Innovative Microscopy Unveils Role of Hippo Pathway Proteins in Cancer Regulation
Recent advancements in microscopy have shed light on the molecular mechanisms of the Hippo pathway, enhancing understanding of its role in regulating gene activity, particularly in cancer cells. This breakthrough, achieved by researchers in Melbourne, opens new avenues for potential treatments for challenging cancers such as mesothelioma.
The research team successfully captured, for the first time, real-time imaging of a group of proteins known as TEADs and YAP that are pivotal in the functioning of the Hippo pathway. This pathway, believed to have evolved over a billion years ago, plays a crucial role in various biological processes, including tissue growth, wound healing, and cell proliferation. Its dysfunction is linked to the development and progression of several cancers.
At present, two novel drugs targeting the Hippo pathway are undergoing initial human trials at Peter MacCallum Cancer Centre, aiming to evaluate their effectiveness in treating mesothelioma, a cancer primarily associated with asbestos exposure.
According to the researchers, the Hippo pathway is integral to the transcription process, which translates genetic information from DNA into functional proteins. However, the specifics of how this regulation occurs have remained elusive. By employing cutting-edge microscopy techniques, the team recorded the dynamics of these proteins interacting with DNA in human cells.
Key findings reveal that the Hippo pathway influences gene expression by modulating the duration of TEAD and YAP binding to DNA. Notably, TEAD1, a member of the TEAD protein family, has been implicated in the advancement of mesothelioma, prompting investigations into drugs designed to inhibit TEADs for therapeutic benefits.
Additionally, the study highlighted the behavior of a mutated form of YAP, known as YAP-TFE3, which is associated with another rare cancer called epithelioid hemangioendothelioma. This variant was found to bind to DNA over longer periods compared to its standard counterparts, suggesting distinct regulatory mechanisms that could be targeted for treatment.
The research, led by Dr. Benjamin Kroeger and Professor Kieran Harvey at Monash University and Peter Mac, signifies a crucial step forward in cancer biology. Their findings, published in the journal Science Advances, underscore the importance of the Hippo pathway in cancer treatment strategies.
Overall, this study not only elucidates the operational intricacies of the Hippo pathway but also holds promise for developing innovative therapies that could improve outcomes for patients with mesothelioma and other hard-to-treat cancers.