Reviews in Molecular Biotechnology最新文献

Self-assembly of reactive amphiphilic block copolymers is used to prepare nanostructured hydrogels with exceptional permeability properties, vesicular structures and planar, freestanding membranes in aqueous solution. Although the underlying block copolymer membranes are two–three-fold thicker than conventional lipid bilayers, they can be regarded as mimetic of biological membranes and can be used as a matrix for membrane-spanning proteins. Surprisingly, the proteins remain functional, despite the extreme thickness of the membranes and even after polymerization of the reactive block copolymers. The unique combination of block copolymers with membrane proteins allows the preparation of mechanically stable, defect-free membranes and nanocapsules that have highly selective permeability and/or specific recognition sites. This is documented by some representative examples.

Self-assembled monolayers of thiolated compounds are used as promoters for protein–electrode reactions. They provide an anchor group based on thiol chemisorptions and also a functional group for effective interaction with the protein. These interactions are often governed by electrostatic attraction. For example, for positively charged proteins, such as cytochrome c and the selenoprotein glutathione peroxidase, mercaptoalkanoic acids have been used. Clay modification of the electrode surface has been found to facilitate the heterogeneous electron transfer process for heme proteins, e.g. cytochrome c, cytochrome P450 and myoglobin. Interestingly, nucleic acids at carbon electrodes and thiol-modified double stranded oligonucleotides act as promoters of the redox communication to proteins, whereas the mechanism is still subject to controversy interpretations. By interacting the protein immobilised at the electrode with species in solution, signal chains have been constructed. The interaction can result in a simple co-ordination or redox reaction, depending on the nature of the reaction partners. For analytical purposes, e.g. biosensors, the electrochemical redox conversion of the immobilised protein is evaluated.

This paper reviews recent advances in biosensors contributed mainly by our laboratory. The biosensors, based on the new immobilization materials — sol–gel organic–inorganic hybrid materials, cryohydrogel (or organohydrogel) and bilayer lipid membranes, are presented. The analytical performances of the biosensors are discussed. Applications of the biosensors in extreme environment are emphasized. A new generation of biosensors — surface plasmon resonance biosensors and capacitance biosensors, are also described.

Different procedures used for constructing protein/enzyme-modified electrodes are examined, in particular adsorption, covalent attachment and film deposition. The performances of such modified electrodes with electroactive proteins or enzymes attached to their active surface are examined, especially in the case of c-type cytochromes, hydrogenases and glucose oxidase. Another strategy presented in this review consists of the use of membrane electrodes with an electroactive protein imprisoned between a dialysis membrane and the electrode surface. The versatility and other advantages of such a procedure are underlined. Applications of membrane electrodes to the bioremediation of soils and effluents and as models for investigating interactions between proteins and soils are described.

Assay and screening methods for bioactive substances based on cellular signaling pathways are presented. Examples include: (1) intracellular protein phosphorylation and protein–protein interaction, (1-i) a new assay method for evaluating chemical selectivity of agonists for insulin signaling pathways based on agonist-induced phosphorylation of a target peptide, (1-ii) an SPR-based screening method for agonist selectivity for insulin signaling pathways based on the binding of phosphotyrosine to its specific binding protein, (1-iii) a fluorescent indicator for tyrosine phosphorylation-based insulin signaling pathways, and (1-iv) split luciferase as an optical probe for detecting protein–protein interactions in mammalian cells based on protein splicing; (2) a screening method for antigen-specific IgE using mast cells based on intracellular calcium signaling; (3) a screening method for substrates of multidrug resistance-associated protein (MRP); and (4) fluorescent indicators for cyclic GMP based on cyclic GMP-dependent protein kinase Iα and green fluorescent proteins.

Development of reagentless biosensors implies the tight and functional immobilisation of biological recognition elements on transducer surfaces. Specifically, in the case of amperometric enzyme electrodes, electron-transfer pathways between the immobilised redox protein and the electrode surface have to be established allowing a fast electron transfer concomitantly avoiding free-diffusing redox species. Based on the specific nature of different redox proteins and non-manual immobilisation procedures possible biosensor designs are discussed, namely biosensors based on (i) direct electron transfer between redox proteins and electrodes modified with self-assembled monolayers; (ii) anisotropic orientation of redox proteins at monolayer-modified electrodes; (iii) electron-transfer cascades via redox hydrogels; and (iv) electron-transfer via conducting polymers.

Direct real-time electrochemical measurements have offered new insight into the importance of free radical interplay in a number of cell culture and in vivo models of neurodegenerative processes. This review highlights investigations carried out in this laboratory of real-time superoxide and nitric oxide free radical generation, and presents evidence of complex inter-relationships between these species. These include: a novel function for astrocytic nitric oxide synthase in controlling neuronal nitric oxide availability; and the demonstration that extracellular superoxide flux can lead to the generation of NO by glial cells. The possible consequences of these interactions are discussed.

Bioelectronics is a progressing interdisciplinary research field that involves the integration of biomaterials with electronic transducers such as electrodes, field-effect transistors or piezoelectric crystals. Surface engineering of biomaterials such as enzymes, antigen-antibodies or DNA on the electronic supports controls the electrical properties of the biomaterial/transducer interface and enables the electronic transduction of biorecognition events, or biocatalyzed transformation, on the transducers. The development of biosensor systems of tailored sensitivites and specificities represents a major advance in bioelectronics.

A review is presented dealing with electrocatalytic NADH oxidation at mediator-modified electrodes, summarising the history of the topic, as well as the present state of the art.