Identification and characterization of two novel PTCH1 splice variants

Patched-1 (PTCH1), one of the key molecules involved in the Hedgehog (HH) signaling pathway, acts as the receptor of the HH ligand. PTCH1 also inhibits the positive signal transducer Smoothened (SMO). Several PTCH1 splice variants have been identified and confirmed to play critical roles in HH pathway regulation. In the present study, two novel alternatively spliced variants of PTCH1 transcripts, designated PTCH1-Delta 10 and PTCH1-Delta 15, were found in humans, mice and zebrafish using RT-PCR, direct sequencing and ribonuclease protection assays. PTCH1-Delta 10 lacks exon 10, which encodes part of the sterol-sensing domain (SSD), while PTCH1-Delta 15 lacks 166 bp of exon 15, which causes a frame shift that generates a premature stop codon leading to a truncated PTCH1 protein. Different truncated PTCH1 proteins localized in the cytoplasm were capable of internalizing the N-terminal fragment of Sonic hedgehog (SHH-N), which was visualized using immunofluorescence microscopy. Exon skipping dramatically influenced the steady states of the proteins, with the levels of PTCHI-1B and PTCH1-Delta 10 being significantly higher than those of PTCH1-Delta 15, as detected using western blot. These results imply that the pronounced inhibitory signaling properties of PTCH1-1B and PTCH1-Delta 10 may be partially due to high protein expression in addition to intrinsic functional differences. All isoforms examined worked as functional receptors of SHH. However, the isoforms PTCH1-1B and PTCH1-Delta 10 inhibited SMO and the pathway transcription factor glioma 1 (GLI1) to a greater extent than did PTCH1-Delta 15. In addition, PTCHI-1B and PTCH1-Delta 10 (but not PTCH1-Delta 15) can be negative regulators of the HH pathway. These results indicate that the SSD domain and the C-terminal region are essential for maximal repressor function of PTCH1. Additionally, SMO inhibition by PTCH1 occurred through a non-stoichiometric, catalytic mechanism, indicating that this inhibition was less dependent on the dose of the PTCH1 protein. Finally, all these isoforms have been revealed to inhibit GLI1 activation by either the classical HH signaling pathway or a new pathway not reliant on both SMO and apoptosis. Thus, our study clearly demonstrated the unique involvement of the two novel PTCH1 splice variants in HH signal transduction. (C) 2017 Elsevier Inc. All rights reserved.