Marc J. Wander scite author profile

Intrinsic membrane proteins must usually be extracted from the native membrane with the aid of synthetic amphiphiles and then stabilized in a soluble form before detailed structural and functional characterization is possible. We describe new amphiphiles with unusual architectures that are useful for extraction and stabilization of photosynthetic protein superassemblies from bacterial membranes. Our results suggest that incorporating branch points in both the hydrophilic and lipophilic portions can lead to favorable amphiphile behavior.

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Optimizing multi-step B-side charge separation in photosynthetic reaction centers from Rhodobacter capsulatus

Faries

Kressel

Dylla

et al. 2016

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Using high-throughput methods for mutagenesis, protein isolation and charge-separation functionality, we have assayed 40 Rhodobacter capsulatus reaction center (RC) mutants for their P(+)QB(-) yield (P is a dimer of bacteriochlorophylls and Q is a ubiquinone) as produced using the normally inactive B-side cofactors BB and HB (where B is a bacteriochlorophyll and H is a bacteriopheophytin). Two sets of mutants explore all possible residues at M131 (M polypeptide, native residue Val near HB) in tandem with either a fixed His or a fixed Asn at L181 (L polypeptide, native residue Phe near BB). A third set of mutants explores all possible residues at L181 with a fixed Glu at M131 that can form a hydrogen bond to HB. For each set of mutants, the results of a rapid millisecond screening assay that probes the yield of P(+)QB(-) are compared among that set and to the other mutants reported here or previously. For a subset of eight mutants, the rate constants and yields of the individual B-side electron transfer processes are determined via transient absorption measurements spanning 100 fs to 50 μs. The resulting ranking of mutants for their yield of P(+)QB(-) from ultrafast experiments is in good agreement with that obtained from the millisecond screening assay, further validating the efficient, high-throughput screen for B-side transmembrane charge separation. Results from mutants that individually show progress toward optimization of P(+)HB(-)→P(+)QB(-) electron transfer or initial P*→P(+)HB(-) conversion highlight unmet challenges of optimizing both processes simultaneously.

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High Throughput Engineering to Revitalize a Vestigial Electron Transfer Pathway in Bacterial Photosynthetic Reaction Centers

Faries

Kressel

Wander

et al. 2012

Journal of Biological Chemistry

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Background: Bacterial reaction centers catalyze light-induced transmembrane electron transport using only one of two chemically equivalent pathways. Results: Multiplexed screening uncovers semirandom mutations that unexpectedly activate the unused pathway by employing ionizable residues. Conclusion: High throughput mutagenesis approaches reveal structure/function relationships that govern electron transfer efficiency. Significance: Directed molecular evolution can reveal principles that enable efficient, unidirectional, transmembrane electron transfer for the design of de novo pathways or biomimetic devices.

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High yield of secondary B-side electron transfer in mutant Rhodobacter capsulatus reaction centers

Kressel

Faries

Wander

et al. 2014

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Hydrophobic variants of ganglio-tripod amphiphiles for membrane protein manipulation

Chae

Cho

Wander

et al. 2014

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Membrane proteins operate in unique cellular environments. Once removed from their native context for the purification that is required for most types of structural or functional analyses, they are prone to denature if not properly stabilized by membrane mimetics. Detergent micelles have prominently been used to stabilize membrane proteins in aqueous environments as their amphipathic nature allows for shielding of the hydrophobic surfaces of these bio-macromolecules while supporting solubility and monodispersity in water. This study expands the utility of branched diglucoside-bearing tripod agents, designated ganglio-tripod amphiphiles, with introduction of key variations in their hydrophobic sections and shows how these latter elements can be fine-tuned to maximize membrane protein solubilization while preserving characteristics of these molecules that afford stabilization of rather fragile assemblies. Their efficacy rivals benchmark detergents heavily used today, such as n-dodecyl–β-D-maltoside.

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Marc J. Wander

Glycotripod Amphiphiles for Solubilization and Stabilization of a Membrane‐Protein Superassembly: Importance of Branching in the Hydrophilic Portion

Optimizing multi-step B-side charge separation in photosynthetic reaction centers from Rhodobacter capsulatus

High Throughput Engineering to Revitalize a Vestigial Electron Transfer Pathway in Bacterial Photosynthetic Reaction Centers

High yield of secondary B-side electron transfer in mutant Rhodobacter capsulatus reaction centers

Hydrophobic variants of ganglio-tripod amphiphiles for membrane protein manipulation

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