Papers associated with mcidas

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	Ciliary transcription factors and miRNAs precisely regulate Cp110 levels required for ciliary adhesions and ciliogenesis., Walentek P, Quigley IK, Sun DI, Sajjan UK, Kintner C, Harland RM., Elife. September 13, 2016; 5
	The aryl hydrocarbon receptor controls cyclin O to promote epithelial multiciliogenesis., Villa M, Crotta S, Dingwell KS, Hirst EM, Gialitakis M, Ahlfors H, Smith JC, Stockinger B, Wack A., Nat Commun. August 24, 2016; 7 12652.
	MicroRNAs as key regulators of GTPase-mediated apical actin reorganization in multiciliated epithelia., Mercey O, Kodjabachian L, Barbry P, Marcet B., Small GTPases. April 2, 2016; 7 (2): 54-8.
	Systematic Analysis of CCNO Variants in a Defined Population: Implications for Clinical Phenotype and Differential Diagnosis., Amirav I, Wallmeier J, Loges NT, Menchen T, Pennekamp P, Mussaffi H, Abitbul R, Avital A, Bentur L, Dougherty GW, Nael E, Lavie M, Olbrich H, Werner C, Kintner C, Omran H, Israeli PCD Consortium Investigators., Hum Mutat. April 1, 2016; 37 (4): 396-405.
	Gmnc Is a Master Regulator of the Multiciliated Cell Differentiation Program., Zhou F, Narasimhan V, Shboul M, Chong YL, Reversade B, Roy S., Curr Biol. December 21, 2015; 25 (24): 3267-73.
	ATP4a is required for development and function of the Xenopus mucociliary epidermis - a potential model to study proton pump inhibitor-associated pneumonia., Walentek P, Beyer T, Hagenlocher C, Müller C, Feistel K, Schweickert A, Harland RM, Blum M., Dev Biol. December 15, 2015; 408 (2): 292-304.
	Prdm12 specifies V1 interneurons through cross-repressive interactions with Dbx1 and Nkx6 genes in Xenopus., Thélie A, Desiderio S, Hanotel J, Quigley I, Van Driessche B, Rodari A, Borromeo MD, Kricha S, Lahaye F, Croce J, Cerda-Moya G, Ordoño Fernandez J, Bolle B, Lewis KE, Sander M, Pierani A, Schubert M, Johnson JE, Kintner CR, Pieler T, Van Lint C, Henningfeld KA, Bellefroid EJ, Van Campenhout C., Development. October 1, 2015; 142 (19): 3416-28.
	miR-34/449 control apical actin network formation during multiciliogenesis through small GTPase pathways., Chevalier B, Adamiok A, Mercey O, Revinski DR, Zaragosi LE, Pasini A, Kodjabachian L, Barbry P, Marcet B., Nat Commun. September 18, 2015; 6 8386.
	BMP signalling controls the construction of vertebrate mucociliary epithelia., Cibois M, Luxardi G, Chevalier B, Thomé V, Mercey O, Zaragosi LE, Barbry P, Pasini A, Marcet B, Kodjabachian L., Development. July 1, 2015; 142 (13): 2352-63.
	TGF-β Signaling Regulates the Differentiation of Motile Cilia., Tözser J, Earwood R, Kato A, Brown J, Tanaka K, Didier R, Megraw TL, Blum M, Kato Y., Cell Rep. May 19, 2015; 11 (7): 1000-7.
	Centriole biogenesis and function in multiciliated cells., Zhang S, Mitchell BJ., Methods Cell Biol. January 1, 2015; 129 103-127.
	Genome-wide view of TGFβ/Foxh1 regulation of the early mesendoderm program., Chiu WT, Charney Le R, Blitz IL, Fish MB, Li Y, Biesinger J, Xie X, Cho KW., Development. December 1, 2014; 141 (23): 4537-47.
	Chibby functions in Xenopus ciliary assembly, embryonic development, and the regulation of gene expression., Shi J, Zhao Y, Galati D, Winey M, Klymkowsky MW., Dev Biol. November 15, 2014; 395 (2): 287-98.
	Multiciliogenesis: multicilin directs transcriptional activation of centriole formation., Balestra FR, Gönczy P., Curr Biol. August 18, 2014; 24 (16): R746-9.
	MCIDAS mutations result in a mucociliary clearance disorder with reduced generation of multiple motile cilia., Boon M, Wallmeier J, Ma L, Loges NT, Jaspers M, Olbrich H, Dougherty GW, Raidt J, Werner C, Amirav I, Hevroni A, Abitbul R, Avital A, Soferman R, Wessels M, O'Callaghan C, Chung EM, Rutman A, Hirst RA, Moya E, Mitchison HM, Van Daele S, De Boeck K, Jorissen M, Kintner C, Cuppens H, Omran H., Nat Commun. July 22, 2014; 5 4418.
