of bioactive compounds. The development of orthogonal methods for C-H functionalisation is crucial for such peptide derivatisation. Among them, biocatalytic methods are increasingly attracting attention. Tryptophan halogenases emerged as valuable catalysts to functionalise tryptophan (Trp), while direct enzyme-catalysed halogenation of synthetic peptides is yet unprecedented. Here, it is reported that the Trp 6-halogenase Thal accepts a wide range of amides and peptides containing a Trp moiety. Increasing the sequence length and reaction optimisation made bromination of pentapeptides feasible with good turnovers and a broad sequence scope, while regioselectivity turned out to be sequence dependent. Comparison of X-ray single crystal structures of Thal in complex with d-Trp and a dipeptide revealed a significantly altered binding mode for the peptide. The viability of this bioorthogonal approach was exemplified by halogenation of a cyclic RGD peptide.

Metabolic engineering of Corynebacterium glutamicum for the fermentative production of halogenated tryptophan.

Halogenated compounds, like 7-chloro-l-tryptophan, are important intermediates or components of bioactive substances relevant for the pharmaceutical, chemical and agrochemical industries. About 20% of all pharmaceutical small molecule drugs and around 30% of all active compounds in agrochemistry are halogenated. Chemical halogenation procedures usually are characterized by the use of hazardous or even highly toxic chemicals. Recently, a biocatalytic process for l-tryptophan halogenation at the gram-scale using FAD-dependent halogenase and NADH-dependent flavin reductase enzymes has been described. Many proteinogenic amino acids are produced by fermentation using Corynebacterium glutamicum. The fermentative production of l-glutamate and l-lysine, for example, is operated at the million-ton scale. However, fermentative production of halogenated amino acids has not yet been described. In this study, fermentative production of the halogenated amino acid 7-chloro-l-tryptophan from sugars, ammonium and chloride salts was achieved. This required metabolic engineering of an l-tryptophan producing C. glutamicum strain for expression of the genes coding for FAD-dependent halogenase RebH and NADH-dependent flavin reductase RebF from Lechevalieria aerocolonigenes. Chlorination of l-tryptophan to 7-chloro-l-tryptophan by recombinant C. glutamicum was improved by optimizing the RBS of rebH. Metabolic engineering enabled production of 7-chloro-l-tryptophan and l-tryptophan from the alternative carbon sources arabinose, glucosamine and xylose.

Structure-based switch of regioselectivity in the flavin-dependent tryptophan 6-halogenase Thal.

Flavin-dependent halogenases increasingly attract attention as biocatalysts in organic synthesis, facilitating environmentally friendly halogenation strategies that require only FADH2, oxygen, and halide salts. Different flavin-dependent tryptophan halogenases regioselectively chlorinate or brominate trypto-phan's indole moiety at C5, C6, or C7. Here, we present the first substrate-bound structure of a tryptophan 6-halogenase, namely Thal, also known as ThdH, from the bacterium Streptomyces albogriseolus at 2.55 Šresolution. The structure revealed that the C6 of tryptophan is positioned next to the ϵ-amino group of a conserved lysine, confirming the hypothesis that proximity to the catalytic residue determines the site of electrophilic aromatic substitution. Although Thal is more similar in sequence and structure to the tryptophan 7-halogenase RebH than to the tryptophan 5-halogenase PyrH, the indole binding pose in the Thal active site more closely resembled that of PyrH than that of RebH. The difference in indole orientation between Thal and RebH appeared to be largely governed by residues positioning the Trp backbone atoms. The sequences of Thal and RebH lining the substrate binding site differ in only few residues. Therefore, we exchanged five amino acids in the Thal active site with the corresponding counterparts in RebH, generating the quintuple variant Thal-RebH5. Overall conversion of l-Trp by the Thal-RebH5 variant resembled that of WT Thal, but its regioselectivity of chlorination and bromination was almost completely switched from C6 to C7 as in RebH. We conclude that structure-based protein engineering with targeted substitution of a few residues is an efficient approach to tailoring flavin-dependent halogenases.

Anti-Markovnikov alkene oxidation by metal-oxo-mediated enzyme catalysis.

Catalytic anti-Markovnikov oxidation of alkene feedstocks could simplify synthetic routes to many important molecules and solve a long-standing challenge in chemistry. Here we report the engineering of a cytochrome P450 enzyme by directed evolution to catalyze metal-oxo-mediated anti-Markovnikov oxidation of styrenes with high efficiency. The enzyme uses dioxygen as the terminal oxidant and achieves selectivity for anti-Markovnikov oxidation over the kinetically favored alkene epoxidation by trapping high-energy intermediates and catalyzing an oxo transfer, including an enantioselective 1,2-hydride migration. The anti-Markovnikov oxygenase can be combined with other catalysts in synthetic metabolic pathways to access a variety of challenging anti-Markovnikov functionalization reactions.

A High-Throughput Fluorescence Assay to Determine the Activity of Tryptophan Halogenases.

Biocatalytic halogenation with tryptophan halogenases is hampered by severe limitations such as low activity and stability. These drawbacks can be overcome by directed evolution, but for screening large mutant libraries, a facile high-throughput method is required. Therefore, we developed a quantitative halogenase assay based on a Suzuki-Miyaura cross-coupling towards the formation of a fluorescent aryltryptophan. The technique was optimized for application in crude E. coli lysate without intermediary purification steps, and was used for quantitatively monitoring the formation of halogenated tryptophans with high specificity by facile fluorescence screening in microtiter plates. This novel screening approach was exploited to engineer a thermostable tryptophan 6-halogenase. Libraries were constructed by error-prone PCR and selected for improved thermal resistance simply by fluorogenic cross-coupling. Our method led to an enzyme variant with substantially increased thermal stability and 2.5-fold improved activity.