Tools and ingredients for the biocatalytic synthesis of metabolites

Metabolic networks have been an interesting starting point not only for the design of synthetic routes in a similar sequence of reactions, e.g., in biomimetic syntheses, but also for assembling a number of biocatalytic steps by preparing the required enzymes and auxiliary reagents. Retrosynthetic analysis involving multiple biocatalytic reactions steps therefore needs to consider the practically realized biocatalytic single steps. The opportunities for route selection are enlarged if novel synthetic reactions connecting easily available starting materials and products are found, and/or both biocatalytic and classical reactions of organic chemistry are utilized. Tools and ingredients for biocatalytic synthesis are of special interest for reactions difficult to achieve by classical organic synthesis. Densely and differentially functionalized small molecules do not allow much space for protecting or activating groups. Biocatalytic reactions have therefore performed well for a number of useful metabolites in enantiopure form to achieve full functionality. Although many well-known metabolites from classical biochemistry have only been prepared in racemic form, it is of fundamental interest to have these available in enantiomerically pure form. Biocatalytic reactions with nature's privileged chiral catalysts appear to be a promising synthetic strategy towards these metabolites, especially when sensitive or stable-isotope-labeled metabolites are to be prepared. The main applications for these metabolites are as references materials in metabolomics, as enzyme substrates for the characterization of metabolic enzyme activities and as potential pharmaceuticals in biomedical research. The use of stable-isotope-labeled metabolites can thereby simplify in vivo applications and metabolic flux analyses.     

Combinatorial biocatalysis: taking the lead from nature

Combinatorial biocatalysis is an emerging technology in the field of drug discovery. The biocatalytic approach to combinatorial chemistry uses enzymatic, chemoenzymatic, and microbial transformations to generate libraries from lead compounds. Important recent advances in combinatorial biocatalysis include iterative derivatization of small molecules and complex natural products, regioselectively controlled libraries, novel one-pot library syntheses, process automation, and biocatalyst enhancements.     

组合生物催化

自然界最有效的分子是由酶催化的反应所产生,并对这些产物进行自然选择,使其具有优化的生理活性,组合生物催化（Combinatorial Biocatalysis)利用酶反应的多样性,完成有机库（Organic Library)的反复合成,这些反复的反应,可以用分离的酶或全细胞,在天然或非天然的环境中、在溶液或固相中与底物进行反应。组合生物催化是组合方法的在药物发现和发展中产生和优化先导化合物（LeadCompound)的一个有力补充。     

Biocatalytic combinatorial synthesis

Combinatorial biocatalysis, based on a principle of the combinatorial use of biosynthetic steps rather than the combinatorial use of reagents, offers a complementary approach to combinatorial chemistry, which, used individually or in connection with synthetic organic transformations, provides access to analogues not readily accessible by chemical synthetic means alone. The issues and strategies particular to this approach are discussed. Examples are given demonstrating these principles as well as the unique advantages of achieving chemo-, regio- and stereoselectivity under mild reaction conditions that biocatalytic methods offer.     

Biocatalytic preparation of natural flavours and fragrances

During the past years biocatalytic production of fine chemicals has been expanding rapidly. Flavours and fragrances belong to many different structural classes and therefore represent a challenging target for academic and industrial research. Here, we present a condensed overview of the potential offered by biocatalysis for the synthesis of natural and natural-identical odorants, highlighting relevant biotransformations using microorganisms and isolated enzymes. The industrial processes based on biocatalytic methods are discussed in terms of their advantages over classical chemical synthesis and extraction from natural sources. Recent applications of the biocatalytic approach to the preparation of the most important fine odorants are comprehensively covered.     

Recent developments and applications of liquid-phase strategies in organic synthesis.

Chemistry on soluble polymer supports, termed liquid-phase organic synthesis, is developing into an increasingly viable alternative or adjunct to the classical solid-phase approach across the broad spectrum of polymer-supported organic chemistry. Recent advances in the field include the use of soluble polymers in the combinatorial synthesis of peptide and small-molecule libraries, as catalyst and reagent supports, and as functionalized polymer-quench reagents for purifying solution-phase combinatorial libraries.     

