Recombinant protein expression

In this volume not all stress types are treated. Various aspects have been reviewed recently by various authors e.g. The effects of oxygen on recombinant protein expression by Konz et al. [2]. The Mechanisms by which bacterial cells respond to pH was considered in a Symposium in 1999 [3] and solvent effects were reviewed by de Bont in the article Solvent-tolerant bacteria in biocatalysis [4]. Therefore, these aspects are not considered in this volume. Influence of fluid dynamical stresses on micro-organism, animal and plant cells are in center of interest in this volume. In chapter 2, H.-J. Henzler discusses the quantitative evaluation of fluid dynamical stresses in various type of reactors with different methods based on investigations performed on laboratory an pilot plant scales. S. S. Yim and A. Shamlou give a general review on the effects of fluid dynamical and mechanical stresses on micro-organisms and bio-polymers in chapter 3. G. Ketzmer describes the effects of shear stress on adherent cells in chapter 4. Finally, in chapter 5, P. Kieran considers the influence of stress on plant cells. 

Goodacre, R. Karim, A. Kaderbhai, M. A. Kell, D. B. Rapid and quantitative analysis of recombinant protein expression using pyrolysis mass spectrometry and artificial neural networks Application to mammalian cytochrome b5 in Escherichia coli. J. Biotechnol. 1994,34,185-193. 

Winkler, M. A. Hickman, R. K. Golden, A. Aboleneen, H. Analysis of recombinant protein expression by MALDI-TOF mass spectrometry of bacterial colonies. BioTechniques 2000, 28,890,892,894-895. 

Sorensen, H.P. and Mortensen, K.K. (2005) Advanced genetic strategies for recombinant protein expression in Escherichia coli. Journal of Biotechnology, 115, 113-128. 

Transcriptional inhibitors could be used simultaneously. Rifampicin blocks chloroplast and mitocondrian RNA synthesis [23, 24], while tagetitoxin is a very specific inhibitor of chloroplast RNA polymerase [25]. Treatment with these antibiotics does not inhibit Rubisco SSU synthesis since the promoter is part of the nuclear genome, while the cytosolic ribosomes are not affected by streptomycin. Therefore SSU promoters can be used to drive transgene expression and facilitate the accumulation of recombinant proteins. Expressed proteins are targeted to a suitable cellular compartment, such as the cytoplasm, apoplastic space or chloroplast, depending on the nature of the protein. 

The best results are obtained when 100 mg I. 1 streptomycin is added 48-50 h after the initiation of germination. With streptomycin treatment, 100-400% increases in recombinant protein expression have been obtained. The accumulation of both Rubisco subunits is prevented (Figure 3.7). The specific activity of GUS increases 2.5-fold when streptomycin is used (Figure 3.8). 

Within each species, individual promoters resulted in distinct, tissue-dependent accumulation patterns. The cauliflower mosaic virus (CaMV) 35S promoter, for example, led to high-level accumulation in callus and leaves whereas the maize ubiqui-tin-1 promoter was the best choice for producing recombinant proteins in cereal seeds even though it is not in itself seed-specific [23]. The lack of such comparative studies for proteins other than rAbs makes it difficult to generalize an optimal expression strategy for all proteins. Tables 7.1 and 7.2 list recombinant proteins expressed in plants and provide details of the production system, promoters and other regulatory elements used in each case. 

High-level intracellular recombinant protein expression. The use of powerful viral promoters, such as promoters derived from the viral polyhedrin or P10 genes, can drive recombinant protein expression levels to 30-50 per cent of total intracellular protein. 

Baneyx, F. 1999. Recombinant protein expression in E. coli. Current Opinion in Biotechnology 10, 411-421. 

Nunoi and co-workers (1988) fractionated neutrophil cytoplasm by Mono Q anion-exchange chromatography and obtained three fractions (NCF-1, -2 and -3) that were active in the assembly of the oxidase. Independently, Volpp and colleagues (Volpp, Nauseef Clark, 1988) prepared antiserum from cytosolic factors that eluted from a GTP-affinity column, and this antiserum (Bl) recognised cytoplasmic factors of relative molecular masses 47 kDa and 66 kDa. It was later shown by this group that these cytosolic factors translocated to the plasma membrane during activation. NCF-1 was shown to contain the 47-kDa protein and NCF-2 the 66-kDa protein. Analysis of the defect in the cytosol of autosomal recessive CGD patients revealed that most of these (88%) lacked the 47-kDa protein (p41 -phox), whereas the remainder lacked the 66-kDa protein (p66-phox). Both of these components have now been cloned and recombinant proteins expressed. Interestingly, in the cell-free system, recombinant p47-phox and p66-phox can restore oxidase activity of the cytosol from autosomal recessive CGD patients who lack these components. 

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