	Multicilin drives centriole biogenesis via E2f proteins., Ma L, Quigley I, Omran H, Kintner C., Genes Dev. July 1, 2014; 28 (13): 1461-71.
	Mutations in CCNO result in congenital mucociliary clearance disorder with reduced generation of multiple motile cilia., Wallmeier J, Al-Mutairi DA, Chen CT, Loges NT, Pennekamp P, Menchen T, Ma L, Shamseldin HE, Olbrich H, Dougherty GW, Werner C, Alsabah BH, Köhler G, Jaspers M, Boon M, Griese M, Schmitt-Grohé S, Zimmermann T, Koerner-Rettberg C, Horak E, Kintner C, Alkuraya FS, Omran H., Nat Genet. June 1, 2014; 46 (6): 646-51.
	RFX7 is required for the formation of cilia in the neural tube., Manojlovic Z, Earwood R, Kato A, Stefanovic B, Kato Y., Mech Dev. May 1, 2014; 132 28-37.
	Coordinated genomic control of ciliogenesis and cell movement by RFX2., Chung MI, Kwon T, Tu F, Brooks ER, Gupta R, Meyer M, Baker JC, Marcotte EM, Wallingford JB., Elife. January 1, 2014; 3 e01439.
	The Geminin and Idas coiled coils preferentially form a heterodimer that inhibits Geminin function in DNA replication licensing., Caillat C, Pefani DE, Gillespie PJ, Taraviras S, Blow JJ, Lygerou Z, Perrakis A., J Biol Chem. November 1, 2013; 288 (44): 31624-34.
	Deuterosome-mediated centriole biogenesis., Klos Dehring DA, Vladar EK, Werner ME, Mitchell JW, Hwang P, Mitchell BJ., Dev Cell. October 14, 2013; 27 (1): 103-12.
	Myb promotes centriole amplification and later steps of the multiciliogenesis program., Tan FE, Vladar EK, Ma L, Fuentealba LC, Hoh R, Espinoza FH, Axelrod JD, Alvarez-Buylla A, Stearns T, Kintner C, Krasnow MA., Development. October 1, 2013; 140 (20): 4277-86.
	Ciliogenesis and cerebrospinal fluid flow in the developing Xenopus brain are regulated by foxj1., Hagenlocher C, Walentek P, M Ller C, Thumberger T, Feistel K., Cilia. April 29, 2013; 2 (1): 12.
	Amputation-induced reactive oxygen species are required for successful Xenopus tadpole tail regeneration., Love NR, Chen Y, Ishibashi S, Kritsiligkou P, Lea R, Koh Y, Gallop JL, Dorey K, Amaya E., Nat Cell Biol. February 1, 2013; 15 (2): 222-8.
	Multicilin promotes centriole assembly and ciliogenesis during multiciliate cell differentiation., Stubbs JL, Vladar EK, Axelrod JD, Kintner C., Nat Cell Biol. January 8, 2012; 14 (2): 140-7.
	Use of tc-99m mebrofenin as a clinical probe to assess altered hepatobiliary transport: integration of in vitro, pharmacokinetic modeling, and simulation studies., Ghibellini G, Leslie EM, Pollack GM, Brouwer KL., Pharm Res. August 1, 2008; 25 (8): 1851-60.
	Neuroprotective role of testosterone in the nervous system., Białek M, Zaremba P, Borowicz KK, Czuczwar SJ., Pol J Pharmacol. January 1, 2004; 56 (5): 509-18.
	Specificity of ascorbate analogs for ascorbate transport. Synthesis and detection of [(125)I]6-deoxy-6-iodo-L-ascorbic acid and characterization of its ascorbate-specific transport properties., Rumsey SC, Welch RW, Garraffo HM, Ge P, Lu SF, Crossman AT, Kirk KL, Levine M., J Biol Chem. August 13, 1999; 274 (33): 23215-22.
	Synthesis of 153N-6 analogues and structure-function analysis at murine melanocortin-1 (MC1) receptors., Sahm UG, Olivier GW, Pouton CW., Peptides. January 1, 1999; 20 (3): 387-94.
	Xenopus HDm, a maternally expressed histone deacetylase, belongs to an ancient family of acetyl-metabolizing enzymes., Ladomery M, Lyons S, Sommerville J., Gene. October 1, 1997; 198 (1-2): 275-80.
	Patterning of the mesoderm in Xenopus: dose-dependent and synergistic effects of Brachyury and Pintallavis., O'Reilly MA, Smith JC, Cunliffe V., Development. May 1, 1995; 121 (5): 1351-9.
	A major developmental transition in early Xenopus embryos: I. characterization and timing of cellular changes at the midblastula stage., Newport J, Kirschner M., Cell. October 1, 1982; 30 (3): 675-86.

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