Jürgen A. Steyer scite author profile

Neurons maintain a limited pool of synaptic vesicles which are docked at active zones and are awaiting exocytosis. By contrast, endocrine cells releasing large, dense-core secretory granules have no active zones, and there is disagreement about the size and even the existence of the docked pool. It is not known how, and how rapidly, secretory vesicles are replaced at exocytic sites in either neurons or endocrine cells. By using electron microscopy, we have now been able to identify a pool of docked granules in chromaffin cells that is selectively depleted when cells secrete. With evanescent-wave fluorescence microscopy, we observed single granules undergoing exocytosis and leaving behind patches of bare plasmalemma. Fresh granules travelled to the plasmalemma at a top speed of 114 nm s(-1), taking an average of 6 min to arrive. On arrival, their motility diminished 4-fold, probably as a result of docking. Some granules detached and returned to the cytosol. We conclude that a large pool of docked granules turns over slowly, that granules move actively to their docking sites, that docking is reversible, and that the 'rapidly releasable pool' measured electrophysiologically represents a small subset of docked granules

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Tracking Single Secretory Granules in Live Chromaffin Cells by Evanescent-Field Fluorescence Microscopy

Steyer

Almers

1999

Biophysical Journal

206

209

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We have observed secretory granules beneath the plasma membrane of chromaffin cells. Using evanescent-field excitation by epiillumination, we have illuminated a thin layer of cytosol where cells adhere to glass coverslips. Up to 600 frames could be recorded at diffraction-limited resolution without appreciable photodynamic damage. We localized single granules with an uncertainty of approximately 30 nm and tracked their motion in three dimensions. Granules in resting cells wander randomly as if imprisoned in a cage that leaves approximately 70 nm space around a granule. The "cage" itself moves only slowly (D = 2 x 10(-12) cm2/s). Rarely do granules arrive at or depart from the plasma membrane of resting cells. Stimulation increases lateral motion only slightly. After the plasma membrane has been depleted of granules by exocytosis, fresh granules can be seen to approach it at an angle. The method will be useful for exploring the molecular steps preceding exocytosis at the level of single granules.

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Ca2+-Triggered Peptide Secretion in Single Cells Imaged with Green Fluorescent Protein and Evanescent-Wave Microscopy

Lang

Wacker

Steyer

et al. 1997

Neuron

222

182

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Green fluorescent protein fused to human chromogranin B or neuropeptide Y was expressed in PC12 cells and caused bright, punctate fluorescence. The fluorescent points colocalized with the endogenous secretory granule marker dopamine beta-hydroxylase. Stimulation of live PC12 cells with elevated [K+], or of permeabilized PC12 cells with Ca2+, led to Ca2+-dependent loss of fluorescence from neurites. Ca2+ stimulated secretion of both fusion proteins equally well. In living cells, single fluorescent granules were imaged by evanescent-wave fluorescence microscopy. Granules were seen to migrate; to stop, as if trapped by plasmalemmal docking sites; and then to disappear abruptly, as if through exocytosis. Evidently, GFP fused to secreted peptides is a fluorescent marker for dense-core secretory granules and may be used for time-resolved microscopy of single granules.

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A Membrane Marker Leaves Synaptic Vesicles in Milliseconds after Exocytosis in Retinal Bipolar Cells

Zenisek

Steyer

Feldman

et al. 2002

Neuron

177

185

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Perhaps synaptic vesicles can recycle so rapidly because they avoid complete exocytosis, and release transmitter through a fusion pore that opens transiently. This view emerges from imaging whole terminals where the fluorescent lipid FM1-43 seems unable to leave vesicles during transmitter release. Here we imaged single, FM1-43-stained synaptic vesicles by evanescent field fluorescence microscopy, and tracked the escape of dye from single vesicles by watching the increase in fluorescence after exocytosis. Dye left rapidly and completely during most or all exocytic events. We conclude that vesicles at this terminal allow lipid exchange soon after exocytosis, and lose their dye even if they connected with the plasma membrane only briefly. At the level of single vesicles, therefore, observations with FM1-43 provide no evidence that exocytosis of synaptic vesicles is incomplete.

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Fusion of Constitutive Membrane Traffic with the Cell Surface Observed by Evanescent Wave Microscopy

et al. 2000

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Monitoring the fusion of constitutive traffic with the plasma membrane has remained largely elusive. Ideally, fusion would be monitored with high spatial and temporal resolution. Recently, total internal reflection (TIR) microscopy was used to study regulated exocytosis of fluorescently labeled chromaffin granules. In this technique, only the bottom cellular surface is illuminated by an exponentially decaying evanescent wave of light. We have used a prism type TIR setup with a penetration depth of ∼50 nm to monitor constitutive fusion of vesicular stomatitis virus glycoprotein tagged with the yellow fluorescent protein. Fusion of single transport containers (TCs) was clearly observed and gave a distinct analytical signature. TCs approached the membrane, appeared to dock, and later rapidly fuse, releasing a bright fluorescent cloud into the membrane. Observation and analysis provided insight about their dynamics, kinetics, and position before and during fusion. Combining TIR and wide-field microscopy allowed us to follow constitutive cargo from the Golgi complex to the cell surface. Our observations include the following: (1) local restrained movement of TCs near the membrane before fusion; (2) apparent anchoring near the cell surface; (3) heterogeneously sized TCs fused either completely; or (4) occasionally larger tubular-vesicular TCs partially fused at their tips.

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Jürgen A. Steyer

Transport, docking and exocytosis of single secretory granules in live chromaffin cells

Tracking Single Secretory Granules in Live Chromaffin Cells by Evanescent-Field Fluorescence Microscopy

Ca2+-Triggered Peptide Secretion in Single Cells Imaged with Green Fluorescent Protein and Evanescent-Wave Microscopy

A Membrane Marker Leaves Synaptic Vesicles in Milliseconds after Exocytosis in Retinal Bipolar Cells

Fusion of Constitutive Membrane Traffic with the Cell Surface Observed by Evanescent Wave Microscopy

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