Characterization of reconstituted Fo from wild-type Escherichia coli and identification of two other fluxes co-purifying with Fo.

We purified the ATPase Fo sector from a nonoverexpressing strain of Escherichia coli, reconstituted it into lipid vesicles made of either asolectin or two different mixtures of purified lipids, and measured proton flux through the reconstituted proton channel. We measured single-channel conductances and found that Fo activity depends on both lipids and reconstitution methods. In asolectin vesicles, Fo has a single-channel conductance of about 0.2 fS. Additionally, the relatively impure Fo prepared from cells carrying single-copy ATPase genes allowed us to observe two other fluxes, a nonselective cation leak (C(L)) and a slow H+ flux (Hs). Unlike the Fo flux, these fluxes could not be blocked by the Fo inhibitor DCCD. The C, reduces the total apparent trapped volume inside vesicles and therefore must equilibrate both H+ and K+ in the vesicles that contain it. When reconstituted into bilayers, these Fo preparations displayed a 120 pS cation channel with characteristics consistent with C(L) flux. The Hs conducts only H+ but at a slower rate than the Fo. We were therefore able to: 1) quantitate the single-channel conductance of the Fo, 2) demonstrate that our Fo purification method co-purified other membrane proteins that have ion-conduction properties, and 3) show that certain lipids are necessary for functional reconstitution of Fo.

The t-SNARE syntaxin is sufficient for spontaneous fusion of synaptic vesicles to planar membranes.

Vesicular trafficking and exocytosis are directed by the complementary interaction of membrane proteins that together form the SNARE complex. This complex is composed of proteins in the vesicle membrane (v-SNAREs) that intertwine with proteins of the target membrane (t-SNAREs). Here we show that modified synaptic vesicles (mSV), containing v-SNAREs, spontaneously fuse to planar membranes containing the t-SNARE, syntaxin 1A. Fusion was Ca(2+)-independent and did not occur with vesicles lacking v-SNAREs. Therefore, syntaxin alone forms a functional fusion complex with v-SNAREs. Our functional fusion assay uses synaptic vesicles that are modified, so each fusion event results in an observable transient current. The mSV do not fuse with protein-free membranes. Additionally, artificial vesicles lacking v-SNAREs do not fuse with membranes containing syntaxin. This technique can be adapted to measure fusion in other SNARE systems and should enable the identification of proteins critical to vesicle-membrane fusion. This will further our understanding of exocytosis and may improve targeting and delivery of therapeutic agents packaged in vesicles.

Building a bilayer model of the neuromuscular synapse.

Progress over the past 10 years has made it possible to construct a simple model of neurotransmitter release. Currently, some models use artificially formed vesicles to represent synaptic vesicles and a planar lipid bilayer as a presynaptic membrane. Fusion of vesicles with the bilayer is via channel proteins in the vesicle membrane and an osmotic gradient. In this paper; a framework is presented for the successful construction of a more complete model of synaptic transmission. This model includes real synaptic vesicles that fuse with a planar bilayer. The bilayer contains acetylcholine receptor (AChR) channels which function as autoreceptors in the membrane. Vesicle fusion is initiated following a Ca2+ flux through voltage-gated Ca2+ channels. Key steps in the plan are validated by mathematical modeling. Specifically, the probability that a reconstituted AChR channel opens following the release of ACh from a fusing vesicle, is calculated as a function of time, quantal content, and number of reconstituted AChRs. Experimentally obtainable parameters for construction of a working synapse are given. The inevitable construction of a full working model will mean that the minimal structures necessary for synaptic transmission are identified. This will open the door in determining regulatory and modulatory factors of transmitter release.

Nystatin/ergosterol method for reconstituting ion channels into planar lipid bilayers.

