The evolution of biotransformation technologies

Biotransformation is a broad and growing field of biotechnology and encompasses both enzymatic and microbial biocatalysis. Progress has been made in research on the key drivers of biotransformations, including the isolation and characterization of microbes and their enzymes from, and their utilization in, extreme environments, the manipulation, alteration, and augmentation of metabolic pathways, and the use of combinatorial biosynthesis and biocatalytic methodologies for new compound development.     

Combinatorial biochemistry in plants: the case of O-methyltransferases

Combinatorial chemistry is common place today in chemical synthesis. Virtually thousands of derivatives of a molecule can be achieved by automated systems. The use of biological systems to exploit combinatorial chemistry (combinatorial biochemistry) now has multiple examples in the polyketide field. The modular functional domain structure of polyketide synthases have been recombined through genetic engineering into unnatural constellations in heterologous hosts in order to produce polyketide structures not yet discovered in nature. We present herein an example for a potential type of combinatorial biochemistry in alkaloidal systems using various combinations of Thalictrum tuberosum (meadow rue) O-methyltransferase subunits that result in heterodimeric enzymes with substrate specificities that differ from those of the homodimeric native enzymes.     

Initiating meiosis: the case for retinoic acid

The requirement for vitamin A in reproduction and development was first determined from studies of nutritional deficiencies. Subsequent research has shown that embryonic development and both male and female reproduction are modulated by retinoic acid (RA), the active form of vitamin A. Because RA is active in multiple developmental systems, its synthesis, transport, and degradation are tightly regulated in different tissues. A growing body of evidence implicates RA as a requirement for the initiation of meiosis in both male and female mammals, resulting in a mechanistic model involving the interplay of RA, RA synthesis enzymes, RA receptors, and degradative cytochrome P450 enzymes in this system. Recently, that model has been challenged, prompting a review of the established paradigm. While it remains possible that additional molecules may be involved in regulating entry into meiosis, the weight of evidence supporting a key role for RA is incontrovertible.     

The human extended mitochondrial metabolic network: new hubs from lipids

Even if systems thinking is not new in biology, rationalizing the explosively growing amount of knowledge has been the compelling reason for the sudden rise and spreading of systems biology. Based on 'omics' data, several genome-scale metabolic networks have been reconstructed and validated. One of the most striking aspects of complex metabolic networks is the pervasive power-law appearance of metabolite connectivity. However, the combinatorial diversity of some classes of compounds, such as lipids, has been scarcely considered so far. In this work, a lipid-extended human mitochondrial metabolic network has been built and analyzed. It is shown that, considering combinatorial diversity of lipids and multipurpose enzymes, an intimate connection between membrane lipids and oxidative phosphorilation appears. This finding leads to some biomedical considerations on diseases involving mitochondrial enzymes. Moreover, the lipid-extended network still shows power-law features. Power-law distributions are intrinsic to metabolic network organization and evolution. Hubs in the lipid-extended mitochondrial network strongly suggest that the "RNA world" and the "lipid world" hypothesis are both correct.     

Molecular advancements in the development of thermostable phytases

Since the discovery of phytic acid in 1903 and phytase in 1907, extensive research has been carried out in the field of phytases, the phytic acid degradatory enzymes. Apart from forming backbone enzyme in the multimillion dollar-based feed industry, phytases extend a multifaceted role in animal nutrition, industries, human physiology, and agriculture. The utilization of phytases in industries is not effectively achieved most often due to the loss of its activity at high temperatures. The growing demand of thermostable phytases with high residual activity could be addressed by the combinatorial use of efficient phytase sources, protein engineering techniques, heterologous expression hosts, or thermoprotective coatings. The progress in phytase research can contribute to its economized production with a simultaneous reduction of various environmental problems such as eutrophication, greenhouse gas emission, and global warming. In the current review, we address the recent advances in the field of various natural as well as recombinant thermotolerant phytases, their significance, and the factors contributing to their thermotolerance.

