Regulation of neuronal K(+) currents by target-derived factors: opposing actions of two different isoforms of TGFbeta

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Berghard, A. and Buck, L. B (1996). Sensory transduction in vomeronasal neurons: evidence for Go, G i2, and adenylyl cyclase II as major components of a pheromone signaling cascade. J. Neurosci 16, 909-918.[Abstract/Free Full Text]

Brauer, P. R. and Yee, J. A (1993). Cranial neural crest cells synthesize and secrete a latent form of transforming growth factor-that can be activated by neural crest cell proteolysis. Dev. Biol 155, 281-285.[Medline]

Burt, D. W. and Jakowlew, S. B (1988). Correction: a new interpretation of a chicken transforming growth factor-4 complementary DNA. Mol. Endocrinol 6, 989-992.[Medline]

Burt, D. W. and Patton, I. R (1992). Evolutionary origins of the transforming growth factor-gene family. DNA Cell Biol 11, 497-510.[Medline]

Cameron, J. C., Lhuillier, L., Subramony, P. and Dryer, S. E (1998). Developmental regulation of neuronal K+channels by target-derived TGF in vivo and in vitro. Neuron 21, 1045-1053.[Medline]

Campenot, R. B (1987). Local control of neurite sprouting in cultured sympathetic neurons by nerve growth factor. Brain Res 465, 293-293.[Medline]

Commissiong, J. W., Takeshima, T., Johnston, J. M. and Shimoda, K (1997). Effects of transforming growth factors on dopaminergic neurons in culture. Neurochem. Int 30, 393-399.[Medline]

Corfas, G., Rosen, K. M., Aratake, H., Krauss, R. and Fischbach, G. D (1995). Differential expression of ARIA isoforms in the rat brain. Neuron 14, 103-115.[Medline]

Coulombe, J. N., Schwall, R., Parent, A. S., Eckenstein, F. P. and Nishi, R (1993). Induction of somatostatin immunoreactivity in cultured ciliary ganglion neurons by activin in choroid cell-conditioned medium. Neuron 10, 899-906.[Medline]

Darland, D. C. and Nishi, R (1998). Activin A and follistatin influence expression of somatostatin in the ciliary ganglion in vivo. Dev. Biol 202, 293-303.[Medline]

Deshmukh, M. and Johnson, E. M. Jr (1997). Programmed cell death in neurons: focus on the pathway of nerve growth factor deprivation-induced death of sympathetic neurons. Mol. Pharmacol 51, 897-906.[Abstract/Free Full Text]

Dourado, M. M., Brumwell, C., Wisgirda, M. E., Jacob, M. H. and Dryer, S. E (1994). Target tissues and innervation regulate the characteristics of K+currents in embryonic chick ciliary ganglion neurons developing in situ. J. Neurosci 14, 3156-3165.[Abstract]

Dourado, M. M.and Dryer, S. E (1992). Changes in the electrical properties of acutely dissociated chick ciliary ganglion neurones during embryonic development. J. Physiol. (Lond.) 449, 411-428.[Abstract/Free Full Text]

Dryer, S. E (1994). Functional development of the avian ciliary ganglion: a classic model system for the study of neuronal differentiation and development. Prog. Neurobiol 43, 281-322.[Medline]

Dryer, S. E (1998). Role of cell-cell interactions in the developmental regulation of Ca2+-activated K+currents in vertebrate neurons. J. Neurobiol 37, 23-36.[Medline]

Dunn, B. E., Fitzharris, T. P. and Barnett, B. D (1981). Effects of varying chamber construction and embryo pre-incubation age on survival and growth of chick embryos in shell-less culture. Anat. Rec 199, 33-43.[Medline]

Finn, T. P., Kim, S. and Nishi, R (1998). Overexpression of ciliary neurotrophic factor in vivo rescues chick ciliary ganglion neurons from cell death. J. Neurobiol 34, 283-293.[Medline]

Fischbach, G. D and Rosen, K. M (1997). ARIA: a neuromuscular junction neuregulin. Ann. Rev. Neurosci 20, 429-458.[Medline]

Flanders, K. C., Ludecke, G., Renzig, J., Hamm, C., Cissel, D. S. and Unsicker, K (1991). Effects of TGFs and bFGF on astroglial growth and gene expression in vitro. Mol. Cell. Neurosci 4, 406-417.

Franklin, J. L. and Johnson, E. M., Jr (1992). Suppression of programmed neuronal death by sustained elevation of cytoplasmic calcium. Trends Neurosci 15, 501-508.[Medline]

Ghosh, S. and Brauer, P. R (1996). Latent transforming growth factor-is present in the extracellular matrix of embryonic hearts in situ. Dev. Dyn 205, 126-134.[Medline]

Guidry, G., Landis, S. C., Davis, B. M. and Albers, K. M (1998). Overexpression of nerve growth factor in epidermis disrupts the distribution and properties of sympathetic innervation in footpads. J. Comp. Neurol 393, 234-243.