The nystatin-ergosterol (N/E) method is described and reviewed. Using this procedure, an experimenter can promote and detect fusion of vesicles with planar lipid bilayers. N/E fusion provides a straightforward mechanism to reconstitute any membrane protein into planar lipid bilayers. Once reconstituted, it is easy to determine the ion selectivity, transport rate, voltage dependence, and kinetics of any conductance caused by the membrane protein. Fusigenic N/E vesicles are made with a mixture of phospholipids, ergosterol, and nystatin. Vesicle size can be adjusted either with sonication or with polycarbonate filters. The best vesicles contain approximately 20 mol% ergosterol, are approximately 200 nm in diameter, and are in a solution containing approximately 50 micrograms/ml nystatin. Vesicle fusion requires an osmotic gradient and delivery of vesicles to the bilayer. Vesicle delivery is increased by (1) stirring of the chamber that contains vesicles, (2) larger bilayers, and (3) bilayers that are face-flush with the vesicle-containing solution. Because constant stirring is critical for delivery of vesicles to the bilayer, a system that allows simultaneous stirring and sensitive electrical measurements is desirable. The main strength of the bilayer technique has always been that the experimenter has control over the milieu of the membrane system. The N/E fusion technique adds to this strength by controlling fusion of vesicles to the bilayer, thus allowing the quantitative transfer of isolated proteins from vesicle to bilayer. The techniques and calculations necessary for successful quantitative reconstitution are given in detail.

Activation of P2x-purinoceptors in the nucleus tractus solitarius elicits differential inhibition of lumbar and renal sympathetic nerve activity.

Activation of P2x-purinoceptors in the nucleus tractus solitarius (NTS) via microinjection of alpha,beta-methylene ATP (alpha,beta-MeATP) elicits large dose-dependent decreases in mean arterial pressure (MAP) and heart rate (HR) and preferential dilation of the iliac vascular bed in comparison to renal and mesenteric vascular beds. We investigated whether sympathoinhibition contributes to the depressor responses and whether differential changes in regional sympathetic output occur. In 43 chloralose/urethane anesthetized male Sprague-Dawley rats, MAP, HR, renal (RSNA) and lumbar sympathetic nerve activity (LSNA) were recorded. Data were analyzed as both the maximum decrease and the integral of the decrease over the duration of the depressor response. Microinjection of alpha,beta-MeATP (25 and 100 pmol in 50 nl volume) into the subpostremal NTS caused significant and dose-dependent decreases in MAP, HR, RSNA and LSNA. However, the changes in RSNA were significantly greater than those observed in LSNA for both doses and both methods of analysis of data (maximum responses in delta %: 84 +/- 3 vs 62 +/- 4, and 93 +/- 3 vs 74 +/- 4 for low and high dose of alpha,beta-MeATP, respectively; integral responses in delta % x min: 32 +/- 4 vs 18 +/- 3 and 179 +/- 7 vs 134 +/- 14 for low and high dose of alpha,beta-MeATP, respectively). Blockade of P2-purinoceptors in the NTS by the specific P2-receptor antagonist suramin abolished responses to 100 pmol alpha,beta-MeATP and microinjections of vehicle did not alter neural nor hemodynamic parameters. We conclude that activation of P2x-purinoceptors in the NTS inhibits sympathetic nerve activity and evokes differential regional sympathetic responses. However, differential sympathoinhibition does not explain differential vascular responses to the activation of P2x-purinoceptors in the NTS.

Phospholipase A2 action on planar lipid bilayers generates a small, transitory current that is voltage independent.

Addition of either bee venom or Trimeresurus flavoviridis phospholipase A2 (PLA2) to the solution bathing the front side of a voltage-clamped, planar lipid bilayer consistently produced a transitory current lasting approximately 100 s. This current is consistent with anions moving through the membrane to the rear side. The peak current is independent of holding potential. PLA2 activity on phospholipid membranes not only produced a current but also led to membrane rupture within 300 s. The current depends on Ca2+ and lipid type. Addition of PLA2 in the absence of Ca2+ or to membranes made of nonsubstrate lipids (e.g., glycerol monooleate or lysophosphatidylcholine) produced no current and did not break the bilayer. Peak current height, signal decay time, and time to membrane rupture all depended on PLA2 dose, whereas total charge produced was constant. This current does not flow through ion channels because there are no channels present and the current is not voltage dependent. The evidence is consistent with the hypothesis that the current is generated by the movement of ionized fatty acid produced by PLA2 action. These results demonstrate a simple method to measure enzyme activity in the presence of different substrates and varied environmental conditions.

Role of cardiac output in mediating arterial blood pressure oscillations.