     

Recent advances and applications of the lipolytic activity of Carica papaya latex

The lipolytic enzymes of Carica papaya have been the subjects of a growing research activity in the last years due to the structural characteristics, substrate specificity over lipases from different sources and the wide availability from the large worldwide figures of papaya agro-waste. This review attempts to present an inclusive discussion of the recent advances of these lipolytic enzymes starting from findings related to their structure and mechanism and later examining the most employed pretreatments and the general optimized parameters for its use. Furthermore, individual sections comprising applications in glycerolipid modification, catalysis for the synthesis of non-glycerolipid products and the kinetic resolution of racemic compounds are discussed. The attractive features of CPL cited in this literature survey serve as an invitation for other research groups interested in the development of new and sustainable biochemical technologies.     

Combinatorial carbohydrate chemistry

The application of combinatorial chemistry to the synthesis of carbohydrate-based compound collections has received increased attention in recent years. New strategies for the solution-phase synthesis of oligosaccharide libraries have been reported, and the use of monosaccharides as scaffolds in the generation of combinatorial libraries has been described. Novel approaches to the assembly of carbohydrate-based antibiotics, such as aminoglycoside analogs and vancomycin derivatives, have also been disclosed.     

Libraries of non-polymeric organic molecules

New technology is emerging that permits the chemical synthesis of large numbers of different compounds simultaneously. Combinatorial chemistry is heavily dependent upon the adaption of organic synthesis to solid supports and has necessitated the development of appropriate analytical and chemical approaches to both monitor solid-phase reactions and release finished compounds into solution. Considerable progress has recently been made in all of these areas. Small-molecule libraries of medicinally important chemical classes, such as 1,4-benzodiazepines, mercaptopropionyl amino acids, and peptidyl phosphonates, have recently been reported. Encoded combinatorial libraries of dihydrobenzopyran-based and acylpiperidine-based pharmacophores have yielded potent inhibitors of carbonic anhydrase. Automated instrumentation is growing in importance for the synthesis of small-molecule libraries.     

Beyond Rf tagging

The split-pool diversity orientated synthesis method, which requires some form of encoding to track the synthesis of discrete compounds, has been the lynchpin of most combinatorial synthesis efforts. The use of encoding methods in combinatorial chemistry has matured, and depending on their level of resources, chemists now have a diverse choice of encoding methods available. New methods of encoding have been developed that are inexpensive, simple to incorporate into any laboratory, and utilize analytical equipment such as MS, FTIR and NMR that are readily available to most organic chemists.     

Bimodal occurrence of aspartoacylase in myelin and cytosol of brain

The growing use of N-acetylaspartate as an indicator of neuronal viability has fostered interest in the biological function(s) of this unusual amino acid derivative. In considering the various physiological roles that have been proposed for this relatively abundant molecule one is obliged to take into account its unusual metabolic compartmentalization, according to which synthesis and storage occur in the neuron and hydrolytic cleavage in the oligodendrocyte. The latter reaction, catalyzed by aspartoacylase (ASPA), produces acetyl groups plus aspartate and has been proposed to occur in both soluble and membranous subfractions of white matter. Our study supports such bimodal occurrence and we now present immunoblot, proteomic, and biochemical evidence that the membrane-bound form of ASPA is intrinsic to purified myelin membranes. This was supported by a novel TLC-based method for the assay of ASPA. That observation, together with previous demonstrations of numerous lipid-synthesizing enzymes in myelin, suggests utilization of acetyl groups liberated by myelin-localized ASPA for lipid synthesis within the myelin sheath. Such synthesis might be selective and could explain the deficit of myelin lipids in animals lacking ASPA.     

