Artificial plant cell walls as multi-catalyst systems for enzymatic cooperative asymmetric catalysis in non-aqueous media

The assembly of cellulose-based artificial plant cell wall (APCW) structures that contain diﬀerent types of catalysts is a powerful strategy for the development of cascade reactions. Here we disclose an APCW catalytic system containing a lipase enzyme and nanopalladium particles that transform a racemic amine into the corresponding enantiomerically pure amide in high yield via a dynamic kinetic resolution.

The main structural building block of the plant cell wall is cellulose, 1,2 which forms interwoven microfibril networks that are embedded into a polysaccharide and protein matrix to constitute a multilayer architecture (Fig. S1, ESI †).
Advances in biocatalysis are a requirement for addressing the increasing need for sustainable chemistry in the preparation of materials, fine-chemicals and pharmaceutical synthesis. 3The ability of biocatalysts to operate under unnatural conditions (e.g. in non-aqueous media and at high temperatures), [4][5][6] and to catalyze non-natural chemical reactions are important factors for future advancements of the ''enzyme universe''. 7To date, the primary strategy for obtaining biocatalyst stability in nonaqueous media is through immobilization within, or on the surface of, solid supports such as silica or fossil-based polymer resins. 8However, often increased stability leads to decrease in biocatalyst activity.Thus, there is a significant incentive for developing new (bio)technologies for the advancement of nonaqueous industrial biocatalysis.The development of homogeneous and heterogeneous multi-catalytic systems for cooperatively advancing chemical transformations by combining different types of catalysts (e.g.metal, enzyme or metal-free) 9 is another elegant way of expanding chemical synthesis and biocatalysis.
1][12][13][14][15][16][17][18][19][20][21] Here the state-of-the-art involves directed evolution and/or introducing a transition metal into the enzyme.In the latter approach, the metal of a heme enzyme may be replaced by a transition metal [16][17][18] or a transition metal may be introduced into the active site of the enzyme.10a,19,20 The development of heterogeneous artificial metalloenzyme systems based on dual enzyme/metal nanocatalysis was also recently disclosed. 21However, partial deactivation of the enzyme component led to a limited recycling of the artificial metalloenzyme.][24] To address this problem, we have focused on a multidisciplinary approach for the advancement of non-aqueous biocatalysis, 8,25 which is based on a synergistically combined platform of cellulose chemistry, nanocatalysis, and heterogeneous catalysis.Based on our research on cooperative heterogeneous catalysis 21,22,[26][27][28] and construction/application of functional cellulose-based materials, 29,30 we envisioned a novel approach for setting up nature-inspired catalyst systems that are guided by the intriguing assembly of the primary cell wall 1,31 of plants.Specifically, self-assembled mixtures of cellulose, polysaccharides, enzymes, surfactants and metals can create an artificial plant cell wall (APCW)-like structure with an embedded multi catalyst system (1), which next could catalyze the stereoselective formation of product D from substrates A + B + C in non-aqueous media (Fig. 1).Herein, we disclose this concept by creation of an assembled PCW mimic, which is employed as a heterogeneous catalyst and a ''deracemase'' system for converting racemic mixtures of amines 2 to the corresponding chiral amides (R)-3 by dynamic kinetic resolution (DKR). 32,33e began our search for catalytically active and synthetically useful APCW catalyst systems by a thorough study of the kinetic resolution of racemic amine 2a using Candida antarctica Lipase B (CALB) as the enzyme of choice (Table S1 and Fig. S2, ESI †).
The assembly of various APCWs containing this serine hydrolase revealed a significant enhancement in activity of the enzyme by the different self-assembled polysaccharide-based systems.In fact, CALB is nearly inactive without some type of activation.We also investigated the role of all components used when the APCW contained microcrystalline cellulose (MCC) as the component.The use of cellulose as a support material led to a significant activation as compared to just the use of CALB.Thus, the cellulose immobilization improved the performance of the enzyme in the organic solvent.This is a beneficial effect of immobilization. 34The use of buffer 35 within the assembled network was also beneficial but is not necessary.7][38][39][40] The best self-assembly combination turned out to be non-covalent modification of CALB with surfactant polyethylene glycol hexadecyl ether (Brij) in phosphate buffer together with MCC forming APCW system 3 (APCW3). 