The objective of this study was to determine the role of cardiac output in mediating spontaneous fluctuations in mean arterial pressure (MAP) conscious dogs. Dogs were chronically instrumented to monitor MAP and cardiac output. Atrioventricular (AV) block was induced, and left ventricular and right atrial electrodes were implanted. After recovery, MAP was observed for 5 min under two conditions: 1) normal variation in heart rate and cardiac output via triggering the ventricular stimulator with each atrial depolarization (effectively reversing the AV block, AV-linked stimulation) and 2) computer control of ventricular rate to maintain cardiac output constant on a by-beat basis at the same level as observed during normal variations in heart rate and cardiac output. When cardiac output was held constant, large-amplitude, low-frequency oscillations in MAP were readily apparent. Spectral analysis by fast Fourier transform revealed that during constant cardiac output the power observed at low frequencies in the MAP spectrum represented 95.0 +/- 2.7% of the total power compared with 75.5 +/- 4.6% during normal variations in heart rate and cardiac output (P < 0.05). In addition, when cardiac output was held constant, the power observed at higher frequencies markedly decreased from 24.5 +/- 4.6% of total power during AV-linked stimulation to only 5.0 +/- 2.7% of total power during constant cardiac output (P < 0.05). We conclude that low-frequency oscillations in MAP are due to changes in peripheral resistance, whereas a significant amount of high-frequency changes in MAP stems from spontaneous changes in cardiac output.

Plasma membrane calcium ATPase in synaptic terminals of chick Edinger-Westphal neurons.

The plasma membrane calcium ATPase pump (PMCA) is one of two major mechanisms known to be involved in extruding calcium from cells. The monoclonal antibody 5F10 was used to examine the distribution of PMCA in chick Edinger-Westphal neurons, a population of cholinergic preganglionic neurons whose cells bodies reside in the Edinger-Westphal nucleus in the brainstem and whose axons form synaptic terminals on parasympathetic neurons in the ciliary ganglion. Definitive PMCA immunoreactivity was undetectable in Edinger-Westphal cell bodies in the brainstem. In contrast, immunoreactivity for PMCA was robust in ciliary ganglia and resembled patterns of immunoreactivity for the synaptic vesicle antigen SV-2, suggesting that PMCA is expressed in Edinger-Westphal synaptic terminals. Moreover, PMCA immunoreactivity co-localized with immunoreactivity for enkephalin and substance P, two neuropeptides known to be expressed in Edinger-Westphal synaptic terminals. Fine structure studies revealed that PMCA immunoreactivity is associated with synaptic vesicles rather than the plasma membrane in Edinger-Westphal terminals. In immunodot assays, synaptic vesicles purified from Torpedo electric organ are also immunoreactive for PMCA as well as SV-2. Torpedo vesicles are negative for the sarcoplasmic/ endoplasmic reticulum ATPase, suggesting that the observed PMCA immunoreactivity is not associated with smooth endoplasmic reticulum. Immunoblot analysis confirmed that 5F10 recognizes a protein with the correct molecular mass for PMCA in tissue homogenates of chick cerebellum, chick ciliary ganglia, and Torpedo synaptic vesicles. These findings describe a previously unrecognized location for PMCA in the membranes of cholinergic synaptic vesicles. Relevance to previous data and possible functions are discussed.

Ion channels from synaptic vesicle membrane fragments reconstituted into lipid bilayers.

Cholinergic synaptic vesicles were isolated from the electric organ of Torpedo californica. Vesicle membrane proteins were reconstituted into planar lipid bilayers by the nystatin/ergosterol fusion technique. After fusion, a variety of ion channels were observed. Here we identify four channels and describe two of them in detail. The two channels share a conductance of 13 pS. The first is anion selective and strongly voltage dependent, with a 50% open probability at membrane potentials of -15 mV. The second channel is slightly cation selective and voltage independent. It has a high open probability and a subconductance state. A third channel has a conductance of 4-7 pS, similar to the subconductance state of the second channel. This channel is fairly nonselective and has gating kinetics different from those of the cation channel. Finally, an approximately 10-pS, slightly cation selective channel was also observed. The data indicate that there are one or two copies of each of the above channels in every synaptic vesicle, for a total of six channels per vesicle. These observations confirm the existence of ion channels in synaptic vesicle membranes. It is hypothesized that these channels are involved in vesicle recycling and filling.

Influence of calcium channel blocker treatment on the mechanical properties of diabetic rat myocardium.