Hallbook, F., Backstrom, A., Kullander, K., Kylberg, A., Williams, R. and Ebendal, T (1995). Neurotrophins and their receptors in chicken neuronal development. Int. J. Dev. Biol 39, 855-868.[Medline]

Hamburger, V. and Hamilton, H. L (1951). A series of normal stages in the development of the chick embryo. J. Morphol 88, 49-92.

Harpel, J. G., Metz, C. N., Kojima, S. and Rifkin, D. B (1992). Control of transforming growth factor-activity: latency vs. activation. Prog. Growth Factor Res 4, 321-335.[Medline]

Jakowlew, S. B., Ciment, G., Tuan, T. S., Sporn, M. B. and Roberts, A. B (1992). Pattern of expression of transforming growth factor-4 mRNA and protein in the developing chick embryo. Dev. Dyn 195, 276-289.[Medline]

Jakowlew, S. B., Dillard P. J., Winokur, T. S., Flanders, K. C., Sporn, M. B. and Roberts, A. B (1991). Expression of transforming growth factor-betas 1-4 in chicken embryo chondrocytes and myocytes. Dev. Biol 143, 135-148.[Medline]

Kane, C. J., Brown, G. J. and Phelan, K. D (1996). Transforming growth factor-2 stimulates and inhibits neurogenesis of rat cerebellar granule cells in culture. Dev. Brain Res 96, 46-51.[Medline]

Kaufmann, E., Paul, H., Friedle, H., Metz, A., Scheucher, M., Clement, J. H. and Knochel, W (1996). Antagonistic actions of activin A and BMP-2/4 control dorsal lip-specific activation of the early response gene XFD-1in Xenopus laevis embryos. EMBO J 15, 6739-6749.[Medline]

Landmesser L. and Pilar, G (1974). Synaptic transmission and cell death during normal ganglionic development. J. Physiol. (Lond.) 241, 737-749.[Abstract/Free Full Text]

Leung, D. W., Parent, A. S., Cachianes, G., Esch, F., Coulombe, J. N., Nikolics, K., Eckenstein, F. P. and Nishi, R (1992). Cloning, expression during development, and evidence for release of a trophic factor for ciliary ganglion neurons. Neuron 8, 1045-1053.[Medline]

Levey, M. S., Brumwell, C. L., Dryer, S. E. and Jacob, M. H (1995). Innervation and target tissue interactions differentially regulate acetylcholine receptor subunit mRNA levels in developing neurons in situ. Neuron 14, 153-162.[Medline]

Levi-Montalcini, R (1976). The nerve growth factor: its role in growth, differentiation and function of the sympathetic adrenergic neuron. Prog. Brain Res 45, 235-258.[Medline]

Maina, F., Hilton, M. C., Andres, R., Wyatt, S., Klein, R. and Davies, A. M (1998). Multiple roles for hepatocyte growth factor in sympathetic neuron development. Neuron 20, 835-846.[Medline]

Martinou, J.-C., Le Van Thai, A., Valette, A. and Weber, M (1990). Transforming growth factor-1: a potent survival factor for rat embryo motoneurons in culture. Dev. Brain Res 52, 175-181.[Medline]

McFarlane, S. and Cooper, E (1993). Extrinsic factors influence the expression of voltage-gated K currents on neonatal rat sympathetic neurons. J. Neurosci 13, 2591-2600.[Abstract]

Meriney, S. D. and Pilar, G (1987). Cholinergic innervation of the smooth muscle cells in the choroid coat of the chick eye and its development. J. Neurosci 7, 3827-3839.[Abstract]

Miyazono, K. and Heldin, C.-H (1991). Latent forms of TGF: molecular structure and mechanisms of activation. Ciba Found. Symp 157, 81-89.[Medline]

Narayanan, C. H. and Narayanan, Y (1981). Ultrastructural and histochemical observations in the developing iris musculature of the chick. J. Embryol. exp. Morphol 62, 117-127.[Medline]

Nishi, R. and Berg, D. K (1981). Two components from eye tissue that differentially stimulate the growth and development of ciliary ganglion neurons in cell culture. J. Neurosci 1, 505-513.[Abstract]

Prehn, J. H., Peruche, B., Unsicker, K. and Krieglstein, K (1993). Isoform-specific effects of transforming growth factors-on degeneration of primary neuronal cultures induced by cytotoxic hypoxia or glutamate. J. Neurochem 60, 1665-72.[Medline]

Raucher, S. and Dryer, S. E (1994). Functional expression of A-currents in embryonic chick sympathetic neurones during development in situ and in vitro. J. Physiol. (Lond.) 479, 77-93.

