Boštjan Rituper

High-resolution membrane capacitance measurements for the study of exocytosis and endocytosis

In order to understand exocytosis and endocytosis, it is necessary to study these processes directly. An elegant way to do this is by measuring plasma membrane capacitance (Cm), a parameter proportional to cell surface area, the fluctuations of which are due to fusion and fission of secretory and other vesicles. Here we describe protocols that enable high-resolution Cm measurements in macroscopic and microscopic modes. Macroscopic mode, performed in whole-cell configuration, is used for measuring bulk Cm changes in the entire membrane area, and it enables the introduction of exocytosis stimulators or inhibitors into the cytosol through the patch pipette. Microscopic mode, performed in cell-attached configuration, enables measurements of Cm with attofarad resolution and allows characterization of fusion pore properties. Although we usually apply these protocols to primary pituitary cells and astrocytes, they can be adapted and used for other cell types. After initial hardware setup and culture preparation, several Cm measurements can be performed daily.

Hypotonicity and peptide discharge from a single vesicle

Neuroendocrine secretory vesicles discharge their cargo in response to a stimulus, but the nature of this event is poorly understood. We studied the release of the pituitary hormone prolactin by hypotonicity, because this hormone also contributes to osmoregulation. In perfused rat lactotrophs, hypotonicity resulted in a transient increase followed by a sustained depression of prolactin release, as monitored by radioimmunoassay. In single cells imaged by confocal microscopy, hypotonicity elicited discharge of the fluorescently labeled atrial natriuretic peptide cargo from approximately 2% of vesicles/cell. In contrast, KCl-induced depolarization resulted in a response of approximately 10% of vesicles/cell, with different unloading/loading time course of the two fluorescent probes. In cell-attached studies, discrete changes in membrane capacitance were recorded in both unstimulated and stimulated conditions, reflecting single vesicle fusion/fissions with the plasma membrane. In stimulated cells, the probability of occurrence of full fusion events was low and unchanged, whereas over 95% of fusion events were transient, with the open fusion pore probability, the average pore dwell-time, the frequency of occurrence, and the fusion pore conductance increased. Hypotonicity only rarely elicited new fusion events in silent membrane patches. The results indicate that, in hypotonicity-stimulated lactotrophs, transient vesicle fusion mediates hormone release.

Cholesterol and regulated exocytosis: A requirement for unitary exocytotic events

Since the 1970s, much effort was been expended researching mechanisms of regulated exocytosis. Early work focused mainly on the role of proteins. Most notably the discovery of SNARE proteins in the 1980s and the zippering hypothesis brought us much closer to understanding the complex interactions in membrane fusion between vesicle and plasma membranes, a pivotal component of regulated exocytosis. However, most likely due to the predictions of the Singer-Nicholson fluid mosaic membrane model, the lipid components of the exocytotic machinery remained largely overlooked. Lipids were considered passive constituents of cellular membranes, not contributing much, if anything, to the process of exocytosis and membrane fusion. Since the 1990s, this so-called proteocentric view has been gradually giving way to the new perspective best described with the term proteolipidic. Many lipids were found to be of great importance in the regulation of exocytosis. Here we highlight the role of cholesterol. Furthermore, by using high-resolution cell-attached membrane capacitance measurements, we have monitored unitary exocytotic events in cholesterol-depleted membranes. We show that the frequency of these events is attenuated, providing evidence at the single vesicle level that cholesterol directly influences the merger of the vesicle and the plasma membranes.

Lipid-protein interactions in exocytotic release of hormones and neurotransmitters

Abstract Exocytosis is a highly conserved and ubiquitous process of eukaryotic cells responsible for the release of signaling molecules into extracellular space. Exocytosis involves trafficking, docking and eventually fusion of vesicles, carrying various cargo, with the plasma membrane. Until recently, the membrane fusion was considered to be predominantly mediated by proteins such as SNAP receptors, Muncs and Rabs, where lipids only played a passive role. However, newer studies portray lipids differently. Not only do lipids have a significantly more important role in membrane merger as previously believed, they also appear to be critical for regulating the entire process of exocytosis. The purpose of this article is to highlight the importance of specific lipids and lipid–protein interactions in regulated release of neurotransmitters and hormones.