The objective of this investigation was to determine whether calcium channel blocker (CCB) treatment effectively restores normal baseline mechanical function in diabetic myocardium and to evaluate its effect on the interval-strength relationship. Wistar rats were made diabetic with streptozotocin (55 mg/kg, IV). Left-ventricular papillary muscles from normal and diabetic (10 weeks) rats were superfused with Tyrode's solution at 30 degrees C. A subgroup of diabetic and normal animals received daily injections of verapamil or nifedipine (10 mg/kg, IP; 8 weeks) to compare the effectiveness of a phenylalkylamine to a dihydropyridine in reversing diabetes-induced contractile dysfunction in vitro. Muscles were electrically stimulated at 0.5 Hz with suprathreshold stimuli, and the following parameters were measured: peak tension developed, time to-peak tension, time-to-90% relaxation, and the maximum velocities of tension development and decay. Experimental diabetes was characterized by: severe hyperglycemia, hepatomegaly, reduced body weight gain, cardiomegaly, and increased plasma phospholipid levels. In addition, baseline values of peak tension developed, time to-peak tension, and time-to-90% relaxation were significantly greater in muscles from diabetic animals. Chronic nifedipine treatment reduced hyperglycemia and plasma phospholipid levels, normalized body weight gain, and reduced both heart and liver sizes in diabetic animals. Nifedipine treatment completely reversed diabetes-induced prolongation in both time-to-peak tension and time-to-90% relaxation. In diabetic myocardium, a slightly positive component was present in the interval-strength relationship between 0.01 and 1 Hz, resulting in a rightward shift in the entire curve across a wide range of stimulation frequencies (0.01-5 Hz). This positive component was absent in muscles from diabetic animals treated with both CCBs, and verapamil produced a leftward shift in the frequency response curve. The results of this study suggest that chronic nifedipine treatment may be more effective than verapamil in restoring normal baseline myocardial mechanical function, reducing hyperglycemia and hyperlipidemia, as well as attenuating both cardiac and liver enlargement in experimental diabetes. In contrast, verapamil treatment tended to normalize more effectively the inotropic response to changes in stimulation frequency in diabetic myocardium.

Phospholipase A2-evoked destabilization of planar lipid membranes.

The ability of phospholipase A2 (PLA2) to enhance the flux of charged molecules across a planar lipid bilayer was examined. Within 300 s of adding PLA2, the membrane destabilized, with transient currents and eventual failure of membrane integrity. This effect was blocked by removal of free Ca2+ (with EGTA) or by substitution of normal phospholipids with non-substrate lipids, indicating specificity of PLA2 activity. PLA2 may similarly destabilize plasma membranes, allowing for the movement of molecules down their concentration gradients. PLA2, which is activated by cerebral ischemia, could thus contribute to the extracellular accumulation of neurotoxic excitatory amino acids.

Evaluation of the evidence for ion channels in synaptic vesicles.

Synaptic vesicles (SVs) have been the focus of much research for many years, however only recently have ion channels from SV membranes been reported. There is now convincing evidence that SVs contain ion channels. This conclusion is based on direct experimental results from several different laboratories using the patch clamp or planar lipid bilayer technique on SVs and neurosecretory granules (NSG). Some limitations of patch clamping and of fusing synamptic vesicles to a bilayer are described and the advantages of the nystatin/ergosterol fusion method are presented. Six different channels appear to exist in SV (or NSG) membranes. Two large channels (250 and 154 pS) have been observed in SVs isolated from mammalian brain, two channels (180 and 13 pS) from Torpedo electric organ, and two channels (130 and 30-40 pS) from NSG. The three larger channels from each set (250, 180 and 130 pS7) are novel in that they have a subconductance state. The 154 pS channel has been identified as synaptophysin but the identity and function of the other channels is unknown. Although some of the channels are gated by voltage, only the 130 pS channel is modulated by Ca2+. Further knowledge of what regulates these channels is mandatory if we are to determine the physiological significance of these channels.

Release of ATP from cholinergic synaptic vesicles during freeze-thaw cycling.

Cholinergic synaptic vesicles were isolated from Torpedo californica and subjected to repeated freeze/thraw (F/T) cycles. Both vesicular (trapped) and released (free) ATP were measured after each cycle. It was found that a constant percentage of vesicular content was released during each F/T cycle. In solutions low in Ca2+ and Mg2+ and high in sucrose, 25% of the ATP is released by each F/T cycle. When synaptic vesicles are resuspended in Tornedo Ringer's (which contains less sucrose, higher Ca2+ and urea), 35-40% of the trapped ATP is released during each F/T cycle. These data contradict the hypothesis that F/T does not disrupt synaptic vesicle membranes (although F/T does disrupt cell membranes and synaptosomes). This nonrupture hypothesis was assumed by C. Solsona, C. Saltó, and A. Ymbern (1991, Biochim. Biophys. Acta 1095, 57-62) to calculate cytosolic ATP as 40% of total ATP. Our results indicate that cytosolic ATP is 10-15%. These results may also explain some of the discrepancies in reported values for cytosolic acetylcholine (ACh). Values of 35-50% were obtained by previous workers using the nonrupture hypothesis, and values of 8-22% in experiments that did not depend on the nonrupture hypothesis. Our results refute the nonrupture hypothesis and thus support a lower value for cytosolic ACh.

