Gene Expression Literature Summary

• Symbol: Elavl2
• Name: ELAV like RNA binding protein 1
• ID: MGI:1100887

37 matching records from 37 references.

Summary by Age and Assay: Numbers in the table indicate the number of results matching the search criteria.

Age	E0.5	E1	E2	E2.5	E3	E3.5	E7	E9.5	E10	E10.5	E11	E11.5	E12.5	E13.5	E14	E14.5	E15	E15.5	E16	E16.5	E17	E17.5	E18.5	E	P
Immunohistochemistry (section)								1		1			3		1	3			1	2		1	1		8
In situ RNA (section)												1		2	1	6		2	1	1					7
Immunohistochemistry (whole mount)	1	2	2	1	1	1																			2
In situ RNA (whole mount)								2		2		2
Northern blot							1				1						1				1				1
Western blot									1						1							1			4
RT-PCR	3	3	1	2	1	3			1	2			3	2		3	1	2	2	2		1	3		10
cDNA clones																								1	2

Summary by Gene and Reference: Number indicates the number of results matching the search criteria recorded for each reference.
* Indicates detailed expression data entries available

Elavl2  ELAV like RNA binding protein 1   (Synonyms: Hub, mel-N1)
Results	Reference
1	J:31495 Abe R, Uyeno Y, Yamamoto K, Sakamoto H, Tissue-specific expression of the gene encoding a mouse RNA binding protein homologous to human HuD antigen. DNA Res. 1994;1(4):175-80
5*	J:51307 Atasoy U, Watson J, Patel D, Keene JD, ELAV protein HuA (HuR) can redistribute between nucleus and cytoplasm and is upregulated during serum stimulation and T cell activation. J Cell Sci. 1998 Nov;111(Pt 21):3145-56
1*	J:313619 Bedogni F, Hevner RF, Cell-Type-Specific Gene Expression in Developing Mouse Neocortex: Intermediate Progenitors Implicated in Axon Development. Front Mol Neurosci. 2021;14:686034
8	J:311486 Chalupnikova K, Solc P, Sulimenko V, Sedlacek R, Svoboda P, An oocyte-specific ELAVL2 isoform is a translational repressor ablated from meiotically competent antral oocytes. Cell Cycle. 2014;13(7):1187-200
1*	J:153498 Diez-Roux G, Banfi S, Sultan M, Geffers L, Anand S, Rozado D, Magen A, Canidio E, Pagani M, Peluso I, Lin-Marq N, Koch M, Bilio M, Cantiello I, Verde R, De Masi C, Bianchi SA, Cicchini J, Perroud E, Mehmeti S, Dagand E, Schrinner S, Nurnberger A, SchmidtK, Metz K, Zwingmann C, Brieske N, Springer C, Hernandez AM, Herzog S, Grabbe F, Sieverding C, Fischer B, Schrader K, Brockmeyer M, Dettmer S, Helbig C, Alunni V, Battaini MA, Mura C, Henrichsen CN, Garcia-Lopez R, Echevarria D, Puelles E, et al., A high-resolution anatomical atlas of the transcriptome in the mouse embryo. PLoS Biol. 2011;9(1):e1000582
1	J:95876 Englund C, Fink A, Lau C, Pham D, Daza RA, Bulfone A, Kowalczyk T, Hevner RF, Pax6, Tbr2, and Tbr1 are expressed sequentially by radial glia, intermediate progenitor cells, and postmitotic neurons in developing neocortex. J Neurosci. 2005 Jan 5;25(1):247-51
14*	J:91422 Evsikov AV, de Vries WN, Peaston AE, Radford EE, Fancher KS, Chen FH, Blake JA, Bult CJ, Latham KE, Solter D, Knowles BB, Systems biology of the 2-cell mouse embryo. Cytogenet Genome Res. 2004;105(2-4):240-50
3	J:329983 Fidalgo MF, Fonseca CG, Caldas P, Raposo AA, Balboni T, Henao-Misikova L, Grosso AR, Vasconcelos FF, Franco CA, Aerocyte specification and lung adaptation to breathing is dependent on alternative splicing changes. Life Sci Alliance. 2022 Dec;5(12):e202201554
1*	J:162172 Fox EA, McAdams J, Smooth-muscle-specific expression of neurotrophin-3 in mouse embryonic and neonatal gastrointestinal tract. Cell Tissue Res. 2010 May;340(2):267-86
