The gene coding β-catenin is located on the chromosome 3 in the region p22-p21. β-catenin is a multifunctional protein which is involved in Ca2+-dependent intercellular adhesion, regulation of gene expression through its influence in Wnt/Wingless signaling pathway and some other cell processes.

β-catenin in adhesive joints interact with a cytoplasmatic part of transmembrane cadherins on the one side and with α-cateninem, which binds acting filaments, on the other side. This is the way to ensure the stability of these joints (Fig. 1). The loss or disrupting of β-catenin then cause a violation of normal adhesive cell adhesion.

The second essential function of β-catenin, except for intercellular interactions, is its influence as a transcriptional cofactor in the Wnt/Wingless signaling pathway. This system is, in the case of growth factor Wnt absence, negatively regulated using a protein complex APC-Axin-GSK3β (Adenomatous polyposis coli-Axin-Glykogen synthase kinase 3β), which phosphorylates β-catenin at serine and threonine on the N terminal end and thus it allows its Ubiquitin-mediated degradation. When the Wnt signal is present, GSK3β is inhibited, there is no β-catenin degradation and it interacts with the transcription factors from Tcf/Lef family. It activates, inter alia, the genes participating on cell proliferation, such as Cyclin D1 etc. (Fig. 1). A similar situation occurs also when any of the proteins involved in the regulation of Wnt/Wingless signaling pathway is damaged, in particular the APC and the gene for β-catenin, that are mutated in a wide range of tumor diseases.

The β-catenin gene was analyzed in our study for the presence of the mutations in exon 3 which contains the sites for a phosphorylation of GSK3β. A patient was investigated with a rare pigmented solid and pseudopapillary pancreatic tumor.


In our laboratory we perform the examination of exon 3 of the gene CTNNB1 using direct sequencing.

  • Slideshow Format

    Schematic representation of the role of β-catenin in the cell adhesion and signal transfer.

  • Slideshow Format

    Mutation of the CTNNB1 gene. The point mutation G->A in exon 3 leading to an amino acid substitution S23N.

Analytical sensitivity and specificity of the sequencing: 99%.


In the case of the analysis of somatic mutations by sequencing the mutations will not be detected, if the altered cell line is not represented by at least 20%.


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