Nystatin-induced liposome fusion. A versatile approach to ion channel reconstitution into planar bilayers.

A simple method is described for promoting and detecting fusion of liposomes with planar bilayer membranes. Liposomes containing ergosterol are doped with the pore-forming antibiotic nystatin, and the planar bilayer is kept ergosterol-free. Under these conditions, when a transbilayer salt gradient is applied, liposomes added to the high-salt side of the bilayer elicit the appearance of abrupt conductance jumps of 5-300 pS. The increase in conductance is transient, decaying back to baseline on the order of 10 s. Each of these "spikes" represents the fusion of a single liposome with the bilayer, resulting in the simultaneous insertion of many nystatin channels. Relaxation of the conductance back to baseline occurs because ergosterol, required for the integrity of the nystatin pore, diffuses away into the sterol-free planar bilayer after liposome fusion. When Torpedo Cl- channels are reconstituted into liposomes containing ergosterol and nystatin, fusion spikes are observed simultaneously with the appearance of Cl- channels. This method allows the calculation of the density of functional ion channels in a preparation of proteoliposomes containing reconstituted channel protein.

Pure lipid vesicles can induce channel-like conductances in planar bilayers.

Typical channel-like current fluctuations were observed in planar lipid bilayers following brief exposure to large concentrations of lipid vesicles devoid of protein. Vesicles, formed by sonication of pure lipids suspended in 150 mM salt solutions, were ejected approximately 0.5 mm from a planar bilayer with a pipette. Over the next several minutes the bilayer conductance changed in ways usually considered to be indicative of reconstituted protein channels including step conductance changes (both up and down), flickering, ion selectivity, and inactivation. This observation demonstrates the need for caution in interpreting conductance changes which occur following ejection of channel-containing vesicles near a membrane.

Role of channels in the fusion of vesicles with a planar bilayer.

Fluorescence microscopy combined with electrical conductance measurements were used to assess fusion of phospholipid vesicles with a planar bilayer. Large unilamellar vesicles (0.5-3 microns diam.) filled with the fluorescent dye, calcein, were made both with or without porin channels. Vesicle-bilayer fusion was induced by increasing the osmolarity of the solution on the side of the bilayer to which the vesicles were added. Fusion was detected optically by the fluorescent flash due to release of vesicular contents. Although both porin-containing and porin-free vesicles give the same kind of flash upon content release, the conditions necessary to induce release are very different. Only 4% of the porin-free vesicles fuse (release their contents) when subjected to 3 M urea. However, the same conditions induce 53% of the porin-containing vesicles to fuse and most of these fusions occur at a lower osmolarity ([urea] less than 400 mM). Thus channels greatly enhance fusion in this model system. A physical model based on the postulate that fusion is induced by an increase in surface tension, predicts that three conditions are necessary for fusion in this system: (a) an open channel in the vesicle membrane, (b) an osmotic gradient across the bilayer, and (c) the vesicle in contact with the planar membrane. These are the conditions that experimentally produce fusion in the model system.

Vesicle-membrane fusion. Observation of simultaneous membrane incorporation and content release.

Vesicle fusion, the central process of neurotransmitter release and hormonal secretion, is a complex process culminating in simultaneous incorporation of vesicle membrane into the plasma membrane and release of the vesicular contents extracellularly. This report describes simultaneous observation of membrane incorporation and content release using a model system composed of a planar bilayer and dye-filled vesicles.

Radiation inactivation of ricin occurs with transfer of destructive energy across a disulfide bridge.

The ionizing radiation sensitivity of ricin, a disulfide-linked heterodimeric protein, was studied as a model to determine the ability of disulfide bonds to transmit destructive energy. The radiation-dependent loss of A chain enzymatic activity after irradiation of either intact ricin or ricin in which the interchain disulfide bond was disrupted gave target sizes corresponding to the molecular size of dimeric ricin or monomeric A chain, respectively. These results clearly show that a disulfide bond can transmit destructive energy between protein subunits.