Protein expression-yeast.

Yeast is an excellent system for the expression of recombinant eukaryotic proteins. Both endogenous and heterologous proteins can be overexpressed in yeast (Phan et al., 2001; Ton and Rao, 2004). Because yeast is easy to manipulate genetically, a strain can be optimized for the expression of a specific protein. Many eukaryotic proteins contain posttranslational modifications that can be performed in yeast but not in bacterial expression systems. In comparison with mammalian cell culture expression systems, growing yeast is both faster and less expensive, and large-scale cultures can be performed using fermentation. While several different yeast expression systems exist, this chapter focuses on the budding yeast Saccharomyces cerevisiae and will briefly describe some options to consider when selecting vectors and tags to be used for protein expression. Throughout this chapter, the expression and purification of yeast eIF3 is shown as an example alongside a general scheme outline.

Reconstitution of eukaryotic translation initiation factor 3 by co-expression of the subunits in a human cell-derived in vitro protein synthesis system.

Many biologically important factors are composed of multiple subunits. To study the structure and function of the protein complexes and the role of each subunit, a rapid and efficient method to prepare recombinant protein complexes is needed. In this work, we established an in vitro reconstitution system of eukaryotic translation initiation factor (eIF) 3, a protein complex consisting of 11 distinct subunits. A HeLa cell-derived in vitro coupled transcription/translation system was programmed with multiple plasmids encoding the 11 eIF3 subunits in total. After incubation for several hours, the eIF3 complex was purified through tag-dependent affinity chromatography. When eIF3l, one of the nonessential subunits of eIF3, was not expressed, the eIF3 complex that was devoid of eIF3l was still obtained. Both the 11 subunits complex and the eIF3l-less complex were as active as native eIF3 as observed by a reconstituted translation initiation assay system. In conclusion, the cell-free co-expression system should be a feasible and rapid system to reconstitute protein complexes.

Overexpression and purification of mammalian mitochondrial translational initiation factor 2 and initiation factor 3.

Two mammalian mitochondrial initiation factors have been identified. Initiation factor 2 (IF2(mt)) selects the initiator tRNA (fMet-tRNA) and promotes its binding to the ribosome. Initiation factor 3 (IF3(mt)) promotes the dissociation of the 55S mitochondrial ribosome into subunits and may play additional, less-well-understood, roles in initiation complex formation. Native bovine IF2(mt) was purified from liver a number of years ago. The yield of this factor is very low making biochemical studies difficult. The cDNA for bovine IF2(mt) was expressed in Escherichia coli under the control of the T7 polymerase promoter in a vector that provides a His(6)-tag at the C-terminus of the expressed protein. This factor was expressed in E. coli and purified by chromatography on Ni-NTA resins. The expressed protein has a number of degradation products in partially purified preparations and this factor is then further purified by high-performance liquid chromatography or gravity chromatography on anion exchange resins. IF3(mt) has never been purified from any mammalian system. However, the cDNA for this protein can be identified in the expressed sequence tag (EST) libraries. The portion of the sequence encoding the region of human IF3(mt) predicted to be present in the mitochondrially imported form of this factor was cloned and expressed in E. coli using a vector that provides a C-terminal His(6)-tag. The tagged factor is partially purified on Ni-NTA resins. However, a major proteolytic fragment arising from a defined cleavage of this protein is present in these preparations. This contaminant can be removed by a single step of high-performance liquid chromatography on a cation exchange resin. Alternatively, the mature form of IF3(mt) can be purified by two sequential passes through a gravity S-Sepharose column.

Identification and characterization of a proteolysis-resistant fragment containing the PCI domain in the Arabidopsis thaliana INT6/eIF3e translation factor.

