Enzymology in monophasic organic media.

Over the past year, an important area of research has been directed towards the fundamental aspects of enzymes and new applications of enzymology in monophasic organic media. Much of this research has focused on the factors that influence enzymatic catalysis in monophasic organic solvents, including the importance of enzyme-associated water, and the effect of organic solvents on enzyme structure and thermodynamic features. From an applications perspective, new advances in the use of enzymes in organic and polymer syntheses and optical resolutions have been made.     

固定化酶的空间取向控制策略

阐述了固定化酶的空间取向控制的方法和应用研究。     

Flow cytometry in radiation research: past, present and future

Flow cytometry is an invaluable technique in research and clinical laboratories. The technique has been applied extensively to many areas of radiation research at both the experimental and clinical level. In the past few years, there has been a significant increase in the capabilities of modern flow cytometers to undertake multicolor analysis in a user-friendly manner. The developments in cytometric technology are being matched by the rapid development of new reagents, new fluorochromes and new platforms such as bead arrays. These developments are facilitating many new applications in both basic and clinical research that have relevance for many fields of biology, including radiation research. This review provides a historical overview of the application of flow cytometry to radiobiology and an update on how technology and reagents have changed and cites examples of new applications relevant to radiation researchers. In addition, some entirely new flow instrumentation is currently under development that has significant potential for applications in radiation research.     

Structural and biochemical studies of GH family 12 cellulases: improved thermal stability, and ligand complexes

In this review we will describe how we have gathered structural and biochemical information from several homologous cellulases from one class of glycoside hydrolases (GH family 12), and used this information within the framework of a protein-engineering program for the design of new variants of these enzymes. These variants have been characterized to identify some of the positions and the types of mutations in the enzymes that are responsible for some of the biochemical differences in thermal stability and activity between the homologous enzymes. In this process we have solved the three-dimensional structure of four of these homologous GH 12 cellulases: Three fungal enzymes, Humicola grisea Cel12A, Hypocrea jecorina Cel12A and Hypocrea schweinitzii Cel12A, and one bacterial, Streptomyces sp. 11AG8 Cel12A. We have also determined the three-dimensional structures of the two most stable H. jecorina Cel12A variants. In addition, four ligand-complex structures of the wild-type H. grisea Cel12A enzyme have been solved and have made it possible to characterize some of the interactions between substrate and enzyme. The structural and biochemical studies of these related GH 12 enzymes, and their variants, have provided insight on how specific residues contribute to protein thermal stability and enzyme activity. This knowledge can serve as a structural toolbox for the design of Cel12A enzymes with specific properties and features suited to existing or new applications.     

Exploring the biosynthesis of natural products and their inherent suitability for the rational design of desirable compounds through genetic engineering

Much effort has been invested in studying how natural products are biosynthesized, and great advances have been made in understanding how these compounds acquire their structural complexity and biological activities. In recent years, significant progress has been made due to the devoted efforts of scientists in this field and to technological advancements. Numerous details, applications, and innovative findings have been elucidated by scientists using biochemical, genetic, and molecular biological approaches. Here I present a comprehensive overview of highly valued biosynthetic proteins, polyketide synthase and nonribosomal peptide synthetase. I begin with "Diels-Alderase" a captivating enzyme that has the ability to catalyze a Diels-Alder reaction valued by chemists for its usefulness in chemical synthesis. A handful of these enzymes have been characterized and chemically authenticated. The most well understood enzyme of this category is macrophomate synthase. Secondly, I focus on the polyketide and nonribosomal peptide biosynthetic pathways and the enzyme assembly for producing its metabolite. Many important natural products are produced by this biosynthetic pathway as secondary metabolites, such as erythromycin, rifamycin, and FK520, as antibiotics and an immunosuppressive, respectively. I conclude with a discussion of nonribosomal peptides and their mechanistic pathways. Special attention will be devoted to de novo production of echinomycin in a heterologous manner, the earliest example of totally engineered biosynthesis of the biologically active form of a nonribosomal peptide host in Escherichia coli.     

