Michael Gerrits scite author profile

The genetic code is universal, but recombinant protein expression in heterologous systems is often hampered by divergent codon usage. Here, we demonstrate that reprogramming by standardized multi-parameter gene optimization software and de novo gene synthesis is a suitable general strategy to improve heterologous protein expression. This study compares expression levels of 94 full-length human wt and sequence-optimized genes coding for pharmaceutically important proteins such as kinases and membrane proteins in E. coli. Fluorescence-based quantification revealed increased protein yields for 70% of in vivo expressed optimized genes compared to the wt DNA sequences and also resulted in increased amounts of protein that can be purified. The improvement in transgene expression correlated with higher mRNA levels in our analyzed examples. In all cases tested, expression levels using wt genes in tRNA-supplemented bacterial strains were outperformed by optimized genes expressed in non-supplemented host cells.

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Synthesis of membrane proteins in eukaryotic cell‐free systems

Sachse

Wüstenhagen

Šamalíková

et al. 2012

Engineering in Life Sciences

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Cell-free protein synthesis (CFPS) is a valuable method for the fast expression of difficult-to-express proteins as well as posttranslationally modified proteins. Since cell-free systems circumvent possible cytotoxic effects caused by protein overexpression in living cells, they significantly enlarge the scale and variety of proteins that can be characterized. We demonstrate the high potential of eukaryotic CFPS to express various types of membrane proteins covering a broad range of structurally and functionally diverse proteins. Our eukaryotic cell-free translation systems are capable to provide high molecular weight membrane proteins, fluorescent-labeled membrane proteins, as well as posttranslationally modified proteins for further downstream analysis.

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Chapter 2 In Vitro Synthesis of Posttranslationally Modified Membrane Proteins

Kubick

Gerrits

Merk

et al. 2009

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Site-specific PEGylation of proteins by a Staudinger-phosphite reaction

et al. 2010

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Michael Gerrits

Chemoselective Staudinger‐Phosphite Reaction of Azides for the Phosphorylation of Proteins

Gene optimization mechanisms: A multi‐gene study reveals a high success rate of full‐length human proteins expressed in Escherichia coli

Synthesis of membrane proteins in eukaryotic cell‐free systems

Chapter 2 In Vitro Synthesis of Posttranslationally Modified Membrane Proteins

Site-specific PEGylation of proteins by a Staudinger-phosphite reaction

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