Browsing by Author "Schmid, Rolf D."

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Open Access
Biocatalysts for the epoxidation and hydroxylation of fatty acids and fatty alcohols
(2005) Maurer, Steffen Christian; Schmid, Rolf D.
Whereas most products of the chemical industry are based on petrochemical feedstocks, considerable efforts have been made during the past few decades to use renewable resources as industrial raw materials. Besides polysaccharides and sugars, plant oils and animal fats play an important role in such programmes because of their ready availability (present production is >100 million t/a, which could be increased on demand) of which the lion’s share is used for nutrition (~85 million t/a), whereas ~ 15 – 20 million t/a are used for the synthesis of polymers, surfactants, emollients, lubricants, bio-diesel, emulsifiers, etc.). From a chemical point of view, most natural triglycerides offer just two reactive sites, the ester group and the double bonds of unsaturated fatty acids. In fact, the chemistry of fats and oils is largely focused on the ester group which can be hydrolyzed or catalytically reduced, leading to glycerol and fatty acids or fatty alcohols, respectively. Reactions involving the alkyl chain or double bonds of triglycerides, fatty acids, fatty alcohols or their derivatives represent far less than 10% of today’s oleochemistry, with the production of sulfonated fatty alcohols and their derivatives being a major process of this kind. Oxidation reactions at the alkyl or alkenyl chains would be highly desirable as they would lead to oleochemicals with new properties, but the methods available today lack selectivity and require harsh conditions. Notable exceptions are the epoxidation of unsaturated plant oils and the synthesis and use of a few hydroxy fatty acids.
Open Access
Biotransformation of ionones by engineered cytochrome P450 BM-3
(2005) Urlacher, Vlada B.; Makhsumkhanov, Akhmadjan; Schmid, Rolf D.
Wild type cytochrome P450 monooxygenase from Bacillus megaterium (P450 BM-3) has low activity for the hydroxylation of beta-ionone (>1 min-1). Substitution of phenylalanine by valine at position 87 increased the beta-ionone hydroxylation activity up to 100-fold (115 min-1). For further activity improvement methods of site-directed and random mutagenesis were applied. The R47L Y51F F87V mutant, designed by site-directed mutagenesis and the A74E F87V P386S mutant, obtained after two rounds of error-prone PCR, exhibit an increase in activity up to 300-fold compared to the wild type enzyme. All mutants converted -ionone regioselectively to 4-hydroxy-beta-ionone.
Open Access
Biotransformations using prokaryotic P450 monooxygenases
(2002) Urlacher, Vlada B.; Schmid, Rolf D.
Recent studies on microbial cytochrome P450 enzymes cover several new areas. Advances have been made in structure-function analysis. New non-enzymatic/electrochemical systems for the replacement of NAD(P)H have been developed. The properties of some enzymes have been re-engineered by site-directed mutagenesis or by methods of directed evolution. New P450s have been functionally expressed and characterized. A combination of these approaches is believed to facilitate the use of isolated P450 monooxygenases in biocatalysis.
Open Access
Blocking the tunnel: engineering of Candida rugosa lipase mutants with short chain length specificity
(2002) Schmitt, Jutta; Brocca, Stefania; Schmid, Rolf D.; Pleiss, Jürgen
The molecular basis of chain length specificity of Candida rugosa lipase 1 was investigated by molecular modelling and site-directed mutagenesis. The synthetic lip1 gene and the lipase mutants were expressed in Pichia pastoris and assayed for their chain length specificity in single substrate assays using triglycerides as well as in a competitive substrate assay using a randomized oil. Mutation of amino acids at different locations inside the tunnel (P246F, L413F, L410W, L410F/S300E, L410F/S365L) resulted in mutants with a different chain length specificity. Mutants P246F and L413F have a strong preference for short chain lengths whereas substrates longer than C10 are hardly hydrolyzed. Increasing the bulkiness of the amino acid at position 410 led to mutants that show a strong discrimination of chain lengths longer than C14. The results obtained can be explained by a simple mechanical model: the activity for a fatty acid sharply decreases as it becomes long enough to reach the mutated site. In contrast, a mutation at the entrance of the tunnel (L304F) has a strong impact on C4 and C6 substrates. This mutant is nevertheless capable to hydrolyze chain lengths longer than C8.