Enzyme promiscuity: mechanism and applications

Introductory courses in biochemistry teach that enzymes are specific for their substrates and the reactions they catalyze. Enzymes diverging from this statement are sometimes called promiscuous. It has been suggested that relaxed substrate and reaction specificities can have an important role in enzyme evolution; however, enzyme promiscuity also has an applied aspect. Enzyme condition promiscuity has, for a long time, been used to run reactions under conditions of low water activity that favor ester synthesis instead of hydrolysis. Together with enzyme substrate promiscuity, it is exploited in numerous synthetic applications, from the laboratory to industrial scale. Furthermore, enzyme catalytic promiscuity, where enzymes catalyze accidental or induced new reactions, has begun to be recognized as a valuable research and synthesis tool. Exploiting enzyme catalytic promiscuity might lead to improvements in existing catalysts and provide novel synthesis pathways that are currently not available.     

Tagging and detection strategies for activity-based proteomics

The field of activity-based proteomics is a relatively new discipline that makes use of small molecules, termed activity-based probes (ABPs), to tag and monitor distinct sets of proteins within a complex proteome. These activity-dependant labels facilitate analysis of systems-wide changes at the level of enzyme activity rather than simple protein abundance. While the use of small molecule inhibitors to label enzyme targets is not a new concept, the past ten years have seen a rapid expansion in the diversity of probe families that have been developed. In addition to increasing the number and types of enzymes that can be targeted by this method, there has also been an increase in the number of methods used to visualize probes once they are bound to target enzymes. In particular, the use of small organic fluorophores has created a wealth of applications for ABPs that range from biochemical profiling of diverse proteomes to direct imaging of active enzymes in live cells and even whole animals. In addition, the advent of new bioorthogonal coupling chemistries now enables a diverse array of tags to be added after targets are labeled with an ABP. This strategy has opened the door to new in vivo applications for activity-based proteomic methods.     

Interaction of lysozyme with gold nanorods: conformation and activity investigations

Gold nanorods, with their unique morphology and optical properties have offered new prospects for biomedical and biosensing applications. Herein, the interaction between gold nanorods and a model protein has been monitored using spectroscopic techniques. The enzyme retains high fraction of its native structure with a slight increase in the helical content at the expense of β-turns. Kinetic investigations revealed notable increase of enzyme affinity for substrate without significant decrease in the V_max. Emission spectra of tryptophan residues in the presence of chaotropic agent highlighted the maintenance of internal quenching due to the induced compactness. Comparison of the gold nanorod treated lysozyme with free enzyme revealed higher thermodynamic stability under denaturing condition. Results from this study encourage the possibility of utilizing gold nanorods as promising nanocarrier candidates for a new generation of drug delivery applications.     

New approaches to the preparation and application of firefly luciferase

Allowing for the lipid nature of firefly luciferase we have developed a new method for obtaining high-activity and high-stability enzyme preparations for bioluminescent microassay. The method includes the step of differential centrifugation in presence of stabilizing additives which entails a partial purification of the enzyme and its essential stabilization likely due to the fact that luciferase retains its lipid environment which plays an important role in catalysis. The resultant luciferase preparation is stable in solution at 4 °C for 2-3 months and allows the detection of down to 10^?11M ATP. A new method has been offered for luciferase immobilization on film carriers precoated with a phospholipid layer. By sorption of the enzyme on such carriers, the samples of immobilized luciferase have been obtained suitable for constructing chemiluminescent biosensors, in the form of luciferase-containing films. There are many-fold applications for detection of ATP micro-quantities.     

Blue Native electrophoresis to study mitochondrial and other protein complexes

The biogenesis and maintenance of mitochondria relies on a sizable number of proteins. Many of these proteins are organized into complexes, which are located in the mitochondrial inner membrane. Blue Native polyacrylamide gel electrophoresis (BN-PAGE) is a method for the isolation of intact protein complexes. Although it was initially used to study mitochondrial respiratory chain enzymes, it can also be applied to other protein complexes. The use of BN-PAGE has increased exponentially over the past few years and new applications have been developed. Here we review how to set up the basic system and outline modifications that can be applied to address specific research questions. Increasing the upper mass limit of complexes that can be separated by BN-PAGE can be achieved by using agarose instead of acrylamide. BN-PAGE can also be used to study assembly of mitochondrial protein complexes. Other applications include in-gel measurements of enzyme activity by histochemical staining and preparative native electrophoresis to isolate a protein complex. Finally, new ways of identifying protein spots in Blue Native gels using mass spectrometry are briefly discussed.     

