Spatial and Temporal Expression of Lysosomal Acid Phosphatase 2 (ACP2) Reveals Dynamic Patterning of the Mouse Cerebellar Cortex (original) (raw)
Makrypidi G, Damme M, Muller-Loennies S, Trusch M, Schmidt B, Schluter H, et al. Mannose 6 dephosphorylation of lysosomal proteins mediated by acid phosphatases Acp2 and Acp5. Mol Cell Biol. 2012;32:774–82. ArticlePubMedCAS Google Scholar
Coutinho MF, Prata MJ, Alves S. Mannose-6-phosphate pathway: a review on its role in lysosomal function and dysfunction. Mol Genet Metab. 2012;105:542–50. ArticlePubMedCAS Google Scholar
Lubke T, Lobel P, Sleat DE. Proteomics of the lysosome. Biochim Biophys Acta. 2009;1793:625–35. ArticlePubMed Google Scholar
Bagshaw RD, Mahuran DJ, Callahan JW. Lysosomal membrane proteomics and biogenesis of lysosomes. Mol Neurobiol. 2005;32:27–41. ArticlePubMedCAS Google Scholar
Schroder BA, Wrocklage C, Hasilik A, Saftig P. The proteome of lysosomes. Proteomics. 2010;10:4053–76. ArticlePubMed Google Scholar
De Duve C, Pressman BC, Gianetto R, Wattiaux R, Appelmans F. Tissue fractionation studies. 6. Intracellular distribution patterns of enzymes in rat-liver tissue. Biochem J. 1955;60:604–17. Google Scholar
Mannan AU, Roussa E, Kraus C, Rickmann M, Maenner J, Nayernia K, et al. Mutation in the gene encoding lysosomal acid phosphatase (Acp2) causes cerebellum and skin malformation in mouse. Neurogenetics. 2004;5:229–38. ArticlePubMedCAS Google Scholar
Gottschalk S, Waheed A, Schmidt B, Laidler P, von Figura K. Sequential processing of lysosomal acid phosphatase by a cytoplasmic thiol proteinase and a lysosomal aspartyl proteinase. EMBO J. 1989;8:3215–9. PubMedCAS Google Scholar
Hille A, Klumperman J, Geuze HJ, Peters C, Brodsky FM, von Figura K. Lysosomal acid phosphatase is internalized via clathrin-coated pits. Eur J Cell Biol. 1992;59:106–15. PubMedCAS Google Scholar
Braun M, Waheed A, von Figura K. Lysosomal acid phosphatase is transported to lysosomes via the cell surface. EMBO J. 1989;8:3633–40. PubMedCAS Google Scholar
Geier C, Kreysing J, Boettcher H, Pohlmann R, von Figura K. Localization of lysosomal acid phosphatase mRNA in mouse tissues. J Histochem Cytochem: Off J Histochem Soc. 1992;40:1275–82. ArticleCAS Google Scholar
Thach WT. On the mechanism of cerebellar contributions to cognition. Cerebellum. 2007;6:163–7. ArticlePubMedCAS Google Scholar
Steinlin M. Cerebellar disorders in childhood: cognitive problems. Cerebellum. 2008;7:607–10. ArticlePubMed Google Scholar
Voogd J. Comparative aspects of the structure and fibre connexions of the mammalian cerebellum. Prog Brain Res. 1967;25:94–134. ArticlePubMedCAS Google Scholar
Apps R, Hawkes R. Cerebellar cortical organization: a one-map hypothesis. Nat Rev Neurosci. 2009;10:670–81. ArticlePubMedCAS Google Scholar
Sarna JR, Marzban H, Watanabe M, Hawkes R. Complementary stripes of phospholipase Cbeta3 and Cbeta4 expression by Purkinje cell subsets in the mouse cerebellum. J Comp Neurol. 2006;496:303–13. ArticlePubMedCAS Google Scholar
Marzban H, Kim CT, Doorn D, Chung SH, Hawkes R. A novel transverse expression domain in the mouse cerebellum revealed by a neurofilament-associated antigen. Neuroscience. 2008;153:1190–201. ArticlePubMedCAS Google Scholar
