Expression and possible role of neuronal calcium sensor-1 in the cerebellum (original) (raw)
Braunewell KH, Gundelfinger ED. Intracellular neuronal calcium sensor proteins: a family of EF-hand calcium-binding proteins in search of a function. Cell Tissue Res 1999; 295: 1–12. ArticlePubMedCAS Google Scholar
Bourne Y, Dannenberg J, Pollmann V, Marchot P, Pongs O. Immunocytochemical localization and crystal structure of human frequenin (neuronal calcium sensor 1). J Biol Chem 2001; 276: 11949–11955. ArticlePubMedCAS Google Scholar
Burgoyne RD, Weiss JL. The neuronal calcium sensor family of Ca2+-binding proteins. Biochem J 2001; 353: 1–12. ArticlePubMedCAS Google Scholar
Ikura M. Calcium binding and conformational response in EF-hand proteins. Trends Biochem Sci 1996; 21: 14–17. PubMedCAS Google Scholar
Schaad NC, De Castro E, Nef S, Hegi S, Hinrichsen R, Martone ME, Ellisman MH, Sikkink R, Rusnak F, Sygush J, Nef P. Direct modulation of calmodulin targets by the neuronal calcium sensor NCS-1. Proc Natl Acad Sci USA 1996; 93: 9253–9258. ArticlePubMedCAS Google Scholar
Pongs O, Lindemeier J, Zhu XR, Theil T, Engelkamp D, Krah-Jentgens I, Lambrecht HG, Koch KW, Schwemer J, Rivosecchi R. Frequenin-a novel calcium-binding protein that modulates synaptic efficacy in the Drosophila nervous system. Neuron 1993; 11: 15–28. ArticlePubMedCAS Google Scholar
Olafsson P, Wang T, Lu B. Molecular cloning and functional characterization of the Xenopus Ca(2+)-binding protein frequenin. Proc Natl Acad Sci USA 1995; 92: 8001–8005. ArticlePubMedCAS Google Scholar
Gomez M, De Castro E, Guarin E, Sasakura H, Kuhara A, Mori I, Bartfai T, Bargmann CI, Nef P. Ca2+ signaling via the neuronal calcium sensor-1 regulates associative learning and memory in C. elegans. Neuron 2001; 30: 241–248. ArticlePubMedCAS Google Scholar
Tsujimoto T, Jeromin A, Saitoh N, Roder JC, Takahashi T. Neuronal calcium sensor 1 and activity-dependent facilitation of P/Q-type calcium currents at presynaptic nerve terminals. Science 2002; 295: 2276–2279. ArticlePubMedCAS Google Scholar
Sippy T, Cruz-Martin A, Jeromin A, Schweizer FE. Acute changes in short-term plasticity at synapses with elevated levels of neuronal calcium sensor-1. Nat Neurosci 2003; 6(10): 1031–1038. ArticlePubMedCAS Google Scholar
Olafsson P, Soares HD, Herzog KH, Wang T, Morgan JI, Lu B. The Ca2+ binding protein, frequenin is a nervous system-specific protein in mouse preferentially localized in neurites. Brain Res Mol Brain Res 1997; 44: 73–82. ArticlePubMedCAS Google Scholar
Martone ME, Edelmann VM, Ellisman MH, Nef P. Cellular and subcellular distribution of the calcium-binding protein NCS-1 in the central nervous system of the rat. Cell Tissue Res 1999; 295: 395–407. ArticlePubMedCAS Google Scholar
Bergmann M, Grabs D, Roder J, Rager G, Jeromin A. Differential expression of neuronal calcium sensor-1 in the developing chick retina. J Comp Neurol 2002; 449: 231–240. ArticlePubMedCAS Google Scholar
Wilkinson BL, Jeromin A, Roder J, Hyson RL. Activity-dependent regulation of the subcellular localization of neuronal calcium sensor-1 in the avian cochlear nucleus. Neuroscience 2003; 117: 957–964. ArticlePubMedCAS Google Scholar
Paterlini M, Revilla V, Grant AL, Wisden W. Expression of the neuronal calcium sensor protein family in the rat brain. Neuroscience 2000; 99: 205–216. ArticlePubMedCAS Google Scholar