The Importance of Thermophilic Bacteria in Biotechnology

Abstract

The development of new analytical techniques and the commercial availability of new substrates have led to the purification and characterization of a large number of xylan-degrading enzymes. Furthermore, the introduction of recombinant DNA technology has resulted in the selection of xylanolytic enzymes that are more suitable for industrial applications. For a successful integration of xylanases in industrial processes, a detailed understanding of the mechanism of enzyme action is, however, required. This review gives an overview of various xylanolytic enzyme systems from bacteria and fungi that have been described recently in more detail.     

Structural and biochemical studies of GH family 12 cellulases: improved thermal stability,and ligand complexes

In this review we will describe how we have gathered structural and biochemical information from several homologous cellulases from one class of glycoside hydrolases (GH family 12), and used this information within the framework of a protein-engineering program for the design of new variants of these enzymes. These variants have been characterized to identify some of the positions and the types of mutations in the enzymes that are responsible for some of the biochemical differences in thermal stability and activity between the homologous enzymes. In this process we have solved the three-dimensional structure of four of these homologous GH 12 cellulases: Three fungal enzymes, Humicola grisea Cel12A, Hypocrea jecorina Cel12A and Hypocrea schweinitzii Cel12A, and one bacterial, Streptomyces sp. 11AG8 Cel12A. We have also determined the three-dimensional structures of the two most stable H. jecorina Cel12A variants. In addition, four ligand-complex structures of the wild-type H. grisea Cel12A enzyme have been solved and have made it possible to characterize some of the interactions between substrate and enzyme. The structural and biochemical studies of these related GH 12 enzymes, and their variants, have provided insight on how specific residues contribute to protein thermal stability and enzyme activity. This knowledge can serve as a structural toolbox for the design of Cel12A enzymes with specific properties and features suited to existing or new applications.     

Submitting antibodies to binding arbitration

For the last 30 years, the production of affinity reagents and particularly antibodies for research and therapeutic applications has been dominated by hybridoma and polyclonal technologies, while more modern, reliable and inexpensive approaches have lagged. Here we discuss why this is the case and how a cultural shift in the biomedical research community could bring the new technologies for creating antibodies and other tailor-designed binding proteins into the mainstream, with the potential for myriad new applications in research and medicine.     

Oxalate decarboxylase: biotechnological update and prevalence of the enzyme in filamentous fungi

Oxalate decarboxylase (ODC) is a manganese-containing, multimeric enzyme of the cupin protein superfamily. ODC is one of the three enzymes identified to decompose oxalic acid and oxalate, and within ODC catalysis, oxalate is split into formate and CO₂. This primarily intracellular enzyme is found in fungi and bacteria, and currently the best characterized enzyme is the Bacillus subtilis OxdC. Although the physiological role of ODC is yet unidentified, the feasibility of this enzyme in diverse biotechnological applications has been recognized for a long time. ODC could be exploited, e.g., in diagnostics, therapeutics, process industry, and agriculture. So far, the sources of ODC enzyme have been limited including only a few fungal and bacterial species. Thus, there is potential for identification and cloning of new ODC variants with diverse biochemical properties allowing e.g. more enzyme fitness to process applications. This review gives an insight to current knowledge on the biochemical characteristics of ODC, and the relevance of oxalate-converting enzymes in biotechnological applications. Particular emphasis is given to fungal enzymes and the inter-connection of ODC to fungal metabolism of oxalic acid.     

Molecular biology and regulation of methane monooxygenase

Methanotrophs are ubiquitous in the environment and play an important role in mitigating global warming due to methane. They are also potentially interesting for industrial applications such as production of bulk chemicals or bioremediation. The first step in the oxidation of methane is the conversion to methanol by methane monooxygenase, the key enzyme, which exists in two forms: the cytoplasmic, soluble methane monooxygenase (sMMO) and the membrane-bound, particulate methane monooxygenase (pMMO). This paper reviews the biochemistry and molecular biology of both forms of MMO. In the past few years there have been many exciting new findings. sMMO components have been expressed in heterologous and homologous hosts. The pMMO has been purified and biochemically studied in some detail and the genes encoding the pMMO have been sequenced. Copper ions have been shown to play a key role in regulating the expression of both MMO enzyme complexes. We also present a model for copper regulation based on results from Northern analysis, primer-extensions and new sequence data, and raise a number of unanswered questions for future studies.     

