Secretory Granule Biogenesis in Sympathoadrenal Cells

Courel, Maïté; Rodemer, Carrie; Nguyen, Susan; Pance, Alena; Jackson, Antony P.; O’Connor, Daniel T.; Taupenot, Laurent

doi:10.1074/jbc.m604037200

Cited by 49 publications

(19 citation statements)

References 53 publications

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“…5C, the size of fluorescent SIG-SgII-GFP puncta was similar in either GalT-CFP-SgII-or GalT-CFP-expressing PC12 cells, with an average diameter of ϳ308 nm. Considering that the resolution of fluorescence puncta containing the photoprotein is diffraction-limited, this value is consistent with our earlier analyses by electron microscopy, reporting a DCG diameter of ϳ100 -130 nm in PC12 cells (21,25). The number of SIG-SgII-GFP puncta per xy optical section was significantly reduced in cells coexpressing GalT-CFP-SgII (22 Ϯ 4 puncta/xy plan, n ϭ 43; p Ͻ 0.05; Fig.…”

Section: Dominant Inhibitory Effect Of a Trans-golgi/tgn Resident Forsupporting

confidence: 79%

“…In addition, the subcellular distribution of SIG-GFP in PC12 and primary chromaffin cells ( Fig. 2A) was remarkably similar to that of the constitutive secretory pathway markers SgP-GFP (where SgP is the predicted 18-amino acid signal peptide of human CgA) (13) and SEAP (21,25) in the sympathoadrenal cell lineage, which further indicates that SIG-GFP is likely routed to the constitutive branch of the secretory pathway.…”

Section: Presentation Of Data and Statisticsmentioning

confidence: 66%

“…Trafficking of SgII Fusion Proteins into the Regulated Secretory Pathway-Taking our cue from the experimental paradigm developed in our earlier studies on the vesicular trafficking of CgA in sympathoadrenal cells (13,21,25), we fused full-length human SgII to GFP or EAP, for fluorescent or enzymatic tracing of the regulated secretory pathway. This study establishes that SgII flanked by a signal sequence is able to convert GFP or EAP to soluble (releasable) components of DCGs, and it thus reveals that SgII contains a dominant sorting signal for the regulated secretory pathway, whereas its signal peptide alone does not (Figs.…”

Section: Discussionmentioning

confidence: 99%

“…On the contrary, colocalization of SIG-GFP with endogenous CgB was poor ( Fig. 2B) with R p ϭ 0.13 Ϯ 0.05 and R o ϭ 0.17 Ϯ 0.04 (n ϭ 72; Table 1), as predicted for a fusion protein primarily destined to the constitutive secretory pathway (21,25). Partial rather than absolute overlap in the distribution of SIG-SgII-GFP with endogenous CgB can best be explained by the extended half-life of DCGs, which gives rise to pools of old granules (pre-transfection; lacking SIG-SgII-GFP) and young post-transfection granules (i.e.…”

Section: Presentation Of Data and Statisticsmentioning

confidence: 99%

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Sorting of the Neuroendocrine Secretory Protein Secretogranin II into the Regulated Secretory Pathway

Courel

Vasquez

Hook

et al. 2008

Journal of Biological Chemistry

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Section: Dominant Inhibitory Effect Of a Trans-golgi/tgn Resident Forsupporting

confidence: 79%

Section: Presentation Of Data and Statisticsmentioning

confidence: 66%

Section: Discussionmentioning

confidence: 99%

Section: Presentation Of Data and Statisticsmentioning

confidence: 99%

See 2 more Smart Citations

Sorting of the Neuroendocrine Secretory Protein Secretogranin II into the Regulated Secretory Pathway

Courel

Vasquez

Hook

et al. 2008

Journal of Biological Chemistry

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“…A prominent role of chromogranin A (CgA) in the regulation of DCG formation in endocrine and neuroendocrine cells has been proposed. Thus, depletion of CgA in PC12 cells led to a dramatic decrease in the number of DCGs (12), and exogenously expressed CgA in these depleted PC12 cells, as in DCG-deficient endocrine A35C and 6T3 cells, restored DCG biogenesis (12,13). Besides, expression of granins in non-endocrine, constitutively secreting cells such as CV-1, NIH3T3, or COS-7 cells provoked the formation of DCG-like structures that release their content in response to Ca 2ϩ influx (12,14,15).…”

mentioning

confidence: 99%

Chromogranin A Promotes Peptide Hormone Sorting to Mobile Granules in Constitutively and Regulated Secreting Cells

