Ligand-dependent Hedgehog pathway activation in Rhabdomyosarcoma: the oncogenic role of the ligands.

BACKGROUND: Rhabdomyosarcoma (RMS) is the most common type of soft tissue sarcoma in children. The Hedgehog (HH) pathway is known to develop an oncogenic role in RMS. However, the molecular mechanism that drives activation of the pathway in RMS is not well understood. METHODS: The expression of HH ligands was studied by qPCR, western blot and immunohistochemistry. Functional and animal model studies were carried out with cells transduced with shRNAs against HH ligands or treated with HH-specific inhibitors (Vismodegib and MEDI-5304). Finally, the molecular characterisation of an off-target effect of Vismodegib was also made. RESULTS: The results showed a prominent expression of HH ligands supporting an autocrine ligand-dependent activation of the pathway. A comparison of pharmacologic Smoothened inhibition (Vismodegib) and HH ligand blocking (MEDI-5304) is also provided. Interestingly, a first description of pernicious off-target effect of Vismodegib is also reported. CONCLUSIONS: The clarification of the HH pathway activation mechanism in RMS opens a door for targeted therapies against HH ligands as a possible alternative in the future development of better treatment protocols. Moreover, the description of a pernicious off-target effect of Vismodegib, via unfolded protein response activation, may mechanistically explain its previously reported inefficiency in several ligand-dependent cancers.

[Adoptive T-cell therapy of rhabdomyosarcoma]. / Adoptive T-Zell-Therapie des Rhabdomyosarkoms.

AIMS: To improve survival of patients with advanced rhabdomyosarcomas (RMS), we aimed to adoptively transfer T-cells with redirected specificity for the fetal acetylcholine receptor (AChR), an RMS-specific cell surface antigen. METHODS: A "second generation" chimeric antigen receptor (CAR) with a combined CD28-CD3ζ signaling domain was derived from our previously described chimeric antigen receptor composed of an extracellular human anti-fAChR antibody fragment, an Fc hinge region, and the intracellular T-cell receptor zeta chain. Lymphocytes from the peripheral blood were modified by retroviral transduction and monitored by FACS analysis. Cytotoxicity of modified T-cells towards RMS cells was recorded by MTT-based viability tests; expression of co-stimulatory molecules and anti-apoptotic genes was studied by FACS and qRT-PCR analysis. RESULTS: Co-stimulatory molecules were expressed in low levels on RMS cells giving the rationale to generate a CD28-CD3ζ signalling CAR (chimeric antigen receptor) for redirecting T-cells. T-cells were successfully engineered with the "second generation" AChR-specific chimeric antigen receptor. Despite of high CAR expression engineered T-cells showed low killing efficiency towards RMS compared to redirected killing of CD20+ lymphoma or CEA-expressing adenocarcinoma cell lines when redirected by CD20- and/or CEA-specific CAR. CONCLUSIONS: Data suggest that RMS cells exhibit resistance to a T-cell attack redirected by a fAChR-specific CAR. Inhibition of anti-apoptotic pathways in those cells may improve sensitivity to conventional as well as T-cell-based therapeutics.