Tuning
            <i>Escherichia coli</i>
            for membrane protein overexpression

Wagner, Samuel; Klepsch, Mirjam; Schlegel, Susan; Appel, Ansgar; Draheim, Roger Russell; Tarry, M.J.; Högbom, Martin; Wijk, Klaas J. van; Slotboom, Dirk Jan; Persson, Jan Olov; Gier, Jan‐Willem de

doi:10.1073/pnas.0804090105

Cited by 400 publications

(467 citation statements)

References 20 publications

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“…These mutant strains were recently shown to act by slowing expression from the strong T7 promoter. 7 These results clearly indicate that it is possible to reengineer E. coli with an improved ability to express membrane proteins.…”

Section: Introductionmentioning

confidence: 89%

“…For example, the C41 and C43 effects were found to be specific to the T7 promoter. 7 We therefore lysogenized all strains with kDE3 to introduce T7 RNA polymerase and tested the mutants for efficacy in a T7 promoter system. As shown in Figure 5, all of the mutants improved expression of Rv1337 behind the T7 promoter up to fourfold.…”

Section: Performance Of Selected Strains With a T7 Promotermentioning

confidence: 99%

“…It is likely that the reduced copy number in EXP-Rv1337-4 slows down expression to a level that the cells can more readily accommodate, much like the C41 and C43 strains do for expression from the T7 promoter. 7,13 …”

Section: Relative Plasmid Copy Number Of Mutantsmentioning

confidence: 99%

“…Wagner et al found that membrane protein expression could be improved considerably by fine tuning induction levels. 7 In addition, fusion to other proteins can help expression, and fusion to Mistic appears to be particularly helpful and is thought to help chaperone the protein into the membrane. 8 Also, the membrane protein itself can be mutated to generate more stable variants that express at higher levels, but the disadvantage is that the product may not reflect the native structure and function.…”

Section: Introductionmentioning

confidence: 99%

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Genetic selection system for improving recombinant membrane protein expression in E. coli

et al. 2009

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A major barrier to the physical characterization and structure determination of membrane proteins is low yield in recombinant expression. To address this problem, we have designed a selection strategy to isolate mutant strains of Escherichia coli that improve the expression of a targeted membrane protein. In this method, the coding sequence of the membrane protein of interest is fused to a C-terminal selectable marker, so that the production of the selectable marker and survival on selective media is linked to expression of the targeted membrane protein. Thus, mutant strains with improved expression properties can be directly selected. We also introduce a rapid method for curing isolated strains of the plasmids used during the selection process, in which the plasmids are removed by in vivo digestion with the homing endonuclease I-CreI. We tested this selection system on a rhomboid family protein from Mycobacterium tuberculosis (Rv1337) and were able to isolate mutants, which we call EXP strains, with up to 75-fold increased expression. The EXP strains also improve the expression of other membrane proteins that were not the target of selection, in one case roughly 90-fold.

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Section: Introductionmentioning

confidence: 89%

Section: Performance Of Selected Strains With a T7 Promotermentioning

confidence: 99%

Section: Relative Plasmid Copy Number Of Mutantsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Genetic selection system for improving recombinant membrane protein expression in E. coli

et al. 2009

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“…For example, the widely-used E. coli "Walker strains" (C41 and C43) apparently result in higher yields of recombinant membrane protein because their growth is not strongly inhibited upon induction. This results in increased biomass rather than increased "per cell" yields [25]. In yeast, however, the specific activity of some GPCRs is often lower when high cell density cultures are induced [26].…”

Section: Slowed Cell Growthmentioning

confidence: 99%

Mapping the yeast host cell response to recombinant membrane protein production: Relieving the biological bottlenecks

Ashe

Bill

2011

Biotechnology Journal

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Membrane proteins are targeted by over 50 % of marketed pharmaceuticals, and as most membrane proteins are not naturally abundant, they must be produced recombinantly for the structural biology that is a pre-requisite to structure-based drug design. Unfortunately, obtaining high yields of functional, recombinant membrane proteins remains a major bottleneck in contemporary bioscience. Trial-and-error optimisation studies have not (and cannot) reveal mechanistic details of the biology of recombinant protein production, highlighting the need for defined and rational optimisation strategies based upon experimental observation. To this end, we have published a transcriptome and subsequent genetic analysis that has identified genes implicated in high-yielding yeast cell factories. These results have highlighted a role for alterations to a cell's protein synthetic capacity in the production of high yielding cells: paradoxically, reduced protein synthesis favors higher yields of recombinant membrane protein. These results highlight a potential bottleneck at the protein folding or translocation stage of protein production.

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Overview of Electron Crystallography of Membrane Proteins: Crystallization and Screening Strategies Using Negative Stain Electron Microscopy

et al. 2013

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Electron cryomicroscopy, or cryoEM, is an emerging technique for studying the three-dimensional structures of proteins and large macromolecular machines. Electron crystallography is a branch of cryoEM in which structures of proteins can be studied at resolutions that rival those achieved by X-ray crystallography. Electron crystallography employs two-dimensional crystals of a membrane protein embedded within a lipid bilayer. The key to a successful electron crystallographic experiment is the crystallization, or reconstitution, of the protein of interest. This unit describes ways in which protein can be expressed, purified, and reconstituted into well-ordered twodimensional crystals. A protocol is also provided for negative stain electron microscopy as a tool for screening crystallization trials. When large and well-ordered crystals are obtained, the structures of both protein and its surrounding membrane can be determined to atomic resolution.

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Tuning Escherichia coli for membrane protein overexpression

Cited by 400 publications

References 20 publications

Genetic selection system for improving recombinant membrane protein expression in E. coli

Genetic selection system for improving recombinant membrane protein expression in E. coli

Mapping the yeast host cell response to recombinant membrane protein production: Relieving the biological bottlenecks

Overview of Electron Crystallography of Membrane Proteins: Crystallization and Screening Strategies Using Negative Stain Electron Microscopy

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