3*	J:46439 Freeman TC, Dixon AK, Campbell EA, Tait TM, Richardson PJ, Rice KM, Maslen GL, Metcalfe AD, Streuli CH, Bentley DR, Expression Mapping of Mouse Genes. MGI Direct Data Submission. 1998;
1	J:182988 Garcia-Dominguez DJ, Morello D, Cisneros E, Kontoyiannis DL, Frade JM, Stabilization of Dll1 mRNA by Elavl1/HuR in neuroepithelial cells undergoing mitosis. Mol Biol Cell. 2011 Apr 15;22(8):1227-39
1*	J:302050 Hanemaaijer ES, Margaritis T, Sanders K, Bos FL, Candelli T, Al-Saati H, van Noesel MM, Meyer-Wentrup FAG, van de Wetering M, Holstege FCP, Clevers H, Single-cell atlas of developing murine adrenal gland reveals relation of Schwann cell precursor signature to neuroblastoma phenotype. Proc Natl Acad Sci U S A. 2021 Feb 2;118(5):e2022350118
2	J:215364 Hasegawa Y, Yoshida D, Nakamura Y, Sakakibara S, Spatiotemporal distribution of SUMOylation components during mouse brain development. J Comp Neurol. 2014 Sep 1;522(13):3020-36
1	J:203028 Hasenpusch-Theil K, Magnani D, Amaniti EM, Han L, Armstrong D, Theil T, Transcriptional analysis of Gli3 mutants identifies Wnt target genes in the developing hippocampus. Cereb Cortex. 2012 Dec;22(12):2878-93
1*	J:109593 Heanue TA, Pachnis V, Expression profiling the developing mammalian enteric nervous system identifies marker and candidate Hirschsprung disease genes. Proc Natl Acad Sci U S A. 2006 May 2;103(18):6919-24
4*	J:125833 Joshi S, Davies H, Sims LP, Levy SE, Dean J, Ovarian gene expression in the absence of FIGLA, an oocyte-specific transcription factor. BMC Dev Biol. 2007;7:67
1	J:308791 Kameneva P, Artemov AV, Kastriti ME, Faure L, Olsen TK, Otte J, Erickson A, Semsch B, Andersson ER, Ratz M, Frisen J, Tischler AS, de Krijger RR, Bouderlique T, Akkuratova N, Vorontsova M, Gusev O, Fried K, Sundstrom E, Mei S, Kogner P, Baryawno N, Kharchenko PV, Adameyko I, Single-cell transcriptomics of human embryos identifies multiple sympathoblast lineages with potential implications for neuroblastoma origin. Nat Genet. 2021 May;53(5):694-706
7	J:282136 Kato Y, Iwamori T, Ninomiya Y, Kohda T, Miyashita J, Sato M, Saga Y, ELAVL2-directed RNA regulatory network drives the formation of quiescent primordial follicles. EMBO Rep. 2019 Dec 5;20(12):e48251
1	J:230563 Kato Y, Katsuki T, Kokubo H, Masuda A, Saga Y, Dazl is a target RNA suppressed by mammalian NANOS2 in sexually differentiating male germ cells. Nat Commun. 2016;7:11272
1*	J:138815 Kawaguchi A, Ikawa T, Kasukawa T, Ueda HR, Kurimoto K, Saitou M, Matsuzaki F, Single-cell gene profiling defines differential progenitor subclasses in mammalian neurogenesis. Development. 2008 Sep;135(18):3113-24
3*	J:162220 Magdaleno S, Jensen P, Brumwell CL, Seal A, Lehman K, Asbury A, Cheung T, Cornelius T, Batten DM, Eden C, Norland SM, Rice DS, Dosooye N, Shakya S, Mehta P, Curran T, BGEM: an in situ hybridization database of gene expression in the embryonic and adult mouse nervous system. PLoS Biol. 2006 Apr;4(4):e86
6*	J:150715 Malcuit C, Trask MC, Santiago L, Beaudoin E, Tremblay KD, Mager J, Identification of novel oocyte and granulosa cell markers. Gene Expr Patterns. 2009 Sep;9(6):404-10
4*	J:103446 McKee AE, Minet E, Stern C, Riahi S, Stiles CD, Silver PA, A genome-wide in situ hybridization map of RNA-binding proteins reveals anatomically restricted expression in the developing mouse brain. BMC Dev Biol. 2005 Jul 20;5:14