Induction of endo-1,4-beta-xylanase and beta-galactosidase in the original and recombinant strains of the fungus Penicillium canescens

The induction of the synthesis of secreted enzymes endo-1,4-beta-xylanase (EC 3.2.1.8) and beta-galactosidase (EC 3.2.1.23) in the original and recombinant Penicillium canescens strains has been studied. In all producer strains, the synthesis of these enzymes was induced by arabinose and its metabolite arabitol. The two enzymes differed in the concentration of arabinose required for the induction: the synthesis of beta-galactosidase was most pronounced at 1 mM, whereas maximum synthesis of endo-1,4-beta-xylanase was observed at 5 to 10 mM. An increase in the number of endo-1,4-beta-xylanase copies in the high-copy-number strain of the fungus suppressed the synthesis of beta-galactosidase; the synthesis of endo-1,4-beta-xylanase in the high-copy-number recombinant producing beta-galactosidase was affected to a lesser extent. The amount of the enzymes synthesized did not depend on the saccharide used as a sole source of carbon for growing the mycelium prior to its transfer to the inducer-containing medium.     

Preparation of potential inhibitors of the mur-pathway enzymes on solid support using an acetal linker

Here, we report a novel strategy for the combinatorial or parallel solid-phase synthesis of potential inhibitors of the mur-pathway enzymes. The strategy involves the efficient use of p-alkoxybenzylidene acetal linker for reversible immobilization of sugar scaffolds to solid phase. This methodology was used to synthesize several glycopeptides on solid phase in good yields.     

BioProfile-Extract knowledge from corporate databases to assess cross-reactivities of compounds

In the last 10-15years, many new technologies and approaches have been implemented in research in the pharmaceutical industry; these include high-throughput screening or combinatorial chemistry, which result in a rapidly growing amount of biological assay and structural data in the corporate databases. Efficient use of the data from this growing data mountain is a key success factor; 'provide as much knowledge as possible as early as possible and therefore enable research teams to make the best possible decision whenever this decision can be supported by stored data'. Here, an approach which started several years ago to obtain as much information as possible out of historical assay data stored in the corporate database is described. It will be shown how important a careful preprocessing of the stored data is to enhance its information. Different possibilities for accessing and to analyzing the preconditioned data are in place. Some of will be described in the examples.     

'One bead two compound libraries' for detecting chemical and biochemical conversions

When combinatorial chemistry was introduced 13 years ago, the expectations were high for the delivery of results, particularly in the pharmaceutical industry. However, combinatorial chemistry was implemented independently of the application for which the products were going to be used. Resins developed only for efficient solid-phase synthesis were used and products were employed in existing assays developed for traditional solution studies. There was almost no assay or technology development and the use of real combinatorial methods soon had to give way to high-throughput synthesis and traditional screening. However, during recent years more sophisticated resins and assay techniques have been developed that may result in a second and more successful implementation of real integrated combinatorial chemistry. The first in this line of new developments is the 'one bead two compound' assay, in which the resin bead in addition to a combinatorial library member contains a reporter compound that can act as a beacon to monitor the activity of the library member. This powerful concept can be generally applied in all fields of combinatorial chemistry including drug, catalysts and material development.     

Conventional and non-conventional applications of β-galactosidases

β-Galactosidase is one of the most important industrial enzymes, that has been used for many decades in the dairy industry. The main application of β-galactosidase is related to the production of low-lactose and lactose-free milk and dairy products, which are now common consumer goods in supermarket shelves. This is a well-established market that is expected to keep on growing as these products become more accessible to mid-income people worldwide. However, a fresh air has come into the β-galactosidase business as non-conventional applications arose in recent decades based on its transgalactosylation activity. This capacity is certainly a major asset for a commodity enzyme that can be used now as a catalyst for the upgrading of readily available and cheap lactose into high added-value glycosides in processes of organic synthesis in tune with green chemistry principles within the framework of sustainability. This is a reflection of a paradigm shift, where enzymes are now being considered as apt catalysts for the synthesis of valuable organic compounds. This article reviews the main applications of β-galactosidase, going from its conventional use related to its hydrolytic activity to the ongoing non-conventional applications in the synthesis of high added-value oligosaccharides based on its transgalactosylation activity.     