Sawada K, Fukui Y, Hawkes R. Spatial distribution of corticotropin-releasing factor immunopositive climbing fibers in the mouse cerebellum: analysis by whole mount immunohistochemistry. Brain Res. 2008;1222:106–17. ArticlePubMedCAS Google Scholar
Ozol K, Hayden JM, Oberdick J, Hawkes R. Transverse zones in the vermis of the mouse cerebellum. J Comp Neurol. 1999;412:95–111. ArticlePubMedCAS Google Scholar
Armstrong CL, Krueger-Naug AM, Currie RW, Hawkes R. Constitutive expression of the 25-kDa heat shock protein Hsp25 reveals novel parasagittal bands of Purkinje cells in the adult mouse cerebellar cortex. J Comp Neurol. 2000;416:383–97. ArticlePubMedCAS Google Scholar
Akintunde A, Eisenman LM. External cuneocerebellar projection and Purkinje cell zebrin II bands: a direct comparison of parasagittal banding in the mouse cerebellum. J Chem Neuroanat. 1994;7:75–86. ArticlePubMedCAS Google Scholar
Ji Z, Hawkes R. Topography of Purkinje cell compartments and mossy fiber terminal fields in lobules II and III of the rat cerebellar cortex: spinocerebellar and cuneocerebellar projections. Neuroscience. 1994;61:935–54. ArticlePubMedCAS Google Scholar
Sugihara I. Organization and remodeling of the olivocerebellar climbing fiber projection. Cerebellum. 2006;5:15–22. ArticlePubMed Google Scholar
Sugihara I, Shinoda Y. Molecular, topographic, and functional organization of the cerebellar cortex: a study with combined aldolase C and olivocerebellar labeling. J Neurosci: Off J Soc Neurosci. 2004;24:8771–85. ArticleCAS Google Scholar
Sugihara I, Quy PN. Identification of aldolase C compartments in the mouse cerebellar cortex by olivocerebellar labeling. J Comp Neurol. 2007;500:1076–92. ArticlePubMedCAS Google Scholar
Chockkan V, Hawkes R. Functional and antigenic maps in the rat cerebellum: zebrin compartmentation and vibrissal receptive fields in lobule IXa. J Comp Neurol. 1994;345:33–45. ArticlePubMedCAS Google Scholar
Chen G, Hanson CL, Ebner TJ. Functional parasagittal compartments in the rat cerebellar cortex: an in vivo optical imaging study using neutral red. J Neurophysiol. 1996;76:4169–74. PubMedCAS Google Scholar
Hallem JS, Thompson JH, Gundappa-Sulur G, Hawkes R, Bjaalie JG, Bower JM. Spatial correspondence between tactile projection patterns and the distribution of the antigenic Purkinje cell markers anti-zebrin I and anti-zebrin II in the cerebellar folium crus IIA of the rat. Neuroscience. 1999;93:1083–94. ArticlePubMedCAS Google Scholar
Baimbridge KG, Miller JJ. Immunohistochemical localization of calcium-binding protein in the cerebellum, hippocampal formation and olfactory bulb of the rat. Brain Res. 1982;245:223–9. ArticlePubMedCAS Google Scholar
De Camilli P, Miller PE, Levitt P, Walter U, Greengard P. Anatomy of cerebellar Purkinje cells in the rat determined by a specific immunohistochemical marker. Neuroscience. 1984;11:761–817. ArticlePubMed Google Scholar
Marzban H, Khanzada U, Shabir S, Hawkes R, Langnaese K, Smalla KH, et al. Expression of the immunoglobulin superfamily neuroplastin adhesion molecules in adult and developing mouse cerebellum and their localisation to parasagittal stripes. J Comp Neurol. 2003;462:286–301. ArticlePubMedCAS Google Scholar
Hawkes R, Herrup K. Aldolase C/zebrin II and the regionalization of the cerebellum. J Mol Neurosci: MN. 1995;6:147–58. ArticlePubMedCAS Google Scholar
