HIC1 attenuates Wnt signaling by recruitment of TCF-4 and β-catenin to the nuclear bodies

Abstract: The hypermethylated in cancer 1 (HIC1) gene is epigenetically inactivated in cancer, and in addition, the haploinsufficiency of HIC1 is linked to the development of human Miller-Dieker syndrome. HIC1 encodes a zinc-finger transcription factor that acts as a transcriptional repressor. Additionally, the HIC1 protein oligomerizes via the N-terminal BTB/POZ domain and forms discrete nuclear structures known as HIC1 bodies. Here, we provide evidence that HIC1 antagonizes the TCF/b-catenin-mediated transcription in … Show more

“…HIC1 has been shown to interact with and inhibit DNA binding of transcription factors such as T-cell factor-4, b-catenin, and STAT3. [38][39][40] As HIC1-deficient T H 17 cells produce heightened levels of the STAT3 target gene IL-17A, 41 we hypothesized that increased STAT3 activity was associated with HIC1 deficiency. We first examined the levels of IL-6-induced active phosphorylated STAT3 in HIC1-sufficient and -deficient T H 17 cells by flow cytometry.…”

The transcriptional repressor HIC1 regulates intestinal immune homeostasis

“…HIC1 has been shown to interact with and inhibit DNA binding of transcription factors such as T-cell factor-4, b-catenin, and STAT3. [38][39][40] As HIC1-deficient T H 17 cells produce heightened levels of the STAT3 target gene IL-17A, 41 we hypothesized that increased STAT3 activity was associated with HIC1 deficiency. We first examined the levels of IL-6-induced active phosphorylated STAT3 in HIC1-sufficient and -deficient T H 17 cells by flow cytometry.…”

The transcriptional repressor HIC1 regulates intestinal immune homeostasis

“…HIC1 (in an unusual convergence of nomenclature, three proteins discussed in this review, HIC1, HIC5 and HIC, are three completely different proteins; a BTB/POZ protein, LIM domain protein and I-mfa protein, respectively) is the Kaisorelated BTB/POZ family member that binds directly to CtBP (mentioned above in LEF/TCF co-repressors). But instead of acting as a Kaiso-like repressor, HIC1 apparently antagonizes TCF-4 through sequestration to novel dot structures in the nucleus (Deltour et al, 2002;van Roy and McCrea, 2005;Valenta et al, 2006). CtBP is important for this effect as a mutant HIC1 missing its CtBP-binding motif cannot redirect TCF-4 to nuclear dots despite an intact HIC1/TCF-4 interaction (Valenta et al, 2006).…”

“…Also, deletion of these motifs or mutation by amino-acid substitution has consequences. For example, loss of the two motifs from the E-tail of a xLEF/xTCF-3 chimera relieves repressive activity in Siamois reporter assays in Xenopus (albeit, not in the context of full-length xTCF-3), and loss of the two motifs from the E-tail of TCF-4 disrupts its colocalization in nuclear dots with the BTB/POZ antagonist HIC1 (see below in LEF/TCF antagonists) and CtBP (Valenta et al, 2006). Interestingly, HIC1 and CtBP directly interact in vitro and in vivo and HIC1 and TCF-4 also interact directly (Deltour et al, 2002;Stankovic-Valentin et al, 2006).…”

“…Phosphorylation is another modification with negative consequences. Casein kinase 1 phosphorylation of LEF-1 on a serine in the b-catenin-binding domain (Behrens et al, 1996;Brunner et al, 1997;Daniels & Weis, 2005;Graham et al, 2000;Huber et al, 1996;Molenaar et al, 1996;van de Wetering et al, 1997) -catenin (Kolligs et al, 2000;Miravet et al, 2002) YCTTTGWW~1 0 -9 M; (Giese et al, 1991;Love et al, 1995;van Beest et al, 2000;van de Wetering et al, 1997;Waterman et al, 1991) Double-strand DNA Atcha et al, 2006, submitted Importin alpha (Prieve et al, 1996;Prieve et al, 1998) SMADs (Nishita et al, 2000) Cdx1 (Beland et al, 2004) Alx4 (Boras & Hamel, 2002) Pitx2 (Vadlamudi et al, 2005) Ets (Carlsson et al, 1993;Giese et al, 1995;Sheridan et al, 1995) MITF LEF-1 only; Aly LEF-1; (Bruhn et al, 1997) p300 (Hecht & Stemmler, 2003) Groucho/TLE (Brantjes et al, 2001;Daniels & Weis, 2005;Levanon et al, 1998;Roose et al, 1998) CtBP PLSLSxK, PLSLVTK (TCF3, TCF4) (Brannon et al, 1999;Valenta et al, 2003) Kaiso (Park et al, 2005) Runx2 (Kahler & Westendorf, 2003) HIC5 (Ghogomu et al, 2006) HIC1 (Deltour et al, 2002;Valenta et al, 2006) I-mfa, HIC …”

“…But instead of acting as a Kaiso-like repressor, HIC1 apparently antagonizes TCF-4 through sequestration to novel dot structures in the nucleus (Deltour et al, 2002;van Roy and McCrea, 2005;Valenta et al, 2006). CtBP is important for this effect as a mutant HIC1 missing its CtBP-binding motif cannot redirect TCF-4 to nuclear dots despite an intact HIC1/TCF-4 interaction (Valenta et al, 2006). Likewise, the CtBP-binding motifs in the TCF-4 E tail are important for co-localization with HIC1 even though a direct interaction between CtBP and wild-type TCF-4 cannot be detected.…”

Diversity of LEF/TCF action in development and disease

Evolutionary Diversification of Vertebrate TCF/LEF Structure, Function, and Regulation