The Hippo pathway was initially identified in Drosophila study; deletion of Hippo
pathway caused dramatic over growth of various organs [1]. Then, the Hippo pathway,
identified as tumor suppressors in human, have a key role in regulating organ development,
tumorigenesis, tissue regeneration, and stem cell self- renewal [2]. One of the key
factors of the Hippo pathway is Yes-associated protein 1 (YAP1), transcriptional coactivator
interacting with TEA domain family members (TEAD). When the Hippo pathway is activated,
YAP1 is phosphorylated and degraded in the cytoplasm. Once the Hippo pathway is turned
off, YAP-1 translocates into the nucleus from cytoplasm and binds to TEAD (the transcription
factor), leading to an increase transcription of the target genes [2]. Several factors
have been discovered to regulate the Hippo pathway [2]. For instance, activation of
G protein-coupled receptors activates YAP1 through inhibiting large tumor suppressor
1/2 (LATS1/2), which are kinases to phosphorylate YAP1. Moreover, the Wnt pathway
has been discovered to crosstalk with YAP1. Cell-cell contact or extracellular matrix
(ECM) also are involved in YAP1 activity. The Hippo pathway is activated in high cell
density. On the other hand, some mediators from ECM, such as the integrin pathway,
suppresses the Hippo pathway. Oxidative stress and cell metabolism are also interact
with the Hippo pathway.
YAP1 overexpression and its contribution to cancer initiation and growth were reported
in several cancer types [3]. YAP1 activation induces aggressive malignant behavior,
such as epithelial-to-mesenchymal transition (EMT), proliferation, drug resistance,
tumor-promoting microenvironment, and metastases. The YAP1-TEAD components facilitate
target gene transcription related to the mesenchymal markers, such as vimentin and
N-cadherin. Moreover, YAP1 activation is essential for EMT induced by the TGF-β-SMAD
pathway. Song and colleagues reported that YAP1 promotes epidermal growth factor receptor
(EGFR) expression, conferring chemoresistance in esophageal adenocarcinoma (EAC) cell
line [4]. Several researches also reported that overexpression of YAP1 was associated
with poor patient prognosis and advanced stage in lung, breast, liver, esophageal,
and stomach cancer [3].
Importantly, several studies have demonstrated that YAP1 is correlated with cancer
stem cells (CSCs) like properties [2]. CSCs are considered to contribute EMT, high
metastatic potential, and therapy resistance [5]. CSCs were defined as a subset of
cell population within a tumor that possesses the capacity to self-renew and to give
rise to the heterogeneous lineages of cancer cells that comprise the tumor [6]. For
instance, Song and colleagues found that YAP1 was overexpressed in EAC and regulated
the transcription of SOX9, contributing to increasing CSCs properties [7]. Direct
evidence from our laboratory suggests that YAP1 endows self-renewal capacity to non
tumorgenic cells and tumor cells in EAC. Moreover, currently available treatment modalities
target most mature and proliferating tumor cells and may lead to enrichment of the
highly tumorigenic and drug resistant CSCs. Therefore, attenuation of YAP1 might be
very important to reduce the density of CSCs and to overcome therapy resistance.
There are multiple upstream signals and pathways that may serve as novel therapeutic
targets to inhibit YAP1. Verteporfin or VGLL4, that is commonly used as YAP inhibitor
in research laboratories, binds to the YAP-TEAD complex and inhibits its transcription
ability. Recently, Song and colleagues evaluated the new YAP1 inhibitor, CA3, and
demonstrated that CA3 strongly inhibited YAP- TEAD activity and YAP-1 expression compared
with other YAP1 inhibitors in EAC [8]. Especially, this phenomenon was more effective
against radiation-resistant EAC cells that possess CSCs property. This result suggests
that inhibiting YAP1 could be an effective therapy against CSCs, and thus have potential
to overcome therapy resistance. However, agents against the Hippo pathway are under
development.
We acknowledge that the Hippo pathway or function of YAP1 have not been completely
understood at present and more research is warranted. First, the mechanism by which
YAP1 controls expression level of the target genes remains unclear. Many factors and
pathways are involved in the control of YAP1 activity, and thus unknown activator
are yet to be uncovered. It is also unclear that when the Hippo pathway is turned
off and YAP is activated, during carcinogenesis. Secondly, YAP1 activation in normal
tissue has the key role in cell trans- differentiation, but in cancer tissue, there
may be different signals for YAP1 activation to induce CSCs features.
In summary, the Hippo pathway has a key role in CSC capabilities, EMT, therapy resistance,
and metastatic potential. Identification of unique markers of CSCs is important for
diagnosis, treatment, and monitoring various cancers. YAP1 is a potential biomarker
of CSC and a therapeutic target. Yap1 should be a major focus of cancer research.