In Vitro Reconstitution of the Endoplasmic Reticulum.

Reconstitution of cellular organelles in vitro offers the possibility to perform quantitative and qualitative experiments in a controlled environment that cannot be done with the same accuracy in living cells. Following a previous report, the subsequent list of protocols describes how to reconstitute and quantify a tubular ER network in vitro based on purified microsomes from culture cells and cytosol from Xenopus laevis egg extracts. Biological material preparation and reconstitution assays require mostly basic laboratory instrumentation and chemicals, and can be executed without any specific training, making them appealing to a wide range of laboratories. Moreover, to promote conditions that are markedly more reflective of in vivo environments, this method describes for the first time in the literature, the purification of microsomes from HeLa cells in some detail. Basic Protocol 1 in this article describes the reconstitution process on different substrates including the associated fluorescence imaging process. Purification of ER microsomes and cytosol, both of which are needed for this approach, are described in detail in Support Protocols 1 and 2, respectively. Coating of surfaces with polyacrylamide gels is described in Support Protocol 3. Basic Protocol 2 outlines how to segment and skeletonize fluorescence images of ER networks, and how to quantify segment lengths between the network's branching points. The described quantitative evaluation provides a meaningful approach to analyze the topology and geometry of organelle structures. © 2017 by John Wiley & Sons, Inc.

Oscillating Electric Field Measures the Rotation Rate in a Native Rotary Enzyme.

Rotary enzymes are complex, highly challenging biomolecular machines whose biochemical working mechanism involves intersubunit rotation. The true intrinsic rate of rotation of any rotary enzyme is not known in a native, unmodified state. Here we use the effect of an oscillating electric (AC) field on the biochemical activity of a rotary enzyme, the vacuolar proton-ATPase (V-ATPase), to directly measure its mean rate of rotation in its native membrane environment, without any genetic, chemical or mechanical modification of the enzyme, for the first time. The results suggest that a transmembrane AC field is able to synchronise the steps of ion-pumping in individual enzymes via a hold-and-release mechanism, which opens up the possibility of biotechnological exploitation. Our approach is likely to work for other transmembrane ion-transporting assemblies, not only rotary enzymes, to determine intrinsic in situ rates of ion pumping.

Shaping the endoplasmic reticulum in vitro.

Organelles in eukaryotic cells often have complex shapes that deviate significantly from simple spheres. A prime example is the endoplasmic reticulum (ER) that forms an extensive network of membrane tubules in many mammalian cell types and in reconstitution assays in vitro. Despite the successful hunt for molecular determinants of ER shape we are still far from having a comprehensive understanding of ER network morphogenesis. Here, we have studied the hitherto neglected influence of the host substrate when reconstituting ER networks in vitro as compared to ER networks in vivo. In culture cells we observed cytoplasm-spanning ER networks with tubules being connected almost exclusively by three-way junctions and segment lengths being narrowly distributed around a mean length of about 1µm. In contrast, networks reconstituted from purified ER microsomes on flat glass or gel substrates of varying stiffness showed significantly broader length distributions with an up to fourfold larger mean length. Self-assembly of ER microsomes on small oil droplets, however, yielded networks that resembled more closely the native ER network of mammalian cells. We conclude from these observations that the ER microsomes' inherent self-assembly capacity is sufficient to support network formation with a native geometry if the influence of the host substrate's surface chemistry becomes negligible. We hypothesize that under these conditions the networks' preference for three-way junctions follows from creating 'starfish-shaped' vesicles when ER microsomes with a protein-induced spontaneous curvature undergo fusion.