Daniel F. Sauer

Selective Metal-Free Hydrosilylation of CO2 Catalyzed by Triphenylborane in Highly Polar, Aprotic Solvents.

Triphenylborane (BPh3 ) in highly polar, aprotic solvents catalyzes hydrosilylation of CO2 effectively under mild conditions to provide silyl formates with high chemoselectivity (>95 %) and without over-reduction. This system also promotes reductive hydrosilylation of tertiary amides as well as dehydrogenative coupling of silane with alcohols.

Hybrid Ruthenium ROMP Catalysts Based on an Engineered Variant of β‐Barrel Protein FhuA ΔCVFtev: Effect of Spacer Length

A biohybrid ring-opening olefin metathesis polymerization catalyst based on the reengineered β-barrel protein FhuA ΔCVF(tev) was chemically modified with respect to the covalently anchored Grubbs-Hoveyda type catalyst. Shortening of the spacer (1,3-propanediyl to methylene) between the N-heterocyclic carbene ligand and the cysteine site 545 increased the ROMP activity toward a water-soluble 7-oxanorbornene derivative. The cis/trans ratio of the double bond in the polymer was influenced by the hybrid catalyst.

Metatheases: artificial metalloproteins for olefin metathesis

The incorporation of organometallic catalyst precursors in proteins results in so-called artificial metalloenzymes. The protein structure will control activity, selectivity and stability of the organometallic site in aqueous medium and allow non-natural reactions in biological settings. Grubbs-Hoveyda type ruthenium catalysts with an N-heterocyclic carbene (NHC) as ancillary ligand, known to be active in olefin metathesis, have recently been incorporated in various proteins. An overview of these artificial metalloproteins and their potential application in olefin metathesis is given.

Artificial Diels–Alderase based on the transmembrane protein FhuA

Summary Copper(I) and copper(II) complexes were covalently linked to an engineered variant of the transmembrane protein Ferric hydroxamate uptake protein component A (FhuA ΔCVFtev). Copper(I) was incorporated using an N-heterocyclic carbene (NHC) ligand equipped with a maleimide group on the side arm at the imidazole nitrogen. Copper(II) was attached by coordination to a terpyridyl ligand. The spacer length was varied in the back of the ligand framework. These biohybrid catalysts were shown to be active in the Diels–Alder reaction of a chalcone derivative with cyclopentadiene to preferentially give the endo product.

2-Methyl-2,4-pentanediol (MPD) boosts as detergent-substitute the performance of ß-barrel hybrid catalyst for phenylacetylene polymerization

Covering hydrophobic regions with stabilization agents to solubilize purified transmembrane proteins is crucial for their application in aqueous media. The small molecule 2-methyl-2,4-pentanediol (MPD) was used to stabilize the transmembrane protein Ferric hydroxamate uptake protein component A (FhuA) utilized as host for the construction of a rhodium-based biohybrid catalyst. Unlike commonly used detergents such as sodium dodecyl sulfate or polyethylene polyethyleneglycol, MPD does not form micelles in solution. Molecular dynamics simulations revealed the effect and position of stabilizing MPD molecules. The advantage of the amphiphilic MPD over micelle-forming detergents is demonstrated in the polymerization of phenylacetylene, showing a ten-fold increase in yield and increased molecular weights.

Directed OmniChange Evolution Converts P450 BM3 into an Alkyltrimethylammonium Hydroxylase

Cetyl-trimethylammonium bromide (CTAB) is a widely used cationic surfactant that is biodegradable in nature. CTAB biodegradation requires hydroxylation in the first step, which is rate-limiting and crucial for solubility in water. In this study, the OmniChange multi-site mutagenesis method was applied to reengineer the P450 BM3 substrate specificity towards the hydroxylation of CTAB by simultaneous mutagenesis of four previously reported positions (R47, Y51, F87, and L188). 1740 clones from the P450 BM3 OmniChange library were screened with the NADPH depletion assay. A total of 696 clones were rescreened with the NADPH depletion and an Ampliflu™ Red/ horseradish peroxidase based H2 O2 detection assay. Several improved P450 BM3 variants were identified and finally four were kinetically characterized with respect to CTAB hydroxylation, based on both performance and coupling efficiency. Based on NADPH consumption, the P450 BM3 variant P3A8 (R47E/Y51M/F87V/L188E) displayed an initial activity (64.9±4.8 s-1 , 13.5-fold increased activity compared with wild-type P450 BM3), which nearly matches the specific activity for its natural fatty acid substrate (palmitic acid (32-122 s-1 )). Variant P3A8 showed high coupling efficiency (92.5 %), whereas wild-type P450 BM3 displayed a low coupling efficiency (0.5 %). HPLC-MS/MS detection confirmed that P3A8 and P2E7 (R47D/Y51L/F87V/L188A) form 13 and 35 times more 2-hydroxylated CTAB than P450 BM3. In addition, di-hydroxylated CTAB products were detected for all four investigated P450 BM3 variants (up to a yield of 77 %; P3A8). Di-hydroxylated quaternary amines are highly interesting bolaform surfactants with a high hydrophilicity (surface contact angle: θ=16.7°).

CHAPTER 3:Channel Protein FhuA as a Promising Biomolecular Scaffold for Bioconjugates

The ferric hydroxamate uptake protein component A, FhuA, is a large monomeric transmembrane protein. FhuA functions as a receptor for ferrichrome and the structurally closely related antibiotic albomycin. In addition to its biological importance, FhuA is a robust protein scaffold that can be genetically modified and is stable under a broad range of conditions. By removing the globular cork domain (deletion of amino acids 1–160), FhuA became a large passive diffusion channel (FhuA Δ1–160) with an inner diameter of about 2.0 nm. FhuA was reconstituted in liposomes and polymersomes for controlled compound release responding to reducing agents and UV light. FhuA was also re-engineered to increase its length, enlarge its diameter and harbour single functional groups (–SH and –NH2). FhuA Δ1–159 Ext with an increased hydrophobic region was generated and inserted more efficiently into polymer membranes. FhuA Δ1–159 Exp has an enlarged diameter and shows increased diffusion kinetics. The remarkable resistance of FhuA variants to organic solvents and high temperatures makes it suitable as a scaffold for accommodating hybrid catalysts to perform chemical reactions. By substituting the amino acid residues surrounding the coupling site in the interior of the FhuA channel, one can also optimize the accessibility of the coupling site and the enantioselectivity.