Abstract
Distinct groups of transcription factors (TFs) assemble at tissue-specific cis-regulatory sites, implying that different TF combinations may control different genes and cellular functions. Within such combinations, TFs that specify or maintain a lineage and are therefore considered master regulators may play a key role. Gene enhancers often attract these tissue-restricted TFs, as well as TFs that are expressed more broadly. However, the contributions of the individual TFs to combinatorial regulatory activity have not been examined critically in many cases in vivo. We address this question using a genetic approach in mice to inactivate the intestine-specifying and intestine-restricted factor CDX2 alone or in combination with its more broadly expressed partner factors, GATA4 and HNF4A. Compared with single mutants, each combination produced significantly greater defects and rapid lethality through distinct anomalies. Intestines lacking Gata4 and Cdx2 were deficient in crypt cell replication, whereas combined loss of Hnf4a and Cdx2 specifically impaired viability and maturation of villus enterocytes. Integrated analysis of TF binding and of transcripts affected in Hnf4a;Cdx2 compound-mutant intestines indicated that this TF pair controls genes required to construct the apical brush border and absorb nutrients, including dietary lipids. This study thus defines combinatorial TF activities, their specific requirements during tissue homeostasis, and modules of transcriptional targets in intestinal epithelial cells in vivo.
Highlights
Different transcription factor combinations may control distinct or overlapping cellular functions
The contributions of the individual transcription factors (TFs) to combinatorial regulatory activity have not been examined critically in many cases in vivo. We address this question using a genetic approach in mice to inactivate the intestine-specifying and intestine-restricted factor CDX2 alone or in combination with its more broadly expressed partner factors, GATA4 and HNF4A
Intestines lacking Gata4 and Cdx2 were deficient in crypt cell replication, whereas combined loss of Hnf4a and Cdx2 impaired viability and maturation of villus enterocytes
Summary
Different transcription factor combinations may control distinct or overlapping cellular functions. Coupled with the frequent co-occurrence of their specific sequence motifs near CDX2-binding sites, the limited defects in Gata and Hnf4a mutant mice led us to postulate that they may regulate intestinal genes in combination with CDX2 These TFs might act in several different ways: (i) support CDX2 activity at CDX2-dependent genes, (ii) partner with CDX2 in distinct combinations to regulate different cellular functions, or (iii) serve additional, CDX2-independent functions. To evaluate these possibilities, we generated inducible compound-mutant mice that lack Cdx and either Gata4/6 or Hnf4a in the adult intestine. The lineage-restricted factor CDX2 functions in obligate partnerships with different broadly expressed factors to regulate distinct aspects of intestinal epithelial structure and function
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