Protein purification with C-terminal fusion of maltose binding protein

Application of the PHO5-gene-fusion technology to molecular genetics and biotechnology in yeast

Modern biological scientists employ numerous approaches for solving their problems. Among these approaches, the gene fusion is surely one of the well-established valuable tools in various fields of biological sciences. A wide range of applications have been developed to analyze a variety of biological phenomena such as transcriptional regulation, pre-mRNA processing, mRNA decay, translation, protein localization and even protein transport in both prokaryotic and eukaryotic organisms. Gene fusions were also used for the study of protein purification, protein structure, protein folding, protein-protein interaction and protein-DNA interaction. Here, we describe applications of gene fusion technology using the Saccharomyces cerevisiae PHO5 gene encoding repressible acid phosphatase to molecular genetics and biotechnology in S. cerevisiae. Using the PHO5 gene fusion as a reporter, we have identified several cis- and trans-acting genes of S. cerevisiae which are involved in splicing of pre-mRNA, biosynthesis of amino acids, ubiquitin-dependent protein degradation, signal transduction of oxygen and unsaturated fatty acid, regulation of transcription by the nucleosome and chromatin. The PHO5 gene fusions exhibiting the mating-type specific expression were also generated to develop a breeding technique for industrial yeast. It is concluded that the PHO5 gene fusion is extremely useful and should be further exploited to investigate various cellular steps of the eukaryotic gene expression.

Characterization of factors favoring the expression of soluble protozoan tubulin proteins in Escherichia coli

The alpha- and beta-tubulin genes of the parasitic protozoa Giardia duodenalis, Cryptosporidium parvum, and Encephalitozoon intestinalis have been overexpressed in soluble form using Escherichia coli-based expression systems. Several expression systems were compared in terms of the amount of soluble protein produced with different fusion partners, strains of E. coli BL21, and expression temperatures. The cleavability of the fusion partner was also assessed in terms of post-expression applications of the recombinant protein. The maltose-binding protein (MBP) and glutathione S-transferase (GST) fusion partners produced the highest expression levels for all six proteins without the formation of inclusion bodies. The expression system also provided a means of purifying the soluble protein using affinity and anion-exchange chromatography while minimizing protein losses. The yield and purity were therefore very high for both the MBP and GST systems. The tubulin monomers were demonstrated to be assembly-competent using a standard dimerization assay and also retained full antigenicity with monoclonal antibodies. This study presents several methods which are suitable for producing soluble tubulin monomers and, thus, circumventing the formation of inclusion bodies which necessitates re-folding of the tubulin.

Applications of novel affinity cassette methods: use of peptide fusion handles for the purification of recombinant proteins

In this article, recent progress related to the use of different types of polypeptide fusion handles or 'tags' for the purification of recombinant proteins are critically discussed. In addition, novel aspects of the molecular cassette concept are elaborated, together with areas of potential application of these fundamental principles in molecular recognition. As evident from this review, the use of these concepts provides a powerful strategy for the high throughput isolation and purification of recombinant proteins and their derived domains, generated from functional genomic or zeomic studies, as part of the bioprocess technology leading to their commercial development, and in the study of molecular recognition phenomena per se. In addition, similar concepts can be exploited for high sensitivity analysis and detection, for the characterisation of protein bait/prey interactions at the molecular level, and for the immobilisation and directed orientation of proteins for use as biocatalysts/biosensors.

Both subunits of the dimeric plant photoreceptor phytochrome require chromophore for stability of the far-red light-absorbing form

The dimeric plant photoreceptor phytochrome is converted from its inactive red light-absorbing form (Pr) into the active far-red light-absorbing form (Pfr) upon light absorption. Dynamics of Pfr generation and of thermal Pfr-to-Pr conversion are of fundamental importance for inducing adequate responses to light signals. Here, we analyzed the role of subunit interactions on spectroscopic properties of dimeric phytochrome A. Using a coexpression system and affinity chromatography, we prepared mixed phytochrome dimers that can incorporate the essential chromophore only in one subunit. We demonstrate that such mixed dimers have unaltered difference spectra. In contrast, dark reversion differed greatly between Pfr-Pfr homodimers and Pfr-Pr heterodimers, the former being about 100-fold more stable. Temperature dependence of reaction rates revealed an additional stabilization of about 4 kcal/mol in homodimers. Consequences of these findings are discussed in relation to the biological function of, and functional diversification between, phytochrome family members.