Src family kinases and HER2 interactions in human breast cancer cell growth and survival.

Evidence from murine fibroblast models and human breast cancer cells indicates that c-Src and human EGF receptor (HER1) synergize to enhance neoplastic growth of mammary epithelial cells. To investigate whether interactions between c-Src and other HER family members may also play a role in breast tumor progression, we characterized 13 human breast carcinoma cell lines and 13 tumor samples for expression of HER family members and c-Src and examined a subset of the cell lines for Src-dependent, heregulin (HRG)-augmented, anchorage-dependent and independent growth. By immunoblotting, we found that all cell lines overexpressed one or more HER family member, and 60% overexpressed c-Src. Seventy-five per cent of the tumor tissues overexpressed HER2, while 64% overexpressed c-Src. Colony formation in soft agar was enhanced by HRG in three of five cell lines tested, a response that correlated with the presence of a c-Src/HER2 heterocomplex. This result suggests that HRG may act through both HER2 and c-Src to facilitate anchorage-independent growth. In contrast, HRG had little effect on anchorage-dependent growth in any of the cell lines tested. PP1, a Src family kinase inhibitor, reduced or ablated HRG-dependent and independent soft agar growth or anchorage dependent growth, and triggered apoptosis in all cell lines tested. The apoptotic effect of PP1 could be partially or completely reversed by HRG, depending on the cell line. These results suggest that while Src family kinases may cooperate with HRG to promote the survival and growth of human breast tumor cells, they also function independently of HER2/HRG in these processes.

Expression of the bHLH gene NSCL-1 suggests a role in regulating cerebellar granule cell growth and differentiation.

We report that the neuronal-specific basic helix-loop-helix (bHLH) gene NSCL-1 is expressed at multiple and distinct stages of cerebellar granule cell differentiation. During embryonic development, NSCI-1 expression is initially evenly distributed in the cerebellar primordium and then becomes restricted to the ventricular zone. At the early steps of granule cell development, NSCL-1 is not expressed in rhombic lip cells, but instead in migrating granule cell precursors. Its expression culminates during postnatal proliferation of the external germinal layer, and remains only transiently in the newly formed internal granular layer, and at a much lower level. Thus, NSCL-1 expression is linked to the onset of granule cell differentiation, but is not involved in the maintenance of the differentiated state. These findings suggest that NSCL-1 does not behave as a specification factor, but rather as a factor promoting expansion of progenitor external germinal layer (EGL) cells. Gel mobility shift assays show that NSCL-1 only binds DNA as a heterodimeric complex with the ME1a E-protein. We also provide the first evidence that NSCL-1 functions as a transcriptional activator when heterodimerized with the ME1a E-protein. Taken together, these results suggest that NSCL-1 participates in the regulatory network controlling gene expression during cerebellar granule cell differentiation.

The GAP-43 gene is a direct downstream target of the basic helix-loop-helix transcription factors.

The GAP-43 promoter region contains seven E-boxes (E1 to E7) that are organized in two clusters, a distal cluster (E3 to E7) and a proximal cluster (E1 and E2). Deletion analysis and site-directed mutagenesis of the GAP-43 promoter region showed that only the most proximal E1 E-box significantly modulates GAP-43 promoter activity. This E-box is conserved between the rat and human GAP-43 promoter sequences in terms of flanking sequence, core sequence (CAGTTG), and position. We found that endogenous E-box-binding proteins present in neuronal N18 cells recognize the E1 E-box and activate the GAP-43 promoter. The transcriptional activity of the GAP-43 promoter was repressed not only by the negative regulator Id2 protein, but also by two class A basic helix-loop-helix proteins, E12 and ME1a. In vitro analyses showed that both ME1a and E12 bind to the E1 E-box as homodimers. By Northern analyses, we established an inverse correlation between the level of E12 and ME1a mRNAs and GAP-43 mRNA in various neuronal cell lines as well as in ME1a-overexpressing PC12 cells. Therefore, we have identified a cis-acting element, the E1 E-box, located in the GAP-43 promoter region that modulates either positively or negatively the expression of the GAP-43 gene depending on which E-box-binding proteins occupy this site. Together, these data indicate that basic helix-loop-helix transcription factors regulate the expression of the GAP-43 gene and that the class A ME1a and E12 proteins act as down-regulators of GAP-43 expression.