The phosphopantetheinyl transferase superfamily: phylogenetic analysis and functional implications in cyanobacteria

Phosphopantetheinyl transferases (PPTs) are a superfamily of essential enzymes required for the synthesis of a wide range of compounds including fatty acid, polyketide, and nonribosomal peptide metabolites. These enzymes activate carrier proteins in specific biosynthetic pathways by the transfer of a phosphopantetheinyl moiety to an invariant serine residue. PPTs display low levels of sequence similarity but can be classified into two major families based on several short motifs. The prototype of the first family is the broad-substrate-range PPT Sfp, which is required for biosynthesis of surfactin in Bacillus subtilis. The second family is typified by the Escherichia coli acyl carrier protein synthase (AcpS). Facilitated by the growing number of genome sequences available for analyses, large-scale phylogenetic studies were utilized in this research to reveal novel subfamily groupings, including two subfamilies within the Sfp-like family. In the present study degenerate oligonucleotide primers were designed for amplification of cyanobacterial PPT gene fragments. Subsequent phylogenetic analyses suggested a unique, function-based PPT type, defined by the PPTs involved in heterocyst differentiation. Evidence supporting this hypothesis was obtained by sequencing the region surrounding the partial Nodularia spumigena PPT gene. The ability to genetically classify PPT function is critical for the engineering of novel compounds utilizing combinatorial biosynthesis techniques. Information regarding cyanobacterial PPTs has important ramifications for the ex situ production of cyanobacterial natural products.     

Tetrabutylammonium fluoride-assisted rapid N9-alkylation on purine ring: application to combinatorial reactions in microtiter plates for the discovery of potent sulfotransferase inhibitors in situ

Tremendous efforts have been invested in the synthesis of purine libraries due to their importance in targeting various enzymes involved in different diseases and cellular processes. The synthesis of N9-alkylated purine scaffolds relied mostly on Mitsunobu conditions with a variety of alcohols or strong basic conditions with different organic halides. A more reliable and efficient way for the synthesis of N(9)-alkylated purine scaffolds is reported. This method uses tetrabutylammonium fluoride (TBAF) to assist such chemistry. In many cases, the reactions were completed within 10 min and gave the desired product in high yield and selectivity. Moreover, these mild reaction conditions permitted its use in combinatorial reactions in microtiter plates followed by in situ screening for the discovery of potent sulfotransferase inhibitors.     

Genetic manipulation of non-ribosomal peptide synthetases to generate novel bioactive peptide products

Non-ribosomal peptide synthetases (NRPS) are large modular enzymes that govern the synthesis of numerous biotechnologically relevant products. Their mode of action is frequently compared to an assembly line, in which each module acts in a semi-autonomous but coordinated manner to add a specific monomer to a growing peptide chain, unfettered by ribosomal constraints. The modular nature of these systems offers tantalising prospects for synthetic biology, wherein the assembly line is re-engineered at a genetic level to generate a specific or combinatorial modified product. However, despite some success stories, a “one size fits all” approach to NRPS synthetic biology remains elusive. This review examines both rational and random mutagenesis strategies that have been employed to modify NRPS function, in an attempt to highlight key points that should be considered when seeking to re-engineer an NRPS biosynthetic template.     

Manipulating redox systems: application to nanotechnology

Redox proteins and enzymes are attractive targets for nanobiotechnology. The theoretical framework of biological electron transfer is increasingly well-understood, and several properties make redox centres good systems for exploitation: many can be detected both electrochemically and optically; they can perform specific reactions; they are capable of self-assembly; and their dimensions are in the nanoscale. Great progress has been made with the two main approaches of protein engineering: rational design and combinatorial synthesis. Rational design has put our understanding of the structure-function relationship to the test, whereas combinatorial synthesis has generated new molecules of interest. This article provides selected examples of novel approaches where redox proteins are "wired up" in efficient electron-transfer chains, are "assembled" in artificial multidomain structures (molecular Lego), are "linked" to surfaces in nanodevices for biosensing and nanobiotechnological applications.