Jinno S, Jeromin A, Roder J, Kosaka T. Immunocytochemical localization of neuronal calcium sensor-1 in the hippocampus and cerebellum of the mouse, with special reference to presynaptic terminals. Neuroscience 2002; 113: 449–461. ArticlePubMedCAS Google Scholar
Jinno S, Jeromin A, Roder J, Kosaka T. Compartmentation of the mouse cerebellar cortex by neuronal calcium sensor-1. J Comp Neurol 2003; 458: 412–424. ArticlePubMedCAS Google Scholar
Voogd J, Jaarsma D, Marani E. The cerebellum: chemoarchitecture and anatomy. In: Swanson LW, Bjöorklund A, Hökfelt T, editors. Handbook of Chemical Neuroanatomy. Elsevier, Amsterdam, 1996: 1–369. Google Scholar
Garcia-Segura LM, Baetens D, Roth J, Norman AW, Orci L. Immunohistochemical mapping of calcium-binding protein immunoreactivity in the rat central nervous system. Brain Res 1984; 296: 75–86. ArticlePubMedCAS Google Scholar
Schneeberger PR, Norman AW, Heizmann CW. Parvalbumin and vitamin D-dependent calcium-binding protein (Mr 28,000): comparison of their localization in the cerebellum of normal and rachitic rats. Neurosci Lett 1985; 59: 97–103. ArticlePubMedCAS Google Scholar
Celio MR, Heizmann CW. Calcium-binding protein parvalbumin as a neuronal marker. Nature 1981; 293: 300–302. ArticlePubMedCAS Google Scholar
Brown B, Epema A, Marani E. Topography of acetylcholinesterase in the developing rabbit and cat cerebellum. In: Topographic histochemistry of the cerebellum. 5′-nucleotidase, acetylcholinesterase, Immunology of FAL. Prog Histochem Cytochem 1986; 16/ 4: 117–127. Google Scholar
Rogers JH. Immunoreactivity for calretinin and other calciumbinding proteins in cerebellum. Neuroscience 1989; 3: 711–721. Article Google Scholar
Celio MR. Calbindin D-28k and parvalbumin in the rat nervous system. Neuroscience 1990; 35: 375–475. ArticlePubMedCAS Google Scholar
Oberdick J, Baader SL, Schilling K. From zebra stripes to postal zones: deciphering patterns of gene expression in the cerebellum. Trends Neurosci 1998; 21: 383–390. ArticlePubMedCAS Google Scholar
Scott TG. A unique pattern of localization within the cerebellum of the mouse. J Comp Neurol 1964; 122: 1–8. Article Google Scholar
Ramon-Molier E. Acetylthiocholinesterase distribution in the brainstem of the cat. Ergebn Anat 1972; 46: 1–52. Google Scholar
Marani E, Voogd J. An acetylcholinesterase band pattern in the molecular layer of the cat cerebellum. J Anat 1977; 124: 335–345. PubMedCAS Google Scholar
Ingram VI, Ogren MP, Chatot CL, Gossels JM, Owens BB. Diversity among Purkinje cells in the monkey cerebellum. Proc Natl Acad Sci USA 1985; 82: 7131–7135. ArticlePubMedCAS Google Scholar
Hess DT, Voogd J. Chemoarchitectonic zonation of the monkey cerebellum. Brain Res 1986; 369: 383–387. ArticlePubMedCAS Google Scholar
Chan-Palay V, Nilaver G, Palay SL, Beinfeld MC, Zimmerman EA, Wu J-Y, O’Donohue TL. Chemical heterogeneity in cerebellar Purkinje cells: existence and coexistence of glutamic acid decarboxylase-like and motilin-like immunoreactivities. Proc Natl Acad Sci USA 1981; 78: 7787–7791. ArticlePubMedCAS Google Scholar
Chan-Palay V, Lin CT, Palay S, Yamamoto M, Wu J-Y. Taurine in the mammalian cerebellum: demonstration by autoradiography with [3H] taurine and immunocytochemistry with antibodies against the taurine-synthesizing enzyme, cysteine-sulfinic acid decarboxylase. Proc Natl Acad Sci USA 1982; 79: 2695–2699. ArticlePubMedCAS Google Scholar