Raucher, S. and Dryer, S. E (1995). Target-derived factors regulate the expression of Ca2+-activated K+currents in developing chick sympathetic neurones. J. Physiol. (Lond.) 486, 605-614.

Spitzer, N. C (1994). Development of voltage-dependent and ligand-gated channels in excitable membranes. Prog. Brain Res 102, 169-179.[Medline]

Subramony, P. and Dryer, S. E (1996). The effects of innervation on the developmental expression of Ca2+-activated K+currents in embryonic parasympathetic neurons are not activity-dependent. Dev. Brain Res 91, 149-152.[Medline]

Subramony, P. and Dryer, S. E (1997). Neuregulins stimulate the functional expression of Ca2+-activated K+channels in developing chicken parasympathetic neurons. Proc. Natl. Acad. Sci. USA 94, 5934-5938.[Abstract/Free Full Text]

Subramony, P., Raucher, S., Dryer, L. and Dryer, S. E (1996). Posttranslational regulation of Ca2+-activated K+currents by a target-derived factor in developing parasympathetic neurons. Neuron 17, 115-124.[Medline]

Tang, X. M., Zhao, Y., Rossi, M. J., Abu-Rustum, R. S., Ksander, G. A. and Chegini, N (1994). Expression of transforming growth factor-(TGF ) isoforms and TGFtype II receptor messenger ribonucleic acid and protein, and the effect of TGF s on endometrial stromal cell growth and protein degradation in vitro. Endocrinology 135, 450-459.[Abstract]

Wooward, T. L., Dumont, N., O'Connor-McCourt, M., Turner, J. D. and Philip, A (1995). Characterization of transforming growth factor-growth regulatory effects and receptors on bovine mammary cells. J. Cell Physiol 165, 339-348.[Medline]

Yang, X., Kuo, Y., Devay, P., Yu, C. and Role, L (1998). A cysteine-rich isoform of neuregulin controls the level of expression of neuronal nicotinic receptor channels during synaptogenesis. Neuron 20, 255-270.[Medline]

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Articles by Cameron, J. S.

Articles by Dryer, S. E.

				K.-S. Chae, K.-S. Oh, and S. E. Dryer Growth Factors Mobilize Multiple Pools of KCa Channels in Developing Parasympathetic Neurons: Role of ADP-Ribosylation Factors and Related Proteins J Neurophysiol, August 1, 2005; 94(2): 1597 - 1605. [Abstract] [Full Text] [PDF]

				K.-S. Chae, M. Martin-Caraballo, M. Anderson, and S. E. Dryer Akt Activation Is Necessary for Growth Factor-Induced Trafficking of Functional KCa Channels in Developing Parasympathetic Neurons J Neurophysiol, March 1, 2005; 93(3): 1174 - 1182. [Abstract] [Full Text] [PDF]

				R. H. Casavant, C. M. Colbert, and S. E. Dryer A-Current Expression is Regulated by Activity but not by Target Tissues in Developing Lumbar Motoneurons of the Chick Embryo J Neurophysiol, November 1, 2004; 92(5): 2644 - 2651. [Abstract] [Full Text] [PDF]

				L. Lhuillier and S. E. Dryer Developmental Regulation of Neuronal KCa Channels by TGFbeta 1: An Essential Role for PI3 Kinase Signaling and Membrane Insertion J Neurophysiol, August 1, 2002; 88(2): 954 - 964. [Abstract] [Full Text] [PDF]

				G. Y.-P. Ko, M. L. Ko, and S. E. Dryer Developmental Expression of Retinal Cone cGMP-Gated Channels: Evidence for Rapid Turnover and Trophic Regulation J. Neurosci., January 1, 2001; 21(1): 221 - 229. [Abstract] [Full Text] [PDF]

				J. S. Cameron and S. E. Dryer BK-Type KCa Channels in Two Parasympathetic Cell Types: Differences in Kinetic Properties and Developmental Expression J Neurophysiol, December 1, 2000; 84(6): 2767 - 2776. [Abstract] [Full Text] [PDF]

				P. R. Perillan, M. Chen, E. A. Potts, and J. M. Simard Transforming Growth Factor-beta 1 Regulates Kir2.3 Inward Rectifier K+ Channels via Phospholipase C and Protein Kinase C-delta in Reactive Astrocytes from Adult Rat Brain J. Biol. Chem., January 11, 2002; 277(3): 1974 - 1980. [Abstract] [Full Text] [PDF]

				J. S. Cameron, L. Dryer, and S. E. Dryer beta -Neuregulin-1 is required for the in vivo development of functional Ca2+-activated K+ channels in parasympathetic neurons PNAS, February 27, 2001; 98(5): 2832 - 2836. [Abstract] [Full Text] [PDF]