Open Access
Catalytic hydroxylation in biphasic systems using CYP102A1 mutants
(2005) Maurer, Steffen Christian; Kühnel, Katja; Kaysser, Leonard A.; Eiben, Sabine; Schmid, Rolf D.; Urlacher, Vlada B.
Cytochrome P450 monooxygenases are biocatalysts that hydroxylate or epoxidise a wide range of hydrophobic organic substrates. To date their technical application is limited to a small number of whole-cell biooxidations. The use of the isolated enzymes is believed to be impractical due to the low stability of this enzyme class, to the stochiometric need of the expensive cofactor NADPH, and due to the low solubility of most substrates in aqueous media. To overcome these problems we have investigated the application of a bacterial monooxygenase (mutants of CYP102A1) in a biphasic reaction system supported by cofactor recycling with NADP+-dependent formate dehydrogenase from Pseudomonas sp 101. Using this experimental setup, cyclohexane, octane and myristic acid were hydroxylated. To reduce the process costs a novel NADH-dependent double mutant of CYP102A1 was designed. For recycling of NADH during myristic acid hydroxylation in a biphasic system NAD+-dependent FDH was used. Stability of the monooxygenase under the reaction conditions is quite high as revealed by total turnover numbers of up to 12850 in NADPH-dependent cyclohexane hydroxylation and up to 30000 in NADH-dependent myristic acid oxidation.
Open Access
Cloning, expression and characterisation of CYP102A2, a self-sufficient P450 monooxygenase from Bacillus subtilis
(2004) Budde, Michael; Maurer, Steffen Christian; Schmid, Rolf D.; Urlacher, Vlada B.
The gene encoding CYP102A2, a novel P450 monooxygenase from Bacillus subtilis, was cloned and expressed in Escherichia coli. The recombinant enzyme formed was purified by immobilised metal chelat affinity chromatography (IMAC) and characterised. CYP102A2 is a 119 kDa self-sufficient monooxygenase, consisting of an FMN/FAD–containing reductase domain and a heme domain. The deduced amino acid sequence of CYP102A2 exhibits a high level of identity with the amino acid sequences of CYP102A1 from Bacillus megaterium (59%) and CYP102A3 from Bacillus subtilis (60%). In reduced, CO-bound form, the enzyme shows a typical Soret band at 450 nm. It catalyses the oxidation of even- and odd-chain saturated and unsaturated fatty acids. In all reactions investigated, the products were the respective ù-3, ù-2 and ù-1 hydroxylated fatty acids. Activity was highest towards oleic and linoleic acid (KM=17.4 ± 1.4 ìM, kcat= 2244 ± 72 min-1), linoleic acid (KM=12.25 ± 1.8 ìM, kcat= 1950 ± 84 min-1). Comparison of CYP102A2 homology model to CYP102A1 crystal structure revealed significant differences in the substrate access channels, which might explain the differences in catalytic properties of these two enzymes.
Open Access
Cloning, expression, and characterization of a self-sufficient cytochrome P450 monooxygenase from Rhodococcus ruber DSM 44319
(2006) Liu, Luo; Schmid, Rolf D.; Urlacher, Vlada B.
A new member of class IV of cytochrome P450 monooxygenases was identified in Rhodococcus ruber strain DSM 44319. As the genome of Rhodococcus ruber has not been sequenced, a P450-like gene fragment was amplified using degenerated primers. The flanking regions of the P450-like DNA fragment were identified by directional genome walking using PCR. The primary protein structure suggests a natural self-sufficient fusion protein consisting of a ferredoxin, flavin-containing reductase and P450 monooxygenase. The only flavin found within the enzyme was FMN. The enzyme was successfully expressed in Escherichia coli and purified and characterized. In the presence of NADPH, the P450 monooxygenase showed hydroxylation activity towards polycyclic aromatic hydrocarbons naphthalene, indene, acenaphthene, toluene, fluorene, m-xylene and ethyl benzene. The conversion of naphthalene, acenaphthene and fluorene resulted in respective ring monohydroxylated metabolites. Alkyl aromatics like toluene, m-xylene and ethyl benzene were hydroxylated exclusively at the side chains. The new enzyme’s ability to oxidize such compounds makes it a potential candidate for biodegradation of pollutants and an attractive biocatalyst for synthesis.
