Secretory granules are recaptured largely intact after stimulated exocytosis in cultured endocrine cells

Classical cell biology teaches that exocytosis causes the membrane of exocytic vesicles to disperse into the cell surface and that a cell must later retrieve by molecular sorting whatever membrane components it wishes to keep inside. We have tested whether this view applies to secretory granules in intact PC-12 cells. Three granule proteins were labeled with fluorescent proteins in different colors, and two-color evanescent-field microscopy was used to view single granules during and after exocytosis. Whereas neuro-peptide Y was lost from granules in seconds, tissue plasminogen activator (tPA) and the membrane protein phogrin remained at the granule site for over 1 min, thus providing markers for postexocytic granules. When tPA was imaged simultaneously with cyan fluorescent protein (CFP) as a cytosolic marker, the volume occupied by the granule appeared as a dark spot where it excluded CFP. The spot remained even after tPA reported exocytosis, indicating that granules failed to flatten into the cell surface. Phogrin was labeled with GFP at its luminal end and used to sense the pH in granules. When exocytosis caused the acidic granule interior to neutralize, GFP–phogrin at first brightened and later dimmed again as the interior separated from the extracellular space and reacidified. Reacidification and dimming could be reversed by application of NH4Cl. We conclude that most granules reseal in <10 s after releasing cargo, and that these empty or partially empty granules are recaptured otherwise intact.

[1]  M. Klempner,et al.  Alkalinizing the intralysosomal pH inhibits degranulation of human neutrophils. , 1983, The Journal of clinical investigation.

[2]  A. Verkman,et al.  Photobleaching recovery and anisotropy decay of green fluorescent protein GFP-S65T in solution and cells: cytoplasmic viscosity probed by green fluorescent protein translational and rotational diffusion. , 1997, Biophysical journal.

[3]  J. Trenkle,et al.  Punctate appearance of dopamine-β-hydroxylase on the chromaffin cell surface reflects the fusion of individual chromaffin granules upon exocytosis , 1997, Neuroscience.

[4]  H. von Grafenstein,et al.  Membrane recapture and early triggered secretion from the newly formed endocytotic compartment in bovine chromaffin cells. , 1992, The Journal of physiology.

[5]  E. Neher,et al.  Capacitance measurements reveal stepwise fusion events in degranulating mast cells , 1984, Nature.

[6]  R. J. Fisher,et al.  Control of fusion pore dynamics during exocytosis by Munc18. , 2001, Science.

[7]  Alexander M Aravanis,et al.  Limited numbers of recycling vesicles in small CNS nerve terminals: implications for neural signaling and vesicular cycling , 2001, Trends in Neurosciences.

[8]  H. Palfrey,et al.  Quantal Size Is Dependent on Stimulation Frequency and Calcium Entry in Calf Chromaffin Cells , 2001, Neuron.

[9]  D. Axelrod,et al.  Selective imaging of surface fluorescence with very high aperture microscope objectives. , 2001, Journal of biomedical optics.

[10]  H. Horstmann,et al.  Direct observation of membrane retrieval in chromaffin cells by capacitance measurements , 2001, FEBS letters.

[11]  C. Stevens,et al.  "Kiss and run" exocytosis at hippocampal synapses. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[12]  W. Webb,et al.  Single granule pH cycling in antigen-induced mast cell secretion. , 2000, Journal of cell science.

[13]  W. Betz,et al.  Regulation of dense core release from neuroendocrine cells revealed by imaging single exocytic events , 1999, Nature Neuroscience.

[14]  G. Rutter,et al.  Simultaneous evanescent wave imaging of insulin vesicle membrane and cargo during a single exocytotic event , 2000, Current Biology.

[15]  J. Meldolesi,et al.  Exocytosis and membrane recycling. , 1981, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[16]  W. Almers,et al.  Imaging actin and dynamin recruitment during invagination of single clathrin-coated pits , 2002, Nature Cell Biology.

