High Cell Density Cultivation Combined with high Specific Enzyme Activity: Cultivation Protocol for the Production of an Amine Transaminase from Bacillus megaterium in E. coli.

High cell density cultivation is an established method for the production of various industrially important products such as recombinant proteins. However, these protocols are not always suitable for biocatalytic processes as the focus often lies on biomass production rather than high specific activities of the enzyme inside the cells. In contrast, a range of shake flask protocols are well known with high specific activities but rather low cell densities. To overcome this gap, we established a tailor-made fed-batch protocol combining both aspects: high cell density and high specific activities of heterologously produced enzyme. Using the example of an industrially relevant amine transaminase from Bacillus megaterium, we describe a strategy to optimize the cultivation yield based on the feed rate, IPTG concentration, and post-induction temperature. By adjusting these key parameters, we were able to increase the specific activity by 2.6-fold and the wet cell weight by even 17-fold compared to shake flasks. Finally, we were able to verify our established protocol by transferring it to another experimenter. With that, our optimization strategy can serve as a template for the production of high titers of heterologously produced, active enzymes and might enable the availability of these catalysts for upscaling biocatalytic processes.

An Enzymatic 2-Step Cofactor and Co-Product Recycling Cascade towards a Chiral 1,2-Diol. Part I: Cascade Design.

Alcohol dehydrogenases are of high interest for stereoselective syntheses of chiral building blocks such as 1,2-diols. As this class of enzymes requires nicotinamide cofactors, their application in biotechnological synthesis reactions is economically only feasible with appropriate cofactor regeneration. Therefore, a co-substrate is oxidized to the respective co-product that accumulates in equal concentration to the desired target product. Co-product removal during the course of the reaction shifts the reaction towards formation of the target product and minimizes undesired side effects. Here we describe an atom efficient enzymatic cofactor regeneration system where the co-product of the ADH is recycled as a substrate in another reaction set. A 2-step enzymatic cascade consisting of a thiamine diphosphate (ThDP)-dependent carboligase and an alcohol dehydrogenase is presented here as a model reaction. In the first step benzaldehyde and acetaldehyde react to a chiral 2-hydroxy ketone, which is subsequently reduced by to a 1,2-diol. By choice of an appropriate co-substrate (here: benzyl alcohol) for the cofactor regeneration in the alcohol dehydrogenases (ADH)-catalyzed step, the co-product (here: benzaldehyde) can be used as a substrate for the carboligation step. Even without any addition of benzaldehyde in the first reaction step, this cascade design yielded 1,2-diol concentrations of >100 mM with optical purities (ee, de) of up to 99%. Moreover, this approach overcomes the low benzaldehyde solubility in aqueous systems and optimizes the atom economy of the reaction by reduced waste production. The example presented here for the 2-step recycling cascade of (1R,2R)-1-phenylpropane-1,2-diol can be applied for any set of enzymes, where the co-products of one process step serve as substrates for a coupled reaction.

Identification and characterization of an aß oligomer precipitating peptide that may be useful to explore gene therapeutic approaches to Alzheimer disease.

A key feature of Alzheimer disease (AD) is the pathologic self-association of the amyloid-ß (Aß) peptide, leading to the formation of diffusible toxic Aß oligomers and extracellular amyloid plaques. Next to extracellular Aß, intraneuronal Aß has important pathological functions in AD. Agents that specifically interfere with the oligomerization processes either outside or inside of neurons are highly desired for the elucidation of the pathologic mechanisms of AD and might even pave the way for new AD gene therapeutic approaches. Here, we characterize the Aß binding peptide L3 and its influence on Aß oligomerization in vitro. Preliminary studies in cell culture demonstrate that stably expressed L3 reduces cell toxicity of externally added Aß in neuroblastoma cells.

TTC-based screening assay for ω-transaminases: a rapid method to detect reduction of 2-hydroxy ketones.

A rapid TTC-based screening assay for ω-transaminases was developed to determine the conversion of substrates with a 2-hydroxy ketone motif. Oxidation of the compounds in the presence of 2,3,5-triphenyltetrazolium chloride (TTC) results in a reduction of the colourless TTC to a red-coloured 1,3,5-triphenylformazan. The enzymatic reductive amination of a wide range of various aliphatic, aliphatic-aromatic and aromatic-aromatic 2-hydroxy ketones can be determined by the decrease of the red colouration due to substrate consumption. The conversion can be quantified spectrophotometrically at 510 nm based on reactions, e.g. with crude cell extracts in 96-well plates. Since the assay is independent of the choice of diverse amine donors a panel of ω-transaminases was screened to detect conversion of 2-hydroxy ketones with three different amine donors: l-alanine, (S)-α-methylbenzylamine and benzylamine. The results could be validated using HPLC and GC analyses, showing a deviation of only 5-10%. Using this approach enzymes were identified demonstrating high conversions of acetoin and phenylacetylcarbinol to the corresponding amines. Among these enzymes three novel wild-type ω-transaminases have been identified.

Oral treatment with the d-enantiomeric peptide D3 improves the pathology and behavior of Alzheimer's Disease transgenic mice.

Several lines of evidence suggest that the amyloid-ß-peptide (Aß) plays a central role in the pathogenesis of Alzheimer's disease (AD). Not only Aß fibrils but also small soluble Aß oligomers in particular are suspected to be the major toxic species responsible for disease development and progression. The present study reports on in vitro and in vivo properties of the Aß targeting d-enantiomeric amino acid peptide D3. We show that next to plaque load and inflammation reduction, oral application of the peptide improved the cognitive performance of AD transgenic mice. In addition, we provide in vitro data elucidating the potential mechanism underlying the observed in vivo activity of D3. These data suggest that D3 precipitates toxic Aß species and converts them into nonamyloidogenic, nonfibrillar, and nontoxic aggregates without increasing the concentration of monomeric Aß. Thus, D3 exerts an interesting and novel mechanism of action that abolishes toxic Aß oligomers and thereby supports their decisive role in AD development and progression.

Uneven twins: comparison of two enantiocomplementary hydroxynitrile lyases with alpha/beta-hydrolase fold.

Hydroxynitrile lyases (HNLs) are applied in technical processes for the synthesis of chiral cyanohydrins. Here we describe the thorough characterization of the recently discovered R-hydroxynitrile lyase from Arabidopsis thaliana and its S-selective counterpart from Manihot esculenta (MeHNL) concerning their properties relevant for technical applications. The results are compared to available data of the structurally related S-HNL from Hevea brasiliensis (HbHNL), which is frequently applied in technical processes. Whereas substrate ranges are highly similar for all three enzymes, the stability of MeHNL with respect to higher temperature and low pH-values is superior to the other HNLs with alpha/beta-hydrolase fold. This enhanced stability is supposed to be due to the ability of MeHNL to form tetramers in solution, while HbHNL and AtHNL are dimers. The different inactivation pathways, deduced by means of circular dichroism, tryptophan fluorescence and static light scattering further support these results. Our data suggest different possibilities to stabilize MeHNL and AtHNL for technical applications: whereas the application of crude cell extracts is appropriate for MeHNL, AtHNL is stabilized by addition of polyols. In addition, the molecular reason for the inhibition of MeHNL and HbHNL by acetate could be elucidated, whereas no such inhibition was observed with AtHNL.