Dysregulated stemness-related genes in gynecological malignancies

In recent years, much attention has been paid to the concept of cancer stem cells (CSC) and self-renewal related pathways in cancer biology. This review outlines the dysregulated stemness-related genes or transcription factors in gynecological cancers. Hedgehog (Hh) and Notch signaling are important pathways in tissue pattern programming and cell fate determination during embryonic development. Hyperactivation of these two pathways was frequently observed in gynecological malignancies such as ovarian, endometrial and cervical cancers. In contrast, the expression profiles of pluripotency-regulating core transcriptional circuitry: Nanog, Oct4 and Sox2 appear heterogeneous. Among these transcription factors, overexpression of Nanog was found to exert a prominent effect in gynecological tumorigenesis, while dysregulations of Oct4 and Sox2 may vary in a context dependent manner. On the other hand, the isolation of putative CSC illustrates a hierarchy model of tumor heterogeneity, in which only a subset of cells among biologically distinct populations can initiate tumor growth. Re-activation of these pluripotent transcription factors (Nanog, Oct4 and/or Sox2) in association with distinct tumorigenic properties could be found in clones isolated from gynecological tumors using various approaches. Recent understanding on the roles of Hh and Notch signaling in enhancing CSC survival may help to better understand the mechanism of carcinogenesis and identify new pharmaceutical targets for gynecological malignancie

Functional selection in SH3-mediated activation of the PI3 kinase

BioRxiv preprintABSTRACT The phosphoinositide-3 kinase (PI3K), a heterodimeric enzyme, plays a pivotal role in cellular metabolism and survival. Its deregulation is associated with major human diseases, particularly cancer. The p85 regulatory subunit of PI3K binds to the catalytic p110 subunit via its C-terminal domains, stabilising it in an inhibited state. Certain Src homology 3 (SH3) domains can activate p110 by binding to the proline-rich (PR) 1 motif located at the N-terminus of p85. However, the mechanism by which this N-terminal interaction activates the C-terminally bound p110 remains elusive. Moreover, the intrinsically poor ligand selectivity of SH3 domains raises the question of how they can control PI3K. Combining structural, biophysical, and functional methods, we demonstrate that the answers to both these unknown issues are linked: PI3K-activating SH3 domains engage in additional “tertiary” interactions with the C-terminal domains of p85, thereby relieving their inhibition of p110. SH3 domains lacking these tertiary interactions may still bind to p85 but cannot activate PI3K. Thus, p85 uses a functional selection mechanism that precludes nonspecific activation rather than nonspecific binding. This separation of binding and activation may provide a general mechanism for how biological activities can be controlled by promiscuous protein-protein interaction domains