Cytochemical studies of the vascular endothelium

Cytochemical methods have been used to examine the vascular endothelium. With hemeproteins and immunocytochemistry, investigators have demonstrated the pathways that blood-borne molecules can take to gain access to the extravascular space (Ghitescu et al. 1986; Milici et al. 1987; Schneeberger and Karnovsky 1971; Simionescu et al. 1975). These same cytochemical methods have also provided evidence that morphologically similar endothelia may have different permeability properties (Hart and Pino 1985b, 1986; Pino 1985; Pino and Essner 1980, 1981). Differences in the location and chemical composition of cell surface moieties have been ascertained with enzyme digestion methods, lectins, and cationic ferritin (De Bruyn and Michelson 1978; Pino 1984c, 1986a, b; Simionescu et al. 1981a). The author hopes that he has provided the reader with representative examples of how investigators have used these cytochemical methods for their studies. As new methods are developed and applications are found for existing techniques such as ultracryomicrotomy (Milici et al. 1987) and colloidal gold markers (Pino 1987b), cytochemistry will remain a fundamental tool for the study of the structure and function of the vascular endothelium.     

Definitions of enzyme function for the structural genomics era

Questions are being asked about how enzyme function is described at the molecular level and the strengths and weaknesses of the EC system for this purpose. A new approach to describing enzyme function has been proposed that might improve our capabilities for functional inference for members of enzyme superfamilies.     

Microbial keratinases: industrial enzymes with waste management potential

Proteases are ubiquitous enzymes that occur in various biological systems ranging from microorganisms to higher organisms. Microbial proteases are largely utilized in various established industrial processes. Despite their numerous industrial applications, they are not efficient in hydrolysis of recalcitrant, protein-rich keratinous wastes which result in environmental pollution and health hazards. This paved the way for the search of keratinolytic microorganisms having the ability to hydrolyze “hard to degrade” keratinous wastes. This new class of proteases is known as “keratinases”. Due to their specificity, keratinases have an advantage over normal proteases and have replaced them in many industrial applications, such as nematicidal agents, nitrogenous fertilizer production from keratinous waste, animal feed and biofuel production. Keratinases have also replaced the normal proteases in the leather industry and detergent additive application due to their better performance. They have also been proved efficient in prion protein degradation. Above all, one of the major hurdles of enzyme industrial applications (cost effective production) can be achieved by using keratinous waste biomass, such as chicken feathers and hairs as fermentation substrate. Use of these low cost waste materials serves dual purposes: to reduce the fermentation cost for enzyme production as well as reducing the environmental waste load. The advent of keratinases has given new direction for waste management with industrial applications giving rise to green technology for sustainable development.     

A visual environment for the manipulation and integration of JAVA beans

MOTIVATION: Visual programming has the potential to allow non- programmers to redesign and rebuild applications to suit their individual needs. We have built such a visual programming environment, which allows non-programmers to interrogate and combine software components graphically to form new applications. As the needs of the biological community grow, so too will the need for more powerful and easy to use software tools. Intelligent visual programming environments will allow users to design and develop applications easily, so that they can concentrate on the application they wish to build rather than how it is to be done. RESULTS: The environment can read in JAVA Beans, and present relevant information about the beans to the user. The user can then graphically specify how they would like information to flow between the beans by performing simple docking operations. Unnecessary complexities associated with such visual design have been removed by providing intelligent docking of components and visual feedback. With such mechanisms, the complexities of building new applications are reduced. When the biologist has finished the visual construction, the design system is able to generate the new application automatically. The system has been designed specifically to meet the needs of the biological community, and a range of 'BioBeans' are being developed. These include beans for visualization (sequence displays and data visualizers), analysis (feature recognition, error detection) and communication (database access, URL retrieval, DDE communication). AVAILABILITY: Freely available. CONTACT: boyle@synomics.com