Evaluation of cell‐free protein synthesis for the crystallization of membrane proteins – a case study on a member of the glutamate transporter family from <i>Staphylothermus marinus</i>

Jaehme, Michael; Michel, Hartmut

doi:10.1111/febs.12105

Cited by 7 publications

(5 citation statements)

References 65 publications

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“…The cell-free methods are expected to become the standard procedures for crystallography-oriented membrane protein preparation, as they overcome a number of difficulties that unavoidably accompany the cell-based recombinant expression methods with respect to the preparation of mammalian membrane proteins. These expectations have been mentioned previously 38 39 , but have not been met successfully in the crystallography of mammalian membrane proteins at atomic resolution. In this study, we applied the P-MF and S-MF methods to the cell-free protein production and purification of mammalian α-helical membrane proteins.…”

Section: Discussionmentioning

confidence: 91%

Cell-free methods to produce structurally intact mammalian membrane proteins

Shinoda

Shinya

Ito

et al. 2016

Sci Rep

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The crystal structures of four membrane proteins, from bacteria or a unicellular alga, have been solved with samples produced by cell-free protein synthesis. In this study, for mammalian membrane protein production, we established the precipitating and soluble membrane fragment methods: membrane proteins are synthesized with the Escherichia coli cell-free system in the presence of large and small membrane fragments, respectively, and are simultaneously integrated into the lipid environments. We applied the precipitating membrane fragment method to produce various mammalian membrane proteins, including human claudins, glucosylceramide synthase, and the γ-secretase subunits. These proteins were produced at levels of about 0.1–1.0 mg per ml cell-free reaction under the initial conditions, and were obtained as precipitates by ultracentrifugation. Larger amounts of membrane proteins were produced by the soluble membrane fragment method, collected in the ultracentrifugation supernatants, and purified directly by column chromatography. For several proteins, the conditions of the membrane fragment methods were further optimized, such as by the addition of specific lipids/detergents. The functional and structural integrities of the purified proteins were confirmed by analyses of their ligand binding activities, size-exclusion chromatography profiles, and/or thermal stabilities. We successfully obtained high-quality crystals of the complex of human claudin-4 with an enterotoxin.

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Section: Discussionmentioning

confidence: 91%

Cell-free methods to produce structurally intact mammalian membrane proteins

Shinoda

Shinya

Ito

et al. 2016

Sci Rep

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“…To investigate whether our in vitro subunit reassembly procedure is applicable to other multimeric transporters, we initially tested the procedure on Glt Sm , a glutamate transporter homolog from Staphylothermus marinus that shares 58% sequence identity to Glt Ph ( Figure 5A )( Jaehme and Michel, 2013 ). We observed that SDS dissociated the Glt Sm transporter and that the dissociated subunits can be reassembled back to the trimeric state upon dilution of SDS coupled with protein incorporation into lipid vesicles ( Figure 5B ).…”

Section: Resultsmentioning

confidence: 99%

“…Glt Sm was amplified by PCR from a plasmid carrying the gene for a Glt Sm -GFP fusion protein ( Jaehme and Michel, 2013 ) and cloned into a pBAD-HisA vector (Fisher Scientific) with a N-terminal His 6 tag. The Glt Sm vector was transformed into TOP10 cells (Fisher Scientific) for protein expression.…”

Section: Methodsmentioning

confidence: 99%

A facile approach for the in vitro assembly of multimeric membrane transport proteins

Riederer

Focke

Georgieva

et al. 2018

eLife

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Membrane proteins such as ion channels and transporters are frequently homomeric. The homomeric nature raises important questions regarding coupling between subunits and complicates the application of techniques such as FRET or DEER spectroscopy. These challenges can be overcome if the subunits of a homomeric protein can be independently modified for functional or spectroscopic studies. Here, we describe a general approach for in vitro assembly that can be used for the generation of heteromeric variants of homomeric membrane proteins. We establish the approach using GltPh, a glutamate transporter homolog that is trimeric in the native state. We use heteromeric GltPh transporters to directly demonstrate the lack of coupling in substrate binding and demonstrate how heteromeric transporters considerably simplify the application of DEER spectroscopy. Further, we demonstrate the general applicability of this approach by carrying out the in vitro assembly of VcINDY, a Na+-coupled succinate transporter and CLC-ec1, a Cl-/H+ antiporter.

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“…The alternate technology that eliminates most of these drawbacks is cell‐free in vitro protein synthesis. Presently, only a few crystallography groups have employed this technology to prepare soluble proteins and, recently, membrane proteins . In the case of RNAs as well, specific drawbacks have to be overcome for the preparation of homogeneous samples for crystallization.…”

Section: Crystallogenesis In the Era Of Technologies And Structural Gmentioning

confidence: 99%

A historical perspective on protein crystallization from 1840 to the present day

Giegé

2013

FEBS J

106

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Protein crystallization has been known since 1840 and can prove to be straightforward but, in most cases, it constitutes a real bottleneck. This stimulated the birth of the biocrystallogenesis field with both ‘practical’ and ‘basic’ science aims. In the early years of biochemistry, crystallization was a tool for the preparation of biological substances. Today, biocrystallogenesis aims to provide efficient methods for crystal fabrication and a means to optimize crystal quality for X‐ray crystallography. The historical development of crystallization methods for structural biology occurred first in conjunction with that of biochemical and genetic methods for macromolecule production, then with the development of structure determination methodologies and, recently, with routine access to synchrotron X‐ray sources. Previously, the identification of conditions that sustain crystal growth occurred mostly empirically but, in recent decades, this has moved progressively towards more rationality as a result of a deeper understanding of the physical chemistry of protein crystal growth and the use of idea‐driven screening and high‐throughput procedures. Protein and nucleic acid engineering procedures to facilitate crystallization, as well as crystallization methods in gelled‐media or by counter‐diffusion, represent recent important achievements, although the underlying concepts are old. The new nanotechnologies have brought a significant improvement in the practice of protein crystallization. Today, the increasing number of crystal structures deposited in the Protein Data Bank could mean that crystallization is no longer a bottleneck. This is not the case, however, because structural biology projects always become more challenging and thereby require adapted methods to enable the growth of the appropriate crystals, notably macromolecular assemblages.

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Evaluation of cell‐free protein synthesis for the crystallization of membrane proteins – a case study on a member of the glutamate transporter family from Staphylothermus marinus

Cited by 7 publications

References 65 publications

Cell-free methods to produce structurally intact mammalian membrane proteins

Cell-free methods to produce structurally intact mammalian membrane proteins

A facile approach for the in vitro assembly of multimeric membrane transport proteins

A historical perspective on protein crystallization from 1840 to the present day

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