Emerging strategies for expanding the toolbox of enzymes in biocatalysis

Expanding the repertoire of reactions available to enzymes is an enduring challenge in biocatalysis. Owing to the synthetic versatility of transition metals, metalloenzymes have been favored targets for achieving new catalytic functions. Although less well explored, enzymes lacking metal centers can also be effective catalysts for non-natural reactions, providing access to reaction modalities that compliment those available to metals. By understanding how these activation modes can reveal new functions, strategies can be developed to access novel biocatalytic reactions. This review will cover discoveries in the last two years which access catalytic reactions that go beyond the native repertoire of metal-free biocatalysts.     

Biocatalysis--key to sustainable industrial chemistry

The ongoing trends to process improvements, cost reductions and increasing quality, safety, health and environment requirements of industrial chemical transformations have strengthened the translation of global biocatalysis research work into industrial applications. One focus has been on biocatalytic single-step reactions with one or two substrates, the identification of bottlenecks and molecular as well as engineering approaches to overcome these bottlenecks. Robust industrial procedures have been established along classes of biocatalytic single-step reactions. Multi-step reactions and multi-component reactions (MCRs) enable a bottom-up approach with biocatalytic reactions working together in one compartment and recations hindering each other within different compartments or steps. The understanding of the catalytic functions of known and new enzymes is key for the development of new sustainable chemical transformations.     

Combinatorial catalyst discovery.

There have been recent attempts to use the principles of combinatorial chemistry and high-throughput screening strategies for catalyst identification. With the technology available that allows the synthesis of large libraries, scientists of varied backgrounds have implemented screening efforts to identify active and selective catalysts. Within this context, several techniques have come to light in the past year: infrared thermography is used to identify optimal catalysts by monitoring the change in temperature for exothermic reactions; fluorescence and colored-dye assays, a familiar tool to biologists, is being applied to the identification of catalysts that exhibit the highest activity. Whereas none of these screening methods provide a general solution to the problem of screening large combinatorial libraries (there is likely to be no general solution), each advance represents an important intellectual and technological step forward.     

Wanted: new multicomponent reactions for generating libraries of polycyclic natural products

The amalgamation of two of combinatorial chemistry's most attractive concepts--natural product libraries and multicomponent reactions (MCRs)--should provide a powerful tactic for generating libraries of bioactive compounds. Yet, despite many recent advances in this area, only a few MCRs can deliver functionalized products whose structures closely resemble that of complex polycyclic natural products. A large proportion of recently developed MCRs are based on [4+2] or [3+2] cycloadditions, and isocyanide-based processes. Because of substrate limitations, however, they are not always ideally suitable for applications in diversity-oriented synthesis of natural product-like compounds. A promising area awaiting further development is the use of transition metal-catalyzed cascade reactions.     

Diversity assessment.

Several themes have been highlighted recently in both conferences and publications: the availability of product-focused and pharmacophore-based methods for the analysis and design of combinatorial libraries; the power of cell-based methods for molecular similarity, diversity and library design applications; methods for 'rational' diverse subset selection (with applicability to library design); the need for specialized optimization programs for the design of combinatorial libraries that maximize the use of common reagents; and the concept of 'drug-likeness' and its importance in the design of combinatorial libraries.     

Exploitation of carbohydrate processing enzymes in biocatalysis

Exploitation of enzymes in biocatalytic processes provides scope both in the synthesis and degradation of molecules. Enzymes have power not only in their catalytic efficiency, but their chemoselectivity, regioselectivity, and stereoselectivity means the reactions they catalyze are precise and reproducible. Focusing on carbohydrate processing enzymes, this review covers advances in biocatalysis involving carbohydrates over the last 2–3 years. Given the notorious difficulties in the chemical synthesis of carbohydrates, the use of enzymes for synthesis has potential for significant impact in the future. The use of catabolic enzymes in the degradation of biomass, which can be exploited in the production of biofuels to provide a sustainable and greener source of energy, and the synthesis of molecules that have a range of applications including in the pharmaceutical and food industries will be explored.     