Furuya S, Makino A, Hirabayashi Y. An improved method for culturing cerebellar Purkinje cells with differentiated dendrites under a mixed monolayer setting. Brain Res Brain Res Protocols. 1998;3:192–8. ArticleCAS Google Scholar
Tabata T, Sawada S, Araki K, Bono Y, Furuya S, Kano M. A reliable method for culture of dissociated mouse cerebellar cells enriched for Purkinje neurons. J Neurosci Methods. 2000;104:45–53. ArticlePubMedCAS Google Scholar
Marzban H, Hawkes R. Fibroblast growth factor promotes the development of deep cerebellar nuclear neurons in dissociated mouse cerebellar cultures. Brain Res. 2007;1141:25–36. ArticlePubMedCAS Google Scholar
Jande SS, Tolnai S, Lawson DE. Immunohistochemical localization of vitamin D-dependent calcium-binding protein in duodenum, kidney, uterus and cerebellum of chickens. Histochemistry. 1981;71:99–116. ArticlePubMedCAS Google Scholar
Sillitoe RV, Vogel MW, Joyner AL. Engrailed homeobox genes regulate establishment of the cerebellar afferent circuit map. J Neurosci. 2010;30:10015–24. ArticlePubMedCAS Google Scholar
Reeber SL, White JJ, George-Jones NA, Sillitoe RV. Architecture and development of olivocerebellar circuit topography. Front Neural Circ. 2012;6:115. 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
Marzban H, Zahedi S, Sanchez M, Hawkes R. Antigenic compartmentation of the cerebellar cortex in the Syrian hamster Mesocricetus auratus. Brain Res. 2003;974:176–83. ArticlePubMedCAS Google Scholar
Hawkes R. Antigenic markers of cerebellar modules in the adult mouse. Biochem Soc Trans. 1992;20:391–5. PubMedCAS Google Scholar
Eisenman LM, Hawkes R. 5′-Nucleotidase and the mabQ113 antigen share a common distribution in the cerebellar cortex of the mouse. Neuroscience. 1989;31:231–5. ArticlePubMedCAS Google Scholar
Marzban H, Hawkes R. On the architecture of the posterior zone of the cerebellum. Cerebellum. 2011;10:422–34. ArticlePubMed Google Scholar
Hatten ME, Heintz N. Mechanisms of neural patterning and specification in the developing cerebellum. Annu Rev Neurosci. 1995;18:385–408. ArticlePubMedCAS Google Scholar
Wang VY, Zoghbi HY. Genetic regulation of cerebellar development. Nat Rev Neurosci. 2001;2:484–91. ArticlePubMedCAS Google Scholar
Barkovich AJ, Millen KJ, Dobyns WB. A developmental and genetic classification for midbrain–hindbrain malformations. Brain: J Neurol. 2009;132:3199–230. Article Google Scholar
Melquist S, Craig DW, Huentelman MJ, Crook R, Pearson JV, Baker M, et al. Identification of a novel risk locus for progressive supranuclear palsy by a pooled genomewide scan of 500,288 single-nucleotide polymorphisms. Am J Hum Genet. 2007;80:769–78. ArticlePubMedCAS Google Scholar
Metcalf DJ, Calvi AA, Seaman M, Mitchison HM, Cutler DF. Loss of the Batten disease gene CLN3 prevents exit from the TGN of the mannose 6-phosphate receptor. Traffic. 2008;9:1905–14. ArticlePubMedCAS Google Scholar
Saftig P, Hartmann D, Lullmann-Rauch R, Wolff J, Evers M, Koster A, et al. Mice deficient in lysosomal acid phosphatase develop lysosomal storage in the kidney and central nervous system. J Biol Chem. 1997;272:18628–35. ArticlePubMedCAS Google Scholar
Tanaka Y, Himeno M, Kato K. Release of acid phosphatase from lysosomal membranes by cathepsin D. J Biochem. 1990;108:287–91. PubMedCAS Google Scholar