41We also successfully created assembled APCWs containing nanofibrillated cellulose (NFC, APCW5), chitosan (APCW6) and nanocrystalline cellulose (CNC, APCW7), respectively.However, in the latter cases (APCW5-7) the E-value (enantiomeric ratio) 42 for 2a was lower than that obtained when MCC was used as the polysaccharide component.We next decided to further explore APCWs containing aminopropylsilane modified MCC (MCC-Amp) and Pd(0) nanoparticles (MCC-Amp-Pd(0)-NPs) for the kinetic resolution of rac-2a.Thus, self-assembled APCW8 and APCW9 (Fig. 2a) were evaluated as heterogeneous catalysts.The AmP surface modification as well as the presence of Pd(0)-NPs did not decrease the excellent enantioselectivity of the enzyme (E 4 400).We also prepared and evaluated a hybrid catalyst containing CALB/Brij/Pd(0)/buffer salts.This catalyst did not exhibit good selectivity (E = 21).Thus, the presence of the MCC component is essential for reaching a high E-value under the evaluated reaction conditions.With these results in hand, the novel APCW9 structure was chosen and further investigated as the nature-inspired multi-catalyst system.The assembled APCW9 multi-catalyst structure (Fig. 2a) had a narrow distribution of Pd nanoparticles (main distribution of 1.6 to 2.8 nm in size, Fig. 2f) as confirmed by TEM analyses (Fig. 2b and c).The distribution between Pd(0) and Pd(II) in the Pd NPs of APCW9 was difficult to determine due to the presence of the salts of the phosphate buffer; however, it was similar to that of its MCC-AmP-Pd(0) component as determined by XPS (Fig. 2d and e).Thus, we had accomplished the assembly of an APCW structure containing Pd-nanoparticles and enzyme units as well-defined catalysts.Next, the APCW-catalyzed deracemization of amine 2a was investigated (Table 1).We found that APCW9 is an excellent catalyst system, which is able to catalyze the formation of amide 3a under DKR  conditions in several solvents (Table 1).The deracemization (DKR process) involves a synergistic interplay between Pd(0)-catalyzed racemization and CALB-catalyzed enantioselective amidation of 2a within the cellulose network of APCW9. 43Another competing catalytic side-reaction that the APCW can catalyze, is deamination of 2a to give the corresponding ethylbenzene (5a).It is noteworthy that the integrated heterogeneous APCW9 catalyst system is more efficient and chemoselective than when using mixed separate Pd-NPs on MCC and CALB on MCC or when using a hybrid-catalyst made of CALB, Brij, Pd(0)-NP and buffer (Table 1, entries 1, 11 and 12).
In addition, performing the reaction with APCW11, which contains Pd(II), gave a low ee (entry 13).The reaction with APCW3, which do not contain Pd, led to a kinetic resolution (3a, 46% yield, entry 14).Moreover, the Pd-nanoparticle catalysts are not able to racemize the product (R)-3a just the amine 2a (see ESI †).The heterogeneous APCW9 multi-catalyst system catalyzed the asymmetric synthesis of a variety of amides 3, which were isolated in good to high yields with 91-99% enantiomeric excess (Table 2).We further investigated the sustainable APCW multi-catalyst systems by probing their recyclability.The recycling studies revealed that the APCW catalytic systems, which contained a hydrolytic enzyme can be recycled multiple times when catalyzing the KR of amine 2a maintaining their high enantioselectivity in the organic solvent.
For example, the APCW3 system catalyzed the amidation of 2a in high enantioselectivity and the corresponding amide (R)-3a was isolated in 48% yield (50% is the maximum theoretical yield) in 499% ee even after 9 recycles (Fig. S2a, ESI †).It is remarkable that the sustainable APCW9 multi-catalyst system can catalyze the DKR of 2a over several cycles (Fig. S2b, ESI †), 44 since most of the previous recycling studies of artificial ''deracemases'' and hybrid enzyme catalyst systems containing CALB displayed a limited recycling due to significant deactivation of the enzyme catalyst. 21Thus, the disclosed artificial plant-cell wall concept enables several important features of accomplishing effective biocatalysis in non-aqueous media such as maintaining activity and stability in organic solvents, high stereoselectivity, recyclability, asymmetric synthesis, high temperature tolerance (90 1C), and efficient cooperation with chemical catalysts.No leaching of the metal catalyst was observed during the recycling studies.
We have demonstrated that sustainable artificial plant cellwall (APCW) structures, which contain a multi-catalytic system of both enzyme and metal nanoparticle catalysts, can be used to accomplish asymmetric catalysis and cascade synthesis in nonaqueous media.A key feature of the disclosed APCW concept is its intrinsic ability to activate the enzyme protein for catalysis in organic solvents.The heterogeneous polysaccharide-based APCW network having both enzyme and metal nanoparticles in its structure, catalyzed DKR of primary amines by cooperative catalysis.Thus, the assembled sustainable APCW structure acts as a ''deracemase''.It is also possible to reuse the bioinspired APCW structures in multiple-reaction cycles.In comparison, previous attempts of constructing artificial ''deracemases'' using silica-based or cross-linked enzyme aggregate systems had limitations in their recycling due to deactivation of the enzyme k MCC-Amp-Pd 0 (16.5 mg, 12 mol% Pd) and APCW3 (MCC/CALB/Brij/ buffer) (9 mg) were used as catalysts.l CALB/Brij/Pd 0 /buffer (9 mg) was used as a catalyst.m APCW11 (MCC-Amp-Pd II /CALB/Brij/buffer) was used as a catalyst.n APCW3 was used as a catalyst.a Reaction conditions: 2 (0.25 mmol, 1 equiv.), 4 (2.5 mmol, 10 equiv.),APCW9 (9 mg, 1.1 mol% Pd), Na 2 CO 3 (0.75 mmol, 3 equiv.),solvent (1 mL), 90 1C, H 2 balloon.b Reaction performed in toluene for 23 hours.
component.The concept of introducing catalysts with different functions within an artificial primary cell-wall structure holds great promise in creating other types of APCW catalysts with novel reactivity.Thus, various enzymes and chemical catalysts can be combined within nature-inspired plant cell wall structures to create heterogeneous catalysts for cooperative chemoenzymatic cascade reactions.

Fig. 1
Fig.1Simplified scheme of self-assembly of components to create an artificial primary cell wall 1, which simultaneously catalyzes racemization and amidation of racemic amines 2. M = metal.