Open Access
A comparative study of extraction and purification methods for environmental DNA from soil and sludge samples
(2006) Roh, Changhyun; Villatte, Francois; Kim, Byung-Gee; Schmid, Rolf D.
An important prerequisite for a successful metagenome library construction is an efficient extraction procedure for DNA out of environmental samples. In this study we compared three indirect and four direct extraction methods, including a commercial kit, in terms of DNA yield, purity and time requirement. A special focus was set on methods which are appropriate for the extraction of environmental DNA (eDNA) from very limited sample sizes (0.1 g) to enable a highly parallel approach. Direct extraction procedures yielded on average 100-fold higher DNA amounts than indirect ones. A drawback of direct extraction was the small fragment size of appr. 12 kb. The quality of the extracted DNA was evaluated by the ability of different restriction enzymes to digest the environmental DNA. Only the commercial kit and a direct extraction method using freeze-thaw cell lysis in combination with an in gel patch electrophoresis with hydroxyapatite to remove humic acid substances yielded DNA, which was completely digested by all restriction enzymes. Moreover, only DNA extracted by these two procedures could be used as template for the amplification of fragments of several 16S rDNA, 18S rDNA groups under standard PCR conditions.
Open Access
The database of epoxide hydrolases and haloalkane dehalogenases: one structure, many functions
(2004) Barth, Sandra; Fischer, Markus; Schmid, Rolf D.; Pleiss, Jürgen
The epoxide hydrolases and haloalkane dehalogenase database (EH/HD) integrates sequence and structure of a highly diverse protein family including mainly the Asp-hydrolases of EHs and HDs but also proteins like the Ser-hydrolases non-heme peroxidases, prolyl iminopetidases or 2-hydroxymuconic semialdehyde hydrolases. These proteins have a highly conserved structure, but display a remarkable diversity in sequence and function. 305 protein entries were assigned to 14 homologous families, forming two superfamilies. Annotated multisequence alignments and phylogenetic trees are provided for each homologous family and superfamily. Experimentally derived structures of 19 proteins are superposed and consistently annotated. Sequence and structure of all 305 proteins were systematically analysed. Thus, deeper insight is gained into the role of a highly conserved sequence motifs and structural elements. The EH/HD database is available at http://www.led.uni-stuttgart.de.
Open Access
Design of acetylcholinesterases for biosensor applications
(2003) Schulze, Holger; Vorlová, Sandra; Villatte, Francois; Bachmann, Till T.; Schmid, Rolf D.
In recent years, the use of acetylcholinesterases (AChEs) in biosensor technology has gained enormous attention, in particular with respect to insecticide detection. The principle of biosensors using AChE as a biological recognition element is based on the inhibition of the enzyme’s natural catalytic activity by the agent that is to be detected. The advanced understanding of the structure-function-relationship of AChEs serves as the basis for developing enzyme variants, which, compared to the wild type, show an increased inhibition efficiency at low insecticide concentrations and thus a higher sensitivity. This review describes different expression systems that have been used for the production of recombinant AChE. In addition, approaches to purify recombinant AChEs to a degree that is suitable for analytical applications will be elucidated as well as the various attempts that have been undertaken to increase the sensitivity of AChE to specified organophosphates and carbamates using side-directed mutagenesis and employing the enzyme in different assay formats.
Open Access
Development, validation, and application of an acetylcholinesterase-biosensor test for the direct detection of insecticide residues in infant food
(2002) Schulze, Holger; Scherbaum, Ellen; Anastassiades, Michelangelo; Vorlová, Sandra; Schmid, Rolf D.; Bachmann, Till T.
A highly sensitive and rapid food-screening test based on disposable screen-printed biosensors was developed, which is suitable for monitoring infant food. The exposure of infants and children to neurotoxic organophosphates and carbamates is of particular concern because of their higher susceptibility to adverse effects. The European Union has therefore set a very low limit for pesticides in infant food which must not contain concentrations exceeding 10 μg/kg for any given pesticide. The maximum residue limit (MRL) has been set to be near the determination threshold that is typically achieved for pesticides with traditional analytical methods. The biosensor method could detect levels lower than 5 μg/kg and thus clearly fulfills the demands of the EU. To substantiate these measurements, recovery rates were determined and amounted on average to 104 % in food. Matrix effects were eliminated by the introduction of a special electrode treatment. The test was compared with two traditional pesticide multiresidue analysis methods (GC/MS, LC/MS) using 26 fruit and vegetable samples from local markets and 23 samples of processed infant food from Germany, Spain, Poland and the USA. Three infant food samples exceeded the MRL of 10 μg/kg when analyzed by either biosensor test or multiresidue methods.