Subanesthetic doses of ketamine stabilize the fusion pore in a narrow flickering state in astrocytes

Ketamine is an anesthetic that exhibits analgesic, psychotomimetic, and rapid antidepressant effects that are of particular neuropharmacological interest. Recent studies revealed astrocytic Ca2+ signaling and regulated exocytosis as ketamine‐targeted processes. Thus high‐resolution cell‐attached membrane capacitance measurements were performed to examine the influence of ketamine on individual vesicle interactions with the plasma membrane in cultured rat astrocytes. Ketamine evoked long‐lasting bursts of repetitive opening and closing of the fusion pore that were both time‐ and concentration‐dependent. Moreover, acute application and subanesthetic doses of ketamine elicited a significant increase in the occurrence of bursts that were characterized by a decreased fusion pore conductance, indicating that the fusion pore was stabilized in a narrow configuration. The time‐ and concentration‐dependent increase in burst occurrence was correlated with a decrease in full fission events. This study has demonstrated a novel effect of ketamine manifested as stabilization of a fusion pore incapable of transiting to full vesicle fission, suggestive of an inhibitory effect on vesicle retrieval. This until now unrecognized effect of ketamine on the vesicle fusion pore might play a role in astroglial release and (re)uptake of molecules, modulating synaptic activity.

Hyperpolarization-activated cyclic nucleotide-gated channels and cAMP-dependent modulation of exocytosis in cultured rat lactotrophs.

Hormone and neurotransmitter release from vesicles is mediated by regulated exocytosis, where an aqueous channel-like structure, termed a fusion pore, is formed. It was recently shown that second messenger cAMP modulates the fusion pore, but the detailed mechanisms remain elusive. In this study, we asked whether the hyperpolarization-activated cyclic nucleotide-gated (HCN) channels, which are activated by cAMP, are involved in the regulation of unitary exocytic events. By using the Western blot technique, a real-time PCR, immunocytochemistry in combination with confocal microscopy, and voltage-clamp measurements of hyperpolarizing currents, we show that HCN channels are present in the plasma membrane and in the membrane of secretory vesicles of isolated rat lactotrophs. Single vesicle membrane capacitance measurements of lactotrophs, where HCN channels were either augmented by transfection or blocked with an HCN channel blocker (ZD7288), show modulated fusion pore properties. We suggest that the changes in local cation concentration, mediated through HCN channels, which are located on or near secretory vesicles, have an important role in modulating exocytosis.

Fusion pore regulation in peptidergic vesicles

Regulated exocytosis, which involves fusion of secretory vesicles with the plasma membrane, is an important mode of communication between cells. In this process, signalling molecules that are stored in secretory vesicles are released into the extracellular space. During the initial stage of fusion, the interior of the vesicle is connected to the exterior of the cell with a narrow, channel-like structure: the fusion pore. It was long believed that the fusion pore is a short-lived intermediate state leading irreversibly to fusion pore dilation. However, recent results show that the diameter of the fusion pore can fluctuate, suggesting that the fusion pore is a subject of stabilization. A possible mechanism is addressed in this article, involving the local anisotropicity of membrane constituents that can stabilize the fusion pore. The molecular nature of such a stable fusion pore to predict how interacting molecules (proteins and/or lipids) mediate changes that affect the stability of the fusion pore and exocytosis is also considered. The fusion pore likely attains stability via multiple mechanisms, which include the shape of the lipid and protein membrane constituents and the interactions between them.

