Reciprocal Intraepithelial Interactions Between TP63 and Hedgehog Signaling Regulate Quiescence and Activation of Progenitor Elaboration by Mammary Stem Cells

TP63 is required for preservation of epithelial regenerative stasis and regulates the activity of diverse genetic pathways; however, specific effector pathways are poorly understood. Data presented here indicate that reciprocal regulatory interactions between hedgehog signaling and TP63 mediate stage-specific effects on proliferation and clonigenicity of separable enriched mammary stem and progenitor fractions. Analysis of ΔN-p63 and TA-p63 indicates segregated expression in mammary stem and progenitor fractions, respectively, demonstrating that differential TP63 promoter selection occurs during elaboration of mammary progenitors by mammary stem cells. This segregation underlies mammary progenitor-specific expression of Indian Hedgehog , identifying it as a binary transcriptional target of TP63. Hedgehog activation in vivo enhances elaboration of mammary progenitors and decreases label retention within mammary stem cell-enriched fractions, suggesting that hedgehog exerts a mitogenic effect on mammary stem cells. Hedgehog signaling promotes differential TP63 promoter usage via disruption of Gli3 or Gli3 R accumulation, and shRNA-mediated disruption of Gli3 expression was sufficient to alter TP63 promoter usage and enhance clonigenicity of mammary stem cells. Finally, hedgehog signaling is enhanced during pregnancy, where it contributes to expansion of the mammary progenitor compartment. These studies support a model in which hedgehog activates elaboration and differentiation of mammary progenitors via differential TP63 promoter selection and forfeiture of self-renewing capacity

Multiple trans QTL and one cis-regulatory deletion are associated with the differential expression of cone opsins in African cichlids

Abstract Background Dissecting the genetic basis of phenotypic diversity is one of the fundamental goals in evolutionary biology. Despite growing evidence for gene expression divergence being responsible for the evolution of complex traits, knowledge about the proximate genetic causes underlying these traits is still limited. African cichlids have diverse visual systems, with different species expressing different combinations of seven cone opsin genes. Using opsin expression variation in African cichlids as a model for gene expression evolution, this study aims to investigate the genetic architecture of opsin expression divergence in this group. Results Results from a genome-wide linkage mapping on the F2 progeny of an intergeneric cross, between two species with differential opsin expression show that opsins in Lake Malawi cichlids are controlled by multiple quantitative trait loci (QTLs). Most of these QTLs are located in trans to the opsins except for one cis-QTL for SWS1 on LG17. A closer look at this major QTL revealed the presence of a 691 bp deletion in the promoter of the SWS1 opsin (located 751 bp upstream of the start site) that is associated with a decrease in its expression. Phylogenetic footprinting indicates that the region spanning the deletion harbors a microRNA miR-729 and a conserved non-coding element (CNE) that also occurs in zebrafish and other teleosts. This suggests that the deletion might contain ancestrally preserved regulators that have been tuned for SWS1 gene expression in Lake Malawi. While this deletion is not common, it does occur in several other species within the lake. Conclusions Differential expression of cichlid opsins is associated with multiple overlapping QTL, with all but one in trans to the opsins they regulate. The one cis-acting factor is a deletion in the promoter of the SWS1 opsin, suggesting that ancestral polymorphic deletions may contribute to cichlid’s visual diversity. In addition to expanding our understanding of the molecular landscape of opsin expression in African cichlids, this study sheds light on the molecular mechanisms underlying phenotypic variation in natural populations