Open Access
Directed evolution of a bacterial alpha-amylase : towards enhanced pH-performance and higher specific activity
(2003) Bessler, Cornelius; Schmitt, Jutta; Maurer, Karl-Heinz; Schmid, Rolf D.
Alpha-Amylases, in particular, microbial Alpha-amylases are used widely in industrial processes such as starch liquefaction and pulp processes and more recently in detergency. Following the need for Alpha-amylases adapted to latter, we enhanced the alkali-activity of the Alpha-amylase from Bacillus amyloliquefaciens (BAA). The genes coding for the wild type BAA and the mutants BAA S201N and BAA N297D were subjected to error prone PCR and gene shuffling. For the screening of mutants we developed a novel, reliable assay suitable for high throughput screening based on the Phadebas® assay. One mutant (BAA 42) has an optimal activity at pH 7, corresponding to a shift of one pH unit compared to the wild type. BAA 42 is active over a broader pH-range than the wild type resulting in a fivefold higher activity at pH 10. In addition, the activity in periplasmic extracts and the specific activity increased 4 and 1.5 fold, respectively. Another mutant (BAA 29) possesses a wild type like pH-profile but reveals a 40-fold higher activity in periplasmic extracts and a nine fold higher specific activity. The comparison of the amino acid sequences of these two mutants with other homologous microbial Alpha-amylases revealed the mutation of the highly conserved residues W194R, S197P and A230V. In addition, three further mutations were found K406R, N414S and E356D, the latter being present in other bacterial Alpha-amylases.
Open Access
DNA isolation from soil samples for cloning in different hosts
(2004) Kauffmann, Isabelle Melanie; Schmitt, Jutta; Schmid, Rolf D.
Many protocols to extract DNA directly from soil samples have been developed in recent years. We employed two extraction methods which differed in the method of lysis and compared these methods with respect to yield, purity and degree of shearing. The main focus was on the specific isolation of DNA from different microorganisms, especially DNA from actinomycetes, as these cells are very difficult to lyse in contrast to non-actinomycetes. Thus, we used both methods to isolate DNA from Pseudomonas (Entcheva et al. 2001), Arthrobacter and Rhodococcus (Borneman et al. 1996) and from soil spiked with the respective microorganisms. Both methods rendered high DNA yields with a low degree of shearing but differed in the type of cells that were lysed. By one protocol (utilizing enzymatic lysis) only DNA from the Gram-negative Pseudomonas strain could be obtained whereas by the other protocol (utilizing mechanical lysis), all microorganisms that were used could be lysed and DNA from them extracted. Using a combination of both protocols, DNA from those organisms could be obtained selectively. Furthermore, one of the protocols was modified, resulting in higher DNA yield and purity.
Open Access
High-yield expression of the recombinant, atrazine-specific Fab fragment K411B by the methylotrophic yeast Pichia pastoris
(2001) Lange, Stefan; Schmitt, Jutta; Schmid, Rolf D.
In this report, we describe the high-yield secretory expression (~ 40 mg l-1) of pure, atrazine-specific Fab fragments (K411B) from P. pastoris that was achieved by co-integration of the genes encoding the heavy and light chains (both under the control of the alcohol oxidase promoter) into the genome of the yeast cells. Antibody-expressing clones were selected by SDS-PAGE and ELISA and fed-batch fermentations were carried out in a 5 l scale. Both chains of the Fab were successfully expressed upon methanol induction and almost no other proteins were secreted into the media. Approximately 30 % of the two chains formed the active Fab fragment containing the intermolecular disulphide bond, as determined by Western blot analysis under non-reducing conditions. Crude culture supernatant was used to study the binding properties of the Fab fragment toward different s-triazines by means of competitive ELISA: the IC50 value for the detection of atrazine was determined from the standard curve as 3 µg l-1, which is one magnitude higher than the value obtained with the parental mAb K4E7 but equals that obtained when the same Fab fragment was expressed in E. coli cells. In addition, the cross-reactivity pattern of the Fab from Pichia is comparable to that of E. coli and the parental mAb K4E7.