The PCI domain comprises approx 200 amino acids and is found in subunits of the eukaryotic translation initiation factor 3 (eIF3), the 26S proteasome and the COP9/signalosome complexes. The PCI domain is involved in protein-protein interaction, and mouse INT6 truncated proteins lacking the PCI domain show cell malignanttransforming activity. In this work, the Arabidopsis thaliana INT6/eIF3e (AtINT6) protein was dissected using limited proteolysis, and a protease-resistant fragment containing the PCI domain was identified. Based on mass spectrometry analyses of the protease-resistant fragments and on secondary structure prediction, AtINT6-truncated proteins were cloned and expressed in Escherichia coli. Stability studies using thermal unfolding followed by circular dichroism revealed a midpoint transition temperature of 44 degrees C for the full-length AtINT6 protein, whereas the truncated proteins comprising residues 125-415 (AtINT6TR2) and 172-415 (AtINT6TR3) showed transition temperatures of 49 and 58 degrees C, respectively. AtINT6TR3 contains the PCI domain with additional amino acids at the N and C termini. It shows high solubility, and together with the high thermal stability, should facilitate further characterization of the PCI domain structure, which is important to understand its function in protein- protein interaction.

Characterization of eIF3k: a newly discovered subunit of mammalian translation initiation factor elF3.

Mammalian translation initiation factor 3 (eIF3) is a multisubunit complex containing at least 12 subunits with an apparent aggregate mass of approximately 700 kDa. eIF3 binds to the 40S ribosomal subunit, promotes the binding of methionyl-tRNAi and mRNA, and interacts with several other initiation factors to form the 40S initiation complex. Human cDNAs encoding 11 of the 12 subunits have been isolated previously; here we report the cloning and characterization of a twelfth subunit, a 28-kDa protein named eIF3k. Evidence that eIF3k is present in the eIF3 complex was obtained. A monoclonal anti-eIF3a (p170) Ig coimmunoprecipitates eIF3k with the eIF3 complex. Affinity purification of histidine-tagged eIF3k from transiently transfected COS cells copurifies other eIF3 subunits. eIF3k colocalizes with eIF3 on 40S ribosomal subunits. eIF3k coexpressed with five other 'core' eIF3 subunits in baculovirus-infected insect cells, forms a stable, immunoprecipitatable, complex with the 'core'. eIF3k interacts directly with eIF3c, eIF3g and eIF3j by glutathione S-transferase pull-down assays. Sequences homologous with eIF3k are found in the genomes of Caenorhabitis elegans, Arabidopsis thaliana and Drosophila melanogaster, and a homologous protein has been reported to be present in wheat eIF3. Its ubiquitous expression in human tissues, yet its apparent absence in Saccharomyces cerevisiae and Schizosaccharomyces pombe, suggest a unique regulatory role for eIF3k in higher organisms. The studies of eIF3k complete the characterization of mammalian eIF3 subunits.

Mammalian translation initiation factor eIF1 functions with eIF1A and eIF3 in the formation of a stable 40 S preinitiation complex.

We have examined the role of the mammalian initiation factor eIF1 in the formation of the 40 S preinitiation complex using in vitro binding of initiator Met-tRNA (as Met-tRNA(i).eIF2.GTP ternary complex) to 40 S ribosomal subunits in the absence of mRNA. We observed that, although both eIF1A and eIF3 are essential to generate a stable 40 S preinitiation complex, quantitative binding of the ternary complex to 40 S subunits also required eIF1. The 40 S preinitiation complex contained, in addition to eIF3, both eIF1 and eIF1A in a 1:1 stoichiometry with respect to the bound Met-tRNA(i). These three initiation factors also bind to free 40 S subunits, and the resulting complex can act as an acceptor of the ternary complex to form the 40 S preinitiation complex (40 S.eIF3.eIF1.eIF1A.Met-tRNA(i).eIF2.GTP). The stable association of eIF1 with 40 S subunits required the presence of eIF3. In contrast, the binding of eIF1A to free 40 S ribosomes as well as to the 40 S preinitiation complex was stabilized by the presence of both eIF1 and eIF3. These studies suggest that it is possible for eIF1 and eIF1A to bind the 40 S preinitiation complex prior to mRNA binding.