1*	J:205051 Miller JA, Nathanson J, Franjic D, Shim S, Dalley RA, Shapouri S, Smith KA, Sunkin SM, Bernard A, Bennett JL, Lee CK, Hawrylycz MJ, Jones AR, Amaral DG, Sestan N, Gage FH, Lein ES, Conserved molecular signatures of neurogenesis in the hippocampal subgranular zone of rodents and primates. Development. 2013 Nov;140(22):4633-44
1	J:214809 Moniot B, Ujjan S, Champagne J, Hirai H, Aritake K, Nagata K, Dubois E, Nidelet S, Nakamura M, Urade Y, Poulat F, Boizet-Bonhoure B, Prostaglandin D2 acts through the Dp2 receptor to influence male germ cell differentiation in the foetal mouse testis. Development. 2014 Sep;141(18):3561-71
13	J:62325 Okano HJ, Darnell RB, A hierarchy of Hu RNA binding proteins in developing and adult neurons. J Neurosci. 1997 May 1;17(9):3024-37
4	J:187391 Pacal M, Bremner R, Mapping differentiation kinetics in the mouse retina reveals an extensive period of cell cycle protein expression in post-mitotic newborn neurons. Dev Dyn. 2012 Oct;241(10):1525-44
1	J:232516 Parchem RJ, Moore N, Fish JL, Parchem JG, Braga TT, Shenoy A, Oldham MC, Rubenstein JL, Schneider RA, Blelloch R, miR-302 Is Required for Timing of Neural Differentiation, Neural Tube Closure, and Embryonic Viability. Cell Rep. 2015 Aug 4;12(5):760-73
2	J:156036 Schilling K, Oberdick J, The treasury of the commons: making use of public gene expression resources to better characterize the molecular diversity of inhibitory interneurons in the cerebellar cortex. Cerebellum. 2009 Dec;8(4):477-89
1	J:296487 Schoof M, Launspach M, Holdhof D, Nguyen L, Engel V, Filser S, Peters F, Immenschuh J, Hellwig M, Niesen J, Mall V, Ertl-Wagner B, Hagel C, Spohn M, Lutz B, Sedlacik J, Indenbirken D, Merk DJ, Schuller U, The transcriptional coactivator and histone acetyltransferase CBP regulates neural precursor cell development and migration. Acta Neuropathol Commun. 2019 Dec 5;7(1):199
3	J:170671 Shibata M, Nakao H, Kiyonari H, Abe T, Aizawa S, MicroRNA-9 regulates neurogenesis in mouse telencephalon by targeting multiple transcription factors. J Neurosci. 2011 Mar 2;31(9):3407-22
4*	J:209112 Shimizu H, Kubo A, Uchibe K, Hashimoto M, Yokoyama S, Takada S, Mitsuoka K, Asahara H, The AERO system: a 3D-like approach for recording gene expression patterns in the whole mouse embryo. PLoS One. 2013;8(10):e75754
1	J:219688 Shinomura M, Kishi K, Tomita A, Kawasumi M, Kanezashi H, Kuroda Y, Tsunekawa N, Ozawa A, Aiyama Y, Yoneda A, Suzuki H, Saito M, Picard JY, Kohno K, Kurohmaru M, Kanai-Azuma M, Kanai Y, A novel Amh-Treck transgenic mouse line allows toxin-dependent loss of supporting cells in gonads. Reproduction. 2014 Dec;148(6):H1-9
1	J:216104 Sugiyama T, Osumi N, Katsuyama Y, A novel cell migratory zone in the developing hippocampal formation. J Comp Neurol. 2014 Oct 15;522(15):3520-38
1	J:343100 Takada Y, Fierro L, Sato K, Sanada T, Ishii A, Yamamoto T, Kotani T, Mature mRNA processing that deletes 3' end sequences directs translational activation and embryonic development. Sci Adv. 2023 Nov 24;9(47):eadg6532
12	J:307191 Wu M, Deng Q, Lei X, Du Y, Shen Y, Elavl2 Regulates Retinal Function Via Modulating the Differentiation of Amacrine Cells Subtype. Invest Ophthalmol Vis Sci. 2021 Jun 1;62(7):1
3*	J:156017 Yokoyama S, Ito Y, Ueno-Kudoh H, Shimizu H, Uchibe K, Albini S, Mitsuoka K, Miyaki S, Kiso M, Nagai A, Hikata T, Osada T, Fukuda N, Yamashita S, Harada D, Mezzano V, Kasai M, Puri PL, Hayashizaki Y, Okado H, Hashimoto M, Asahara H, A systems approach reveals that the myogenesis genome network is regulated by the transcriptional repressor RP58. Dev Cell. 2009 Dec;17(6):836-48