Open Access
Identification of factors impeding the production of a single-chain antibody fragment in Escherichia coli by comparing in vivo and in vitro expression
(2003) Ölschläger, Peter; Lange, Stefan; Schmitt, Jutta; Siemann-Herzberg, Martin; Reuss, Matthias; Schmid, Rolf D.
In order to produce the atrazine-specific scFv K411B, it was expressed in either the cytoplasm or the periplasm of Escherichia coli BL21(DE3). For periplasmic production, the scFv was N-terminally fused to the pelB leader, whereas the unfused variant resulted in cytoplasmic expression. The extent of protein accumulation differed significantly: The expression level of the scFv with leader was 2.3 times higher than that of the protein without leader. To further investigate this, the respective translation profiles were generated by coupled in vitro transcription/translation assays and gave according results. Periplasmic expression resulted in only 10% correctly folded scFv. The same percentage was obtained when the scFv was expressed in vitro, indicating that the oxidizing environment of the periplasm did not increase proper folding. Thus, the data obtained in vitro confirmed the findings observed in vivo and suggested that the discrepancy in expression levels was due to different translation efficiencies. However, the in vivo production of the scFv with EGFP fused C-terminally (scFv-EGFP) was only successful in the cytoplasm, although in vitro the expression with and without the leader rendered the same production profile. This indicated that neither the translation efficiency nor the solubility but other factors impeded periplasmic expression of the fusion protein.
Open Access
Immobilisation of P450 BM-3 and an NADP+ cofactor recycling system : towards a technical application of heme-containing monooxygenases in fine chemical synthesis
(2003) Maurer, Steffen Christian; Schulze, Holger; Schmid, Rolf D.; Urlacher, Vlada B.
Cytochrome P450 monooxygenases are potentially a very useful class of hydroxylation catalysts; they are able to introduce oxygen at activated and non-activated carbon-hydrogen bonds and thus lead to regio- and/or stereochemically pure compounds. However, this potential is lowered by their intrinsic low activity and inherent instability. P450-catalysed biotransformations require a constant supply of NAD(P)H, making the process an expensive one. To render these catalysts more suitable for industrial biocatalysis, the immobilisation of P450 BM-3 (CYP 102A1) from Bacillus megaterium in a sol-gel matrix was combined with a cofactor recycling system based on NADPƒy-dependent formate dehydrogenase (EC 1.2.1.2) from Pseudomonas sp. 101 and tested for practical applicability. This approach was used for the conversion of £]-ionone, octane and naphthalene to the respective hydroxy-compounds with DMSO as cosolvent using sol-gel immobilised P450 BM-3 mutants.
Open Access
"In gel patch electrophoresis" : a new method for environmental DNA purification
(2005) Roh, Changhyun; Villatte, Francois; Kim, Byung-Gee; Schmid, Rolf D.
Most of the microorganism species are largely untapped and could represent an interesting reservoir of genes useful for biotechnological applications. Unfortunately, a major difficulty associated with the methods used to isolate environmental DNA is related to the contamination of the extracted material with humic substances. These polyphenolic compounds inhibit the DNA processing reactions and severely impede cloning procedures. In this work, we describe a rapid, simple and efficient method for the purification of genomic DNA from environmental samples: we added a chromatography step directly embedded into an agarose gel electrophoresis. This strategy enabled the DNA extraction from various environmental samples and it appeared that the purity grade was compatible with digestion by restriction enzymes and PCR amplifications.
Open Access
Insight into the mechanism of the IMP-1 metallo-beta-lactamase by molecular dynamics simulations
(2003) Ölschläger, Peter; Schmid, Rolf D.; Pleiss, Jürgen
Two models, a purely nonbonded model and a cationic dummy atom approach, were examined for the modeling of the binuclear zinc-containing IMP-1 metallo-beta-lactamase in complex with a mercaptocarboxylate inhibitor. The cationic dummy atom approach had substantial advantages as it maintained the initial, experimentally determined geometry of the metal-containing active site during molecular dynamics simulations in water. The method was extended to the modeling of the free enzyme and the enzyme in complex with a cephalosporin substrate docked in an intermediate structure. For all three systems, the modeled complexes and the tetrahedral coordination of the zinc ions were stable. The average zinc-zinc distance increased by about 1 Å in the substrate complex compared to the inhibitor complex and the free enzyme in which a hydroxide ion acts as a bridging ligand. Thus, the zinc ions are predicted to undergo a back and forth movement upon the cycle of hydrolysis. In contrast to previous assumptions, no interaction of the Asn167 side chain with the bound cephalosporin substrate was observed. Our observations are in agreement with quantum-mechanical calculations and experimental data and indicate that the cationic dummy atom approach is useful to model zinc-containing metallo-beta-lactamases as free proteins, in complex with inhibitors and in complex with substrates.
