Detergent screening of the human voltage‐gated proton channel using fluorescence‐detection size‐exclusion chromatography

Agharkar, Amruta S.; Rzadkowolski, Jennifer; McBroom, Mandy; Gonzales, Eric B.

doi:10.1002/pro.2492

Cited by 7 publications

(2 citation statements)

References 39 publications

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“…57 Green fluorescent protein (GFP) has also gained significant utility in tagging ion channels to monitor expression in cells and to facilitate ion channel purification. [58][59][60] The use of epitope tags has been comprehensively reviewed by Maue. 57 Controlling the timing of gene expression is another method that can be used to allow overexpression and reduce the issues associated with channels that cause toxicity.…”

Section: Antigen and Immunogen Formatsmentioning

confidence: 99%

Discovery of Functional Antibodies Targeting Ion Channels

2015

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Ion channels play critical roles in physiology and disease by modulation of cellular functions such as electrical excitability, secretion, cell migration, and gene transcription. Ion channels represent an important target class for drug discovery that has been largely addressed, to date, using small-molecule approaches. A significant opportunity exists to target these channels with antibodies and alternative formats of biologics. Antibodies display high specificity and affinity for their target antigen, and they have the potential to target ion channels very selectively. Nevertheless, isolating antibodies to this target class is challenging due to the difficulties in expression and purification of ion channels in a format suitable for antibody drug discovery in addition to the complexity of screening for function. In this article, we will review the current state of ion channel biologics discovery and the progress that has been made. We will also highlight the challenges in isolating functional antibodies to these targets and how these challenges may be addressed. Finally, we also illustrate successful approaches to isolating functional monoclonal antibodies targeting ion channels by way of a number of case studies drawn from recent publications.

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Section: Antigen and Immunogen Formatsmentioning

confidence: 99%

Discovery of Functional Antibodies Targeting Ion Channels

2015

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“…Bicelles are of unique interest for membrane protein studies because unlike their detergent counterpart, they contain a bilayered planar region, which captures a true membrane-like environment (Figure 1) [4, 5]. In membrane protein studies, choosing the optimal detergent or lipid system usually necessitates a screening of potential candidates because not all systems are universally adaptable to all types of membrane proteins [10 – 13]. In this study, a novel lipid-detergent complex was prepared with DMPC, the long-chain phospholipid, and a nonionic detergent, pentaethylene glycol n-octyl ether or C 8 E 5 (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

The best of both worlds: A new lipid complex has micelle and bicelle-like properties

Rieth

2018

Preprint

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The utility of detergent micelle and bicelle systems has been demonstrated to be a valuable tool for the study of membrane protein interactions and in structural studies. Bicelles are distinguished from micelles in that they contain a lipid bilayer that mimics the plasma membrane of cells making it more native-like than its detergent micelle counter-part. Bicelles are typically comprised of a long-chain phospholipid such as 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and either a short-chain phospholipid, typically 1,2-dihexanoyl-sn-glycero-3phosphocholine (DHPC), or a bile-salt derivative such as CHAPS or CHAPSO. In solution DMPC and DHPC bicelles assume a discoidal structure comprised of a heterogeneous arrangement where the short-chain lipids gather around the rim of the disk and the long-chain lipids form the flat, bilayer region of the bicelle. Aside from DHPC, CHAPS and CHAPSO few other detergents have reportedly been investigated for their ability to form bicelles with DMPC. In this study, the detergent, C8E5, was used to prepare mixtures with DMPC to determine if it adopts properties similar to DMPC-DHPC bicelles. Mixtures were evaluated using sedimentation equilibrium, 31 Pphosphorus NMR, and light scattering and compared to DMPC-DHPC bicelles. Interestingly, mixtures of DMPC and C8E5 assumed a spherical-shaped micellar structure, not the predicted discoidal shape. DMPC-C8E5 mixtures retain interesting properties rendering them particularly advantageous in studies of membrane protein interactions and hold promise as vehicles for drug delivery.

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