Chan-Palay V, Palay SL, Wu J-Y. Sagittal cerebellar microbands of taurine neurons: immunocytochemical demonstration by using antibodies against the taurine synthesizing enzyme cysteine sulfinic acid decarboxylase. Proc Natl Acad Sci USA 1982; 79: 4221–4225. ArticlePubMedCAS Google Scholar
Hawkes R, Colonnier M, Leclerc N. Monoclonal antibodies reveal sagittal banding in the rodent cerebellar cortex. Brain Res 1985; 333: 359–365. ArticlePubMedCAS Google Scholar
Hawkes R, Leclerc N. Antigenic map of the rat cerebellar cortex: the distribution of parasagittal bands as revealed by monoclonal anti-Purkinje cell antibody mabQ113. J Comp Neurol 1987; 256: 29–41. ArticlePubMedCAS Google Scholar
Albin RL, Gilman S. Parasagittal zonation of GABA-B receptors in molecular layer of rat cerebellum. Eur J Pharmacol 1989; 173: 113–114. ArticlePubMedCAS Google Scholar
Brochu G, Maler L, Hawkes R. Zebrin II: a polypeptide antigen expressed selectively by Purkinje cells reveals compartments in rat and fish cerebellum. J Comp Neurol 1990; 291: 538–552. ArticlePubMedCAS Google Scholar
Eisenman LM, Hawkes R. Antigenic compartmentation in the mouse cerebellar cortex: zebrin and HNK-1 reveal a complex, overlapping molecular topography. J Comp Neurol 1993; 335: 586–605. ArticlePubMedCAS Google Scholar
Chen S, Hillman DE. Compartmentation of the cerebellar cortex by protein kinase C delta. Neuroscience 1993; 56: 177–188. ArticlePubMedCAS Google Scholar
Leclerc N, Schwarting GA, Herrup K, Hawkes R, Yamamoto M. Compartmentation in mammalian cerebellum: Zebrin II and P-path antibodies define three classes of sagittally organized bands of Purkinje cells. Proc Natl Acad Sci USA 1992; 89: 5006–5010. ArticlePubMedCAS Google Scholar
Armstrong CL, Krueger-Naug AM, Currie RW, Hawkes R. Expression of heat-shock protein Hsp25 in mouse Purkinje cells during development reveals novel features of cerebellar compartmentation. J Comp Neurol 2001; 429: 7–21. ArticlePubMedCAS Google Scholar
Jansen J, Brodai A. Experimental studies on the intrinsic fibers of the cerebellum. II. The cortico-nuclear projection. J Comp Neurol 1940; 73: 267–321. Article Google Scholar
Goodman DC, Hellitt RE, Welch RB. Patterns of localization in the cerebellar corticonuclear projections of the albino rat. J Comp Neurol 1963; 121: 51–68. ArticlePubMedCAS Google Scholar
Haines DE, Patrick GW, Satrulee P. Organization of cerebellar corticonuclear fiber system. In: Palay SL, Chan-Palay V, editors. The Cerebellum. Berlin: New Vistas, Springer, 1982: 320–367. Google Scholar
Voogd J. The importance of fiber connections in the comparative anatomy of the mammalian cerebellum. In: Llinas R, editor. Neurobiology of Cerebellar Evolution and Development. Chicago: American Medical Association, 1969: 493–514. Google Scholar
Gravel C, Eisenman LM, Sasseville R, Hawkes R. Parasagittal organization of the rat cerebellar cortex: direct correlation between antigenic Purkinje cell bands revealed by mabQ113 and the organization of the olivocerebellar projection. J Comp Neurol 1987; 265: 294–310. ArticlePubMedCAS Google Scholar
Gravel C, Hawkes R. Parasagittal organization of the rat cerebellar cortex: direct comparison of Purkinje cell compartments and the organization of the spinocerebellar projection. J Comp Neurol 1990; 291: 79–102. ArticlePubMedCAS Google Scholar
Oberdick J, Schilling K, Smeyne RJ, Corbin JG, Bocchiaro C, Morgan JI. Control of segment-like patterns of gene expression in the mouse cerebellum. Neuron 1993; 10: 1007–1018. ArticlePubMedCAS Google Scholar