Open Access
Microbial P450 enzymes in biotechnology
(2004) Urlacher, Vlada B.; Lutz-Wahl, Sabine; Schmid, Rolf D.
Oxidations are key reactions in chemical syntheses. Biooxidations using fermentation processes have already conquered some niches in industrial oxidation processes, since they allow the introduction of oxygen even into non-activated carbon atoms in a sterically and optically selective manner which is difficult or impossible to achieve by synthetic organic chemistry. Biooxidation using isolated enzymes is limited to oxidases and dehydrogenases. Surprisingly, cytochrome P450 monooxygenases (CYPs) have scarcely been studied for use in biooxidations, although they are one of the largest known superfamilies of enzyme proteins. Their gene sequences have been identified in various organisms such as humans, bacteria, algae, fungi and plants. The reactions catalyzed by P450s are quite diverse and range from biosynthetic pathways (e.g. those of animal hormones and secondary plant metabolites) to the activation or biodegradation of hydrophobic xenobiotic compounds (e. g. those of various drugs in the liver of higher animals). From a practical point of view, the great potential of P450s is limited by their functional complexity, low activity, and limited stability. In addition, P450-catalyzed reactions require a constant supply of NAD(P)H which makes continuous cell-free processes very expensive. Quite recently, several groups have started to investigate cost-efficient ways which could allow the continuous supply of electrons to the heme iron. These include, for example, the use of electron mediators, direct electron supply from electrodes and enzymatic approaches. In addition, methods of protein design and directed evolution have been applied in an attempt to enhance the activity of the enzymes and improve their selectivity. The promising application of bacterial P450s as catalyzing agents in biocatalytic reactions and recent progress made in this field are covered in this review.
Open Access
A model of the pressure dependence of the enantioselectivity of Candida rugosa lipase towards (±)-menthol
(2001) Kahlow, Ulrich; Schmid, Rolf D.; Pleiss, Jürgen
Transesterification of (±)-menthol using propionic acid anhydride and Candida rugosa lipase was performed in chloroform and water at different pressures (1, 10, 50, and 100 bar) to study the pressure dependence of enantioselectivity E. As a result, E significantly decreased with increasing pressure from E=55 (1 bar) to E=47 (10 bar), E=37 (50 bar), and E=9 (100 bar). In order to rationalize the experimental findings, molecular dynamics simulations of Candida rugosa lipase were carried out. Analyzing the lipase geometry at 1, 10, 50, and 100 bar revealed a cavity in the Candida rugosa lipase. The cavity leads from a position on the surface distinct from the substrate binding site to the core towards the active site and is limited by F415 and the catalytic H449. In the crystal structure of the Candida rugosa lipase, this cavity is filled with 6 water molecules. The number of water molecules in this cavity gradually increased with increasing pressure: 6 molecules in the simulation at 1 bar, 10 molecules at 10 bar, 12 molecules at 50 bar, and 13 molecules at 100 bar. Likewise, the volume of the cavity progressively increased from about 1864 Å³ in the simulation at 1 bar to 2529 Å³ at 10 bar, 2526 Å³ at 50 bar, and 2617 Å³ at 100 bar. At 100 bar, one water molecule slipped between F415 and H449, displacing the catalytic histidine side chain and thus opening the cavity to form a continuous water channel. The rotation of the side chain leads to a decreased distance between the H449-N and the (+)-menthyl-oxygen (non-preferred enantiomer) in the acyl enzyme intermediate, a factor determining the enantioselectivity of the lipase. While the geometry of the preferred enantiomer is similar in all simulations, the geometry of the non-preferred enantiomer gets gradually more reactive. This observation correlates with the gradually decreasing enantioselectivity E.