A simple protocol for combinatorial cyclic depsipeptide libraries sequencing by matrix‐assisted laser desorption/ionisation mass spectrometry

Short cyclic peptides have a great interest in therapeutic, diagnostic and affinity chromatography applications. The screening of ‘one‐bead‐one‐peptide’ combinatorial libraries combined with mass spectrometry (MS) is an excellent tool to find peptides with affinity for any target protein. The fragmentation patterns of cyclic peptides are quite more complex than those of their linear counterparts, and the elucidation of the resulting tandem mass spectra is rather more difficult. Here, we propose a simple protocol for combinatorial cyclic libraries synthesis and ring opening before MS analysis. In this strategy, 4‐hydroxymethylbenzoic acid, which forms a benzyl ester with the first amino acid, was used as the linker. A glycolamidic ester group was incorporated after the combinatorial positions by adding glycolic acid. The library synthesis protocol consisted in the following: (i) incorporation of Fmoc‐Asp[2‐phenylisopropyl (OPp)]‐OH to Ala‐Gly‐oxymethylbenzamide‐ChemMatrix, (ii) synthesis of the combinatorial library, (iii) assembly of a glycolic acid, (iv) couple of an Ala residue in the N‐terminal, (v) removal of OPp, (vi) peptide cyclisation through side chain Asp and N‐Ala amino terminus and (vii) removal of side chain protecting groups. In order to simultaneously open the ring and release each peptide, benzyl and glycolamidic esters were cleaved with ammonia. Peptide sequences could be deduced from the tandem mass spectra of each single bead evaluated. The strategy herein proposed is suitable for the preparation of one‐bead‐one‐cyclic depsipeptide libraries that can be easily open for its sequencing by matrix‐assisted laser desorption/ionisation MS. It employs techniques and reagents frequently used in a broad range of laboratories without special expertise in organic synthesis. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Construction of semi-randomized gene libraries with weighted oligonucleotide synthesis and PCR

Randomized gene libraries may be constructed and screened to find novel candidates with particular functions, and the applications can range widely, from protein engineering to selecting new microRNAs. Here we describe a technique to construct gene libraries using semi-randomized weighted oligonucleotide synthesis and end-to-end ligation. This method makes it possible to search the combinatorial space around a particular nucleotide sequence for a greater number of positions than is possible with fully randomized oligonucleotides. As an alternative to full cassette construction, library mutations can also be introduced through 'round-the-world PCR' approaches. Construction of a randomized gene cassette and cloning can typically be achieved in 2 weeks. Therefore, these are rapid and convenient methods to generate successive generations of libraries for iterative selection and optimization.     

Tools for Selective Enzyme Reaction Steps in the Synthesis of Laboratory Chemicals

The need for more selective reactions steps and the compatibility between process steps which follow on from each other has been a major driving force for organic synthesis. The synthesis of chiral compounds, metabolites, new chemical entities and natural products by a combination of chemical and enzyme reaction steps has become well established, due the existence of stable enzymes as selective catalysts which are inherently chiral by nature. Auxiliary tools such as suitable transfer reagents for reaching complete conversion, easy and robust reaction control as well as tools for straightforward workup and purification of the final product have been developed. Selective enzyme reaction steps in the area of hydrolyses, oxidation steps including hydroxylation and the Baeyer‐Villiger oxidation, carbon‐carbon bond formation and glycosylation reactions have compared favorably with existing methods of classical organic synthesis. The tools developed during optimization and scale‐up of these enzyme reaction steps have the potential to shorten development time. The introduction of selective enzyme reactions into an entire synthetic process has resulted in harmonization of improvements in economic efficiency with resultant solutions to health, safety and environment problems. This will become even more important in industrial synthetic chemistry in the future, for convenient solutions to certain intractable synthetic problems and for expanding the repertoire of chemistry by modular biocatalysts. Efficient isolation procedures for the final product are essential to take full advantage of the biocatalytic conversion to obtain high product yields.     