[17]  W. Almers,et al.  A real-time view of life within 100 nm of the plasma membrane , 2001, Nature Reviews Molecular Cell Biology.

[18]  W. Almers,et al.  Properties of the fusion pore that forms during exocytosis of a mast cell secretory vesicle , 1990, Neuron.

[19]  Thorsten Lang,et al.  Ca2+-Triggered Peptide Secretion in Single Cells Imaged with Green Fluorescent Protein and Evanescent-Wave Microscopy , 1997, Neuron.

[20]  W. Almers,et al.  Fast steps in exocytosis and endocytosis studied by capacitance measurements in endocrine cells , 1996, Current Opinion in Neurobiology.

[21]  G. Alvarez de Toledo,et al.  The exocytotic event in chromaffin cells revealed by patch amperometry , 1997, Nature.

[22]  Steven S. Vogel,et al.  Exocytotic Insertion of Calcium Channels Constrains Compensatory Endocytosis to Sites of Exocytosis , 2000, The Journal of cell biology.

[23]  J. Meldolesi,et al.  Synaptic vesicles: is kissing a matter of competence? , 2001, Trends in cell biology.

[24]  G. Patterson,et al.  Use of the green fluorescent protein and its mutants in quantitative fluorescence microscopy. , 1997, Biophysical journal.

[25]  A Miyawaki,et al.  Measurement of cytosolic, mitochondrial, and Golgi pH in single living cells with green fluorescent proteins. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[26]  H. McMahon,et al.  Dynamin-dependent and dynamin-independent processes contribute to the regulation of single vesicle release kinetics and quantal size , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[27]  J. Hutton,et al.  Molecular Cloning of Phogrin, a Protein-tyrosine Phosphatase Homologue Localized to Insulin Secretory Granule Membranes* , 1996, The Journal of Biological Chemistry.

[28]  S. Mahata,et al.  Tissue Plasminogen Activator (t-PA) Is Targeted to the Regulated Secretory Pathway , 1997, The Journal of Biological Chemistry.

[29]  Toshiaki Tanaka,et al.  Monitoring of exocytosis and endocytosis of insulin secretory granules in the pancreatic β-cell line MIN6 using pH-sensitive green fluorescent protein (pHluorin) and confocal laser microscopy , 2002 .

[30]  K. Takimoto,et al.  Ca2+-Induced Deprotonation of Peptide Hormones Inside Secretory Vesicles in Preparation for Release , 1999, The Journal of Neuroscience.

[31]  Steven S. Vogel,et al.  Direct membrane retrieval into large vesicles after exocytosis in sea urchin eggs , 1995, The Journal of cell biology.

[32]  G. Rutter,et al.  Secretory-granule dynamics visualized in vivo with a phogrin-green fluorescent protein chimaera. , 1998, The Biochemical journal.

[33]  Takeharu Nagai,et al.  Shift anticipated in DNA microarray market , 2002, Nature Biotechnology.

[34]  V. Valero,et al.  High calcium concentrations shift the mode of exocytosis to the kiss-and-run mechanism , 1999, Nature Cell Biology.

[35]  P. De Camilli,et al.  Imaging direct, dynamin-dependent recapture of fusing secretory granules on plasma membrane lawns from PC12 cells , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[36]  T. A. Ryan,et al.  Real-time measurements of vesicle-SNARE recycling in synapses of the central nervous system , 2000, Nature Cell Biology.

[37]  H. Palfrey,et al.  Vesicle Recycling Revisited: Rapid Endocytosis May Be The First Step , 1998, Neuroscience.

[38]  M. McNiven,et al.  Rapid endocytosis coupled to exocytosis in adrenal chromaffin cells involves Ca2+, GTP, and dynamin but not clathrin. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[39]  C. Meliza,et al.  Real-time imaging of the axonal transport of granules containing a tissue plasminogen activator/green fluorescent protein hybrid. , 1998, Molecular biology of the cell.