Disease-associated casein kinase I delta mutation may promote adenomatous polyps formation via a Wnt/beta-catenin independent mechanism.

The Wnt signaling pathway is critical for embryonic development and is dysregulated in multiple cancers. Two closely related isoforms of casein kinase I (CKIdelta and epsilon) are positive regulators of this pathway. We speculated that mutations in the autoinhibitory domain of CKIdelta/epsilon might upregulate CKIdelta/epsilon activity and hence Wnt signaling and increase the risk of adenomatous polyps and colon cancer. Exons encoding the CKIepsilon and CKIdelta regulatory domains were sequenced from DNA obtained from individuals with adenomatous polyps and a family history of colon cancer unaffected by familial adenomatous polyposis or hereditary nonpolyposis colorectal cancer (HNPCC). A CKIdelta missense mutation, changing a highly conserved residue, Arg324, to His (R324H), was found in an individual with large and multiple polyps diagnosed at a relatively young age. Two findings indicate that this mutation is biologically active. First, ectopic ventral expression of CKIdelta(R324H) in Xenopus embryos results in secondary axis formation with an additional distinctive phenotype (altered morphological movements) similar to that seen with unregulated CKIepsilon. Second, CKIdelta(R324H) is more potent than wildtype CKIdelta in transformation of RKO colon cancer cells. Although the R324H mutation does not significantly change CKIdelta kinase activity in an in vitro kinase assay or Wnt/beta-catenin signal transduction as assessed by a beta-catenin reporter assay, it alters morphogenetic movements via a beta-catenin-independent mechanism in early Xenopus development. This novel human CKIdelta mutation may alter the physiological role and enhance the transforming ability of CKIdelta through a Wnt/beta-catenin independent mechanism and thereby influence colonic adenoma development.

Nodal signaling: CrypticLefty mechanism of antagonism decoded.

The secreted TGFbeta factor Lefty antagonizes Nodal signaling during vertebrate embryogenesis, but how it does so has been a mystery. Recent analyses have elucidated the molecular mechanisms underlying this function of Lefty.

Lefty-dependent inhibition of Nodal- and Wnt-responsive organizer gene expression is essential for normal gastrulation.

During gastrulation, diffusible "organizer" signals, including members of the TGFbeta Nodal subfamily, pattern dorsal mesoderm and the embryonic axes. Simultaneously, negative regulators of these signals, including the Nodal inhibitor Lefty, an atypical TGFbeta factor, are induced by Nodal. This suggests that Lefty-dependent modulation of organizer signaling might regulate dorsal mesoderm patterning and axial morphogenesis. Here, Xenopus Lefty (Xlefty) function was blocked by injection of anti-Xlefty morpholino oligonucleotides (MO). Xlefty-deficient embryos underwent exogastrulation, an aberrant morphogenetic process not predicted from deregulation of the Nodal pathway alone. In the absence of Xlefty, both Nodal- (Xnr2, gsc, cer, Xbra) and Wnt-responsive (gsc, Xnr3) organizer gene expression expanded away from the dorsal blastopore lip. Conversely, coexpression of Xlefty with Nodal or Wnt reduced the ectopic expression of Nodal- (Xbra) and Wnt-responsive (Xnr3) genes in a dose-dependent manner. Furthermore, Xlefty expression in the ectodermal animal pole inhibited endogenous Nodal- and Wnt-responsive gene expression in distant mesoderm cells, indicating that Xlefty inhibition can spread from its source. We hypothesize that Xlefty negatively regulates the spatial extent of Nodal- and Wnt-responsive gene expression in the organizer and that this Xlefty-dependent inhibition is essential for normal organizer patterning and gastrulation.