Evolution of DNA and RNA as catalysts for chemical reactions

In vitro selection from combinatorial nucleic acid libraries has provided new RNA and DNA molecules that have catalytic properties. Catalyzed reactions now go far beyond self-modifying reactions of nucleic acid molecules. The future application of in vitro selected RNA and DNA catalysts in bioorganic synthesis appears promising.     

Parallel synthesis of peptide libraries using microwave irradiation

The application of microwave irradiation to solid-phase peptide synthesis increases product purity and reduces reaction time. Parallel synthesis in 96-well polypropylene filter plates with microwave irradiation is an efficient method for the rapid generation of combinatorial peptide libraries in sufficient purity to assay the products directly for biological activity without HPLC purification. In this protocol, the solid-phase support is arrayed into each well of a 96-well plate, reagents are delivered using a multichannel pipette and a microwave reactor is used to complete peptide coupling reactions in 6 min and Fmoc-removal reactions in 4 min under temperature-controlled conditions. The microwave-assisted parallel peptide synthesis protocol has been used to generate a library of difficult hexa-beta-peptides in 61% average initial purity (50% yield) and has been applied to the preparation of longer alpha- and beta-peptides. Using this protocol, a library of 96 different hexapeptides can be synthesized in 24 h (excluding characterization).     

Application of combinatorial biocatalysis for a unique ring expansion of dihydroxymethylzearalenone

Combinatorial biocatalysis was applied to generate a diverse set of dihydroxymethylzearalenone analogs with modified ring structure. In one representative chemoenzymatic reaction sequence, dihydroxymethylzearalenone was first subjected to a unique enzyme-catalyzed oxidative ring opening reaction that creates two new carboxylic groups on the molecule. These groups served as reaction sites for further derivatization involving biocatalytic ring closure reactions with structurally diverse bifunctional reagents, including different diols and diamines. As a result, a library of cyclic bislactones and bislactams was created, with modified ring structures covering chemical space and structure activity relationships unattainable by conventional synthetic means.     

Biocatalysis as an alternative for the production of chiral epoxides: A comparative review

Enantiopure epoxides are remarkably versatile intermediates for the synthesis of numerous biologically active targets, to which considerable efforts have been devoted either chemically or biologically during the past few decades. This review will emphasize the application of biocatalysis as an efficient alternative that complements conventional chemical reactions, with a special focus on the epoxidation reactions catalyzed with monooxygenases and chloroperoxidases and the hydrolytic kinetic resolution catalyzed with epoxide hydrolases. Their scopes and limitations will be elaborately discussed as compared with their chemical counterparts. These biocatalytic approaches have not only provided environmentally friendly alternatives, but also displayed advantages for certain types of enantiopure epoxides, and could serve as potential tools for synthetic chemists.     

Combinatorial array-based enzymatic polyester synthesis.

A combinatorial strategy for biocatalytic polymer synthesis is demonstrated. A library of polymers was synthesized in 96 deep-well plates using AA-BB polycondensations of acyl donors and acceptors. The library was based on four straight-chain diesters as acyl donors (C(3)-C(10)) with aliphatic/aromatic diols as well as more diverse structures including carbohydrates, nucleic acids, and a natural steroid diol used as acyl acceptors. The lipase from Candida antarctica was active in acetonitrile and was capable of catalyzing the polycondensation of the aforementioned monomers to polymers with M(w)'s reaching as high as 20,000 Da, including the preparation of novel sugar-containing polyesters. The combinatorial approach to biocatalytic polymer synthesis described herein serves as a foundation for polymeric materials discovery by demonstrating that polymer arrays can be produced from structurally complex monomers.