Montero-Hadjadje

Élias

Chevalier

et al. 2009

Journal of Biological Chemistry

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Chromogranin A (CgA) has been proposed to play a major role in the formation of dense-core secretory granules (DCGs) in neuroendocrine cells. Here, we took advantage of unique features of the frog CgA (fCgA) to assess the role of this granin and its potential functional determinants in hormone sorting during DCG biogenesis. Expression of fCgA in the constitutively secreting COS-7 cells induced the formation of mobile vesicular structures, which contained cotransfected peptide hormones. The fCgA and the hormones coexpressed in the newly formed vesicles could be released in a regulated manner. The N-and C-terminal regions of fCgA, which exhibit remarkable sequence conservation with their mammalian counterparts were found to be essential for the formation of the mobile DCG-like structures in COS-7 cells. Expression of fCgA in the corticotrope AtT20 cells increased pro-opiomelanocortin levels in DCGs, whereas the expression of N-and C-terminal deletion mutants provoked retention of the hormone in the Golgi area. Furthermore, fCgA, but not its truncated forms, promoted pro-opiomelanocortin sorting to the regulated secretory pathway. These data demonstrate that CgA has the intrinsic capacity to induce the formation of mobile secretory granules and to promote the sorting and release of peptide hormones. The conserved terminal peptides are instrumental for these activities of CgA.Eukaryotic cells share the capacity to rapidly secrete proteins through the constitutive secretory pathway. The fundamental feature of neuroendocrine and endocrine cells is the occurrence of dense-core secretory granules (DCGs), 3 which are key cytoplasmic organelles responsible for secretion of hormones, neuropeptides, and neurotransmitters through the regulated secretory pathway (RSP). Storage at high concentrations of these secretory products is required for their finely tuned release in response to extracellular stimulation (1, 2). DCG biogenesis starts with the budding of immature secretory granules (ISGs) from the trans-Golgi network (TGN) through interactions between lipid rafts and protein components, in a similar manner to constitutive vesicle budding (2, 3). The ISG budding is followed by a multistep maturation process to form the mature secretory granules, including removal of the constitutive secretory proteins and lysosomal enzymes inadvertently packaged into ISGs (4).Despite increasing knowledge of the various steps of DCG formation, the nature of the sorting signals for entry of proteins into the DCGs and the molecular machinery required to generate secretory granules are not fully elucidated (5, 6). Several recent studies highlighted the role of members of the granin family, which may represent the driving force for granulogenesis in the TGN (2), although this notion has been a matter of debate (7). Granins are soluble acidic proteins widely distributed in endocrine and neuroendocrine cells, which are characterized by the ability to aggregate at acidic pH and a high Ca 2ϩ environment (8, 9). These conditions are found in the lum...

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Analysis of Regulated Secretion Using PC12 Cells

Taupenot

2007

CP Cell Biology

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The catecholamine‐secreting PC12 cell line derived from the rat adrenal medulla has long been considered a model system for neurosecretion and neuronal differentiation. PC12 cells contain a large number of secretory granules (otherwise known as large dense‐core vesicles) for storage of small molecules, processing enzymes, neuropeptides, and peptide hormones. Secretory granule exocytosis in PC12 cells is tightly regulated by calcium and occurs in response to a secretagogue. This unit provides protocols for maintenance and transfection of PC12 cells. Several secretion assays are described to measure the release of secretory granule cargo molecules by detection of radioactive catecholamine, or by immunochemical or chemiluminescence detection of transfected regulated secretory proteins. Curr. Protoc. Cell Biol. 36:15.12.1‐15.12.13. © 2007 by John Wiley & Sons, Inc.

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Secretory Granule Biogenesis in Sympathoadrenal Cells

Cited by 49 publications

References 53 publications

Sorting of the Neuroendocrine Secretory Protein Secretogranin II into the Regulated Secretory Pathway

Sorting of the Neuroendocrine Secretory Protein Secretogranin II into the Regulated Secretory Pathway

Chromogranin A Promotes Peptide Hormone Sorting to Mobile Granules in Constitutively and Regulated Secreting Cells

Analysis of Regulated Secretion Using PC12 Cells

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