Multilayered or stacked lipid membranes are a common principle in biology and have various functional advantages compared to single‐lipid membranes, such as their ability to spatially organize processes, compartmentalize molecules, and greatly increase surface area and hence membrane protein concentration. Here, a supramolecular assembly of a multilayered lipid membrane system is reported in which poly‐l‐lysine electrostatically links negatively charged lipid membranes. When suitable membrane enzymes are incorporated, either an ubiquinol oxidase (cytochrome bo 3 from Escherichia coli) or an oxygen tolerant hydrogenase (the membrane‐bound hydrogenase from Ralstonia eutropha), cyclic voltammetry (CV) reveals a linear increase in biocatalytic activity with each additional membrane layer. Electron transfer between the enzymes and the electrode is mediated by the quinone pool that is present in the lipid phase. Using atomic force microscopy, CV, and fluorescence microscopy it is deduced that quinones are able to diffuse between the stacked lipid membrane layers via defect sites where the lipid membranes are interconnected. This assembly is akin to that of interconnected thylakoid membranes or the folded lamella of mitochondria and has significant potential for mimicry in biotechnology applications such as energy production or biosensing.
In article number https://doi.org/10.1002/adfm.201606265 Lars J. C. Jeuken and co‐workers use a layer‐by‐layer assembly of lipid bilayers to multiply the surface concentration of electroactive membrane enzymes at electrodes. The interconnected membrane multilayers, akin to those of thylakoid membranes, create a material that exhibits a linear increase in bioelectrocatalytic activity with each additional enzyme‐containing membrane layer (containing either ubiquinol oxidase or an oxygen‐tolerant hydrogenase).
Pancreatic β-cells have the unique ability to couple glucose metabolism to insulin secretion. This capacity is generally attributed to the ability of ATP to inhibit KATP channels, and the consequent β-cell membrane depolarization and excitation. This notion has recently been challenged by a study which demonstrated that high glucose (HG) downregulates the cell surface KATP channels, and thereby leads to β-cell depolarisation and excitation. The authors attributed the downregulation to HG-induced protein kinase C (PKC) activation and the consequent increase in channel endocytosis. This interpretation, however, is inconsistent with our previous findings that PKC activation does not affect endocytosis. To address this controversy, we revisited the problem: we have used cell biological and electrophysiological approaches combined with the pharmacological activator of PKC, PMA (phorbol 12-myristate 13-acetate). We first confirm that PKC does not play a role in KATP channel endocytosis; instead, it downregulates the channel by promoting lysosomal degradation coupled with reduced recycling. We then show that (i) mutation of the dileucine motif ( 355 LL 356 ) in the Cterminal domain of the Kir6.2 subunit of the KATP channel complex prevents lysosomal degradation; (ii) lysosomal targeting is mediated by the EHD (Eps15 homology domaincontaining) proteins; and (iii) the PKC isoform responsible for channel degradation is PKC.Taken together with the published data, we suggest that HG promotes β-cell excitability via two mechanisms: ATP-dependent channel inhibition and ATP-independent, PKC-dependent channel degradation. The results likely have implications for glucose induced biphasic insulin secretion.
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