Gene Expression Literature Summary

• Symbol: Tgfb1i1
• Name: transforming growth factor beta 1 induced transcript 1
• ID: MGI:102784

21 matching records from 21 references.

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

Age	E8.5	E9.5	E10.5	E11.5	E12.5	E13.5	E14.5	E15.5	E16	E16.5	E17.5	E18.5	P
Immunohistochemistry (section)						1		1			1		1
In situ RNA (section)	1		1		2	1	4	3	1	1		1	2
In situ RNA (whole mount)	1	3	4	1		2	1	1
Western blot			1			2		2				1	1
RT-PCR			1		2	3		2			1		1
cDNA clones		1											1

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

Tgfb1i1  transforming growth factor beta 1 induced transcript 1   (Synonyms: ARA55, hic-5, TSC-5)
Results	Reference
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
7*	J:70363 Brunskill EW, Witte DP, Yutzey KE, Potter SS, Novel cell lines promote the discovery of genes involved in early heart development. Dev Biol. 2001 Jul 15;235(2):507-20
2*	J:168654 Chung YC, Tsai YJ, Shiu TY, Sun YY, Wang PF, Chen CL, Screening large numbers of expression patterns of transcription factors in late stages of the mouse thymus. Gene Expr Patterns. 2011 Jan-Feb;11(1-2):84-92
1	J:161416 Collette NM, Genetos DC, Murugesh D, Harland RM, Loots GG, Genetic evidence that SOST inhibits WNT signaling in the limb. Dev Biol. 2010 Jun 15;342(2):169-79
1*	J:148410 Combes AN, Lesieur E, Harley VR, Sinclair AH, Little MH, Wilhelm D, Koopman P, Three-dimensional visualization of testis cord morphogenesis, a novel tubulogenic mechanism in development. Dev Dyn. 2009 May;238(5):1033-41
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
10	J:95883 Drori S, Girnun GD, Tou L, Szwaya JD, Mueller E, Kia X, Shivdasani RA, Spiegelman BM, Hic-5 regulates an epithelial program mediated by PPARgamma. Genes Dev. 2005 Feb 1;19(3):362-75
1	J:296650 England AR, Chaney CP, Das A, Patel M, Malewska A, Armendariz D, Hon GC, Strand DW, Drake KA, Carroll TJ, Identification and characterization of cellular heterogeneity within the developing renal interstitium. Development. 2020 Aug 14;147(15):dev190108
3*	J:91257 Gray PA, Fu H, Luo P, Zhao Q, Yu J, Ferrari A, Tenzen T, Yuk DI, Tsung EF, Cai Z, Alberta JA, Cheng LP, Liu Y, Stenman JM, Valerius MT, Billings N, Kim HA, Greenberg ME, McMahon AP, Rowitch DH, Stiles CD, Ma Q, Mouse Brain Organization Revealed Through Direct Genome-Scale TF Expression Analysis. Science. 2004 Dec 24;306(5705):2255-2257
4*	J:171409 GUDMAP Consortium, GUDMAP: the GenitoUrinary Development Molecular Anatomy Project. www.gudmap.org. 2004;
1*	J:231595 Gurdziel K, Vogt KR, Walton KD, Schneider GK, Gumucio DL, Transcriptome of the inner circular smooth muscle of the developing mouse intestine: Evidence for regulation of visceral smooth muscle genes by the hedgehog target gene, cJun. Dev Dyn. 2016 May;245(5):614-26
2	J:88217 Hedlund E, Karsten SL, Kudo L, Geschwind DH, Carpenter EM, Identification of a Hoxd10-regulated transcriptional network and combinatorial interactions with Hoxa10 during spinal cord development. J Neurosci Res. 2004 Feb 1;75(3):307-19
1	J:184521 Koss M, Bolze A, Brendolan A, Saggese M, Capellini TD, Bojilova E, Boisson B, Prall OW, Elliott DA, Solloway M, Lenti E, Hidaka C, Chang CP, Mahlaoui N, Harvey RP, Casanova JL, Selleri L, Congenital Asplenia in Mice and Humans with Mutations in a Pbx/Nkx2-5/p15 Module. Dev Cell. 2012 May 15;22(5):913-26
2	J:65651 Neidhardt L, Gasca S, Wertz K, Obermayr F, Worpenberg S, Lehrach H, Herrmann BG, Large-scale screen for genes controlling mammalian embryogenesis, using high-throughput gene expression analysis in mouse embryos. Mech Dev. 2000 Nov;98(1-2):77-94
1	J:321574 Niu Z, Iyer D, Conway SJ, Martin JF, Ivey K, Srivastava D, Nordheim A, Schwartz RJ, Serum response factor orchestrates nascent sarcomerogenesis and silences the biomineralization gene program in the heart. Proc Natl Acad Sci U S A. 2008 Nov 18;105(46):17824-9
1	J:134483 Rajagopal J, Carroll TJ, Guseh JS, Bores SA, Blank LJ, Anderson WJ, Yu J, Zhou Q, McMahon AP, Melton DA, Wnt7b stimulates embryonic lung growth by coordinately increasing the replication of epithelium and mesenchyme. Development. 2008 May;135(9):1625-34
6*	J:245204 Rashid M, Belmont J, Carpenter D, Turner CE, Olson EC, Neural-specific deletion of the focal adhesion adaptor protein paxillin slows migration speed and delays cortical layer formation. Development. 2017 Nov 01;144(21):4002-4014
1	J:171050 Thiagarajan RD, Georgas KM, Rumballe BA, Lesieur E, Chiu HS, Taylor D, Tang DT, Grimmond SM, Little MH, Identification of anchor genes during kidney development defines ontological relationships, molecular subcompartments and regulatory pathways. PLoS One. 2011;6(2):e17286
2	J:221298 Wang Y, Hu G, Liu F, Wang X, Wu M, Schwarz JJ, Zhou J, Deletion of yes-associated protein (YAP) specifically in cardiac and vascular smooth muscle cells reveals a crucial role for YAP in mouse cardiovascular development. Circ Res. 2014 Mar 14;114(6):957-65
2	J:285929 Wen T, Liu J, He X, Dong K, Hu G, Yu L, Yin Q, Osman I, Peng J, Zheng Z, Xin H, Fulton D, Du Q, Zhang W, Zhou J, Transcription factor TEAD1 is essential for vascular development by promoting vascular smooth muscle differentiation. Cell Death Differ. 2019 Dec;26(12):2790-2806
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