Chedotal A, Pourquie O, Ezan F, San Clemente H, Sotelo C. BEN as a presumptive target recognition molecule during the development of the olivocerebellar system. J Neurosci 1996; 16: 3296–3310. PubMedCAS Google Scholar
Poulain C, Ferrus A, Mallart A. Modulation of type A K+ current in Drosophila larval muscle by internal Ca2+; effects of the overexpression of frequenin. Pflugers Arch 1994; 427: 71–79. ArticlePubMedCAS Google Scholar
Angaut-Petit D, Toth P, Rogero O, Faille L, Tejedor FJ, Ferrus A. Enhanced neurotransmitter release is associated with reduction of neuronal branching in a Drosophila mutant overexpressing frequenin. Eur J Neurosci 1998; 10: 423–434. ArticlePubMedCAS Google Scholar
Chen XL, Zhong ZG, Yokoyama S, Bark C, Meister B, Berggren PO, Roder J, Higashida H, Jeromin A. Overexpression of rat neuronal calcium sensor-1 in rodent NG108-15 cells enhances synapse formation and transmission. J Physiol 2001; 532: 649–659. ArticlePubMedCAS Google Scholar
Hansel C, Linden DJ, D’Angelo E. Beyond parallel fiber LTD: the diversity of synaptic and non-synaptic plasticity in the cerebellum. Nat Neurosci 2001; 4: 467–475. PubMedCAS Google Scholar
Ito M. The molecular organization of cerebellar long-term depression. Nat Rev Neurosci 2002; 3: 896–902. ArticlePubMedCAS Google Scholar
Crepel F, Jaillard D. Protein kinases, nitric oxide and long-term depression of synapses in the cerebellum. Neuroreport 1990; 1: 133–136. ArticlePubMedCAS Google Scholar
Daniel H, Hemart N, Jaillard D, Crepel F. Long-term depression requires nitric oxide and guanosine 3′: 5′ cyclic monophosphate production in rat cerebellar Purkinje cells. Eur J Neurosci 1993; 5: 1079–1082. ArticlePubMedCAS Google Scholar
Daniel H, Levenes C, Crepel F. Cellular mechanisms of cerebellar LTD. Trends Neurosci 1998; 21: 401–407. ArticlePubMedCAS Google Scholar
Crepel F, Krupa M. Activation of protein kinase C induces a long term depression of glutamate sensitivity of cerebellar Purkinje cells. An in vitro study. Brain Res 1988; 458: 397–401. ArticlePubMedCAS Google Scholar
Linden DJ, Connor JA. Long-term depression of glutamate currents in cultured cerebellar Purkinje neurons does not require nitric oxide signaling. Eur J Neurosci 1992; 4: 10–15. ArticlePubMed Google Scholar
Weiss JL, Burgoyne RD. Voltage-independent inhibition of P/Q-type Ca2+ channels in adrenal chromaffin cells via a neuronal Ca2+ sensor-1-dependent pathway involves Src family tyrosine kinase. J Biol Chem 2001; 276: 44804–44811. ArticlePubMedCAS Google Scholar
Rousset M, Cens T, Gavarini S, Jeromin A, Charnet P. Downregulation of voltage-gated Ca2+ channels by neuronal calcium sensor-1 is beta subunit-specific. J Biol Chem. 2003; 278: 7019–7026. ArticlePubMedCAS Google Scholar
Wang SS, Denk W, Hausser M. Coincidence detection in single dendritic spines mediated by calcium release. Nat Neurosci 2000; 3: 1266–1273. ArticlePubMedCAS Google Scholar
Hawkes R, Turner RW. Compartmentation of NADPH-diaphorase activity in the mouse cerebellar cortex. J Comp Neurol 1994; 346: 499–516. ArticlePubMedCAS Google Scholar
Hope BT, Vincent SR. Histochemical characterization of neuronal NADPH-diaphorase. J Histochem Cytochem 1989; 37: 653–661. PubMedCAS Google Scholar
Wassef M, Cholley B, Heizmann CW, Sotelo C. Development of the olivocerebellar projection in the rat: II. Matching of the developmental compartmentations of the cerebellum and inferior olive through the projection map. J Comp Neurol 1992; 323: 537–550. ArticlePubMedCAS Google Scholar