Local electrostatic interactions determine the diameter of fusion pores

In regulated exocytosis vesicular and plasma membranes merge to form a fusion pore in response to stimulation. The nonselective cation HCN channels are involved in the regulation of unitary exocytotic events by at least 2 mechanisms. They can affect SNARE-dependent exocytotic activity indirectly, via the modulation of free intracellular calcium; and/or directly, by altering local cation concentration, which affects fusion pore geometry likely via electrostatic interactions. By monitoring membrane capacitance, we investigated how extracellular cation concentration affects fusion pore diameter in pituitary cells and astrocytes. At low extracellular divalent cation levels predominantly transient fusion events with widely open fusion pores were detected. However, fusion events with predominately narrow fusion pores were present at elevated levels of extracellular trivalent cations. These results show that electrostatic interactions likely help determine the stability of discrete fusion pore states by affecting fusion pore membrane composition.

AQP4e-based orthogonal arrays regulate rapid cell volume changes in astrocytes

Water channel aquaporin 4 (AQP4) plays a key role in the regulation of water homeostasis in the brain. It is predominantly expressed in astrocytes at the blood–brain and blood–liquor interfaces. Although several AQP4 isoforms have been identified in the mammalian brain, two, AQP4a (M1) and AQP4c (M23), have been confirmed to cluster into plasma membrane supramolecular structures, termed orthogonal arrays of particles (OAPs) and to enhance water transport through the plasma membrane. However, the role of the newly described water-conductive mammalian isoform AQP4e is unknown. Here, the dynamics of AQP4e aggregation into OAPs and its role in the regulation of astrocyte water homeostasis have been studied. Using super-resolution structured illumination, atomic force, and confocal microscopies, the results revealed that, in female rat astrocytes, AQP4e isoform colocalizes with OAPs, affecting its structural dynamics. In hypoosmotic conditions, which elicit cell edema, OAP formation was considerably enhanced by overexpressed AQP4e. Moreover, the kinetics of the cell swelling and of the regulatory volume decrease was faster in astrocytes overexpressing AQP4e compared with untransfected controls. Furthermore, the increase in maximal cell volume elicited by hypoosmotic stimulation was significantly smaller in AQP4e-overexpressing astrocytes. For the first time, this study demonstrates an active role of AQP4e in the regulation of OAP structural dynamics and in water homeostasis. SIGNIFICANCE STATEMENT Water channel aquaporin 4 (AQP4) plays a key role in the regulation of water homeostasis in the brain. To date, only AQP4a and AQP4c isoforms have been confirmed to enhance water transport through plasmalemma and to cluster into orthogonal arrays of particles (OAPs). We here studied the dynamics, aggregation, and role in the regulation of astrocyte water homeostasis of the newly described water-conductive mammalian isoform AQP4e. Our main findings are as follows: brain edema mimicking hypoosmotic conditions stimulates the formation of new OAPs with larger diameters, due to the incorporation of additional cytoplasmic AQP4 channels and the redistribution of AQP4 channels of the existing OAPs; and AQP4e affects the dynamics of cell swelling and regulatory volume decrease in astrocytes exposed to hypoosmotic conditions.

How to Make a Stable Exocytotic Fusion Pore, Incompetent of Neurotransmitter and Hormone Release from the Vesicle Lumen?

Abstract In multicellular organisms, signaling is a necessity and an important mode of communication between cells is mediated by neurotransmitters, hormones, and other chemical messengers that are stored in secretory vesicles. In stimulated conditions secretory vesicles, which are trafficked to be docked at the plasma membrane, enter exocytosis, characterized by vesicle and plasma membrane merger. Due to repulsive forces of negatively charged membrane surfaces, it was long believed that the fusion pore is merely a short lived intermediate state leading irreversibly to a complete merger of both membranes. However, recent results show that the fusion pore is a rather stable structure, which can reversibly reopen to subnanometer diameters; dimensions too narrow to permit the exit of the cargo into the extracellular space. The aim of this chapter is to first review how can such a structure attain stability and compare two models in which membrane constituents are either isotropic or anisotropic in nature. Then we address the molecular nature of such a stable, release-unproductive fusion pore. We conclude that membrane constituents of the stable fusion pore membrane, being made of proteins and/or lipids, very likely consist of architectural elements that exhibit anisotropicity. The dynamics of fusion pore diameter is then determined by the density and architectural properties of these membrane constituents at fusion pore locales.