Qiao L, Hamamichi S, Caldwell KA, Caldwell GA, Yacoubian TA, Wilson S, et al. Lysosomal enzyme cathepsin D protects against alpha-synuclein aggregation and toxicity. Mol Brain. 2008;1:17. ArticlePubMed Google Scholar
Siintola E, Partanen S, Stromme P, Haapanen A, Haltia M, Maehlen J, et al. Cathepsin D deficiency underlies congenital human neuronal ceroid-lipofuscinosis. Brain. 2006;129:1438–45. ArticlePubMed Google Scholar
Croci L, Chung SH, Masserdotti G, Gianola S, Bizzoca A, Gennarini G, et al. A key role for the HLH transcription factor EBF2COE2, O/E-3 in Purkinje neuron migration and cerebellar cortical topography. Development. 2006;133:2719–29. ArticlePubMedCAS Google Scholar
Chung SH, Kim CT, Hawkes R. Compartmentation of GABA B receptor2 expression in the mouse cerebellar cortex. Cerebellum. 2008;7:295–303. ArticlePubMedCAS Google Scholar
Terada N, Banno Y, Ohno N, Fujii Y, Murate T, Sarna JR, et al. Compartmentation of the mouse cerebellar cortex by sphingosine kinase. J Comp Neurol. 2004;469:119–27. ArticlePubMedCAS Google Scholar
Marzban H, Sillitoe RV, Hoy M, Chung SH, Rafuse VF, Hawkes R. Abnormal HNK-1 expression in the cerebellum of an N-CAM null mouse. J Neurocytol. 2004;33:117–30. ArticlePubMedCAS Google Scholar
Consalez GG, Hawkes R. The compartmental restriction of cerebellar interneurons. Front Neural Circ. 2012;6:123. Google Scholar
Sillitoe RV, Marzban H, Larouche M, Zahedi S, Affanni J, Hawkes R. Conservation of the architecture of the anterior lobe vermis of the cerebellum across mammalian species. Prog Brain Res. 2005;148:283–97. ArticlePubMed Google Scholar
Sarna JR, Hawkes R. Patterned Purkinje cell death in the cerebellum. Prog Neurobiol. 2003;70:473–507. ArticlePubMedCAS Google Scholar
McGovern MM, Schuchman EH. Acid sphingomyelinase deficiency. In: Pagon RA, Bird TD, Dolan CR, Stephens K, Adam MP, editors. Gene reviews. Seattle: University of Washington; 1993.
Sarna JR, Larouche M, Marzban H, Sillitoe RV, Rancourt DE, Hawkes R. Patterned Purkinje cell degeneration in mouse models of Niemann–Pick type C disease. J Comp Neurol. 2003;456:279–91. ArticlePubMed Google Scholar
Amritraj A, Peake K, Kodam A, Salio C, Merighi A, Vance JE, et al. Increased activity and altered subcellular distribution of lysosomal enzymes determine neuronal vulnerability in Niemann–Pick type C1-deficient mice. Am J Pathol. 2009;175:2540–56. ArticlePubMedCAS Google Scholar
Butler D, Hwang J, Estick C, Nishiyama A, Kumar SS, Baveghems C, et al. Protective effects of positive lysosomal modulation in Alzheimer’s disease transgenic mouse models. PLoS One. 2011;6:e20501. ArticlePubMedCAS Google Scholar
Liang Q, Ouyang X, Schneider L, Zhang J. Reduction of mutant huntingtin accumulation and toxicity by lysosomal cathepsins D and B in neurons. Mol Neurodegener. 2011;6:37. ArticlePubMedCAS Google Scholar
Stromme P, Dobrenis K, Sillitoe RV, Gulinello M, Ali NF, Davidson C, et al. X-linked Angelman-like syndrome caused by Slc9a6 knockout in mice exhibits evidence of endosomal–lysosomal dysfunction. Brain: J Neurol. 2011;134:3369–83. Article Google Scholar
Sachs AJ, David SA, Haider NB, Nystuen AM. Patterned neuroprotection in the Inpp4a(wbl) mutant mouse cerebellum correlates with the expression of Eaat4. PLoS One. 2009;4:e8270. ArticlePubMed Google Scholar