Evidence that haploinsufficiency of Ptch leads to medulloblastoma in mice.

The PTCH gene encodes a putative tumor suppressor protein; germline alterations in PTCH have been found in patients with the nevoid basal cell carcinoma syndrome (NBCCS). Medulloblastoma, a brain tumor, develops in about 3% of NBCCS patients, and mutations in PTCH have also been described in a subset of sporadic medulloblastomas. The search for the causes of medulloblastoma has been hindered by the lack of an appropriate model system for this tumor type. Recently, a transgenic mouse hemizygous for the Ptch gene was generated by homologous recombination. Medulloblastomas were found in about 19% of these mice within the first 25 weeks after birth. The status of the wild-type PTCH allele in these tumors has not been investigated. For clearer definition of the role of PTCH as a tumor suppressor in medulloblastoma, 13 cerebellar tumors from transgenic Ptch(+/-) mice were examined for alterations in the remaining Ptch allele. A single mutation was found in one tumor, a C-to-A substitution changing a tyrosine to a stop codon; all other tumors exhibited a wild-type sequence. Two tumors with normal Ptch cDNA were examined by in situ hybridization. Ptch cDNA was found in tumor cells but not in associated tumor stroma. We also examined the mRNA expression levels for the remaining Ptch allele, as well as for Gli1, a gene known to be transcriptionally activated by Ptch inactivation. Blot analysis of RNA from the 13 tumors shows that Ptch mRNA of appropriate size is expressed in all tumors at varying levels. Expression of Gli1 was increased in tumors compared to normal cerebellum. These results suggest that deletion of one copy of Ptch may be sufficient to promote medulloblastoma development in mice.

Analysis of PTCH/SMO/SHH pathway genes in medulloblastoma.

Inactivation of the PTCH tumor suppressor gene occurs in a subset of sporadic medulloblastomas, suggesting that alterations in the PTCH pathway may be important in the development of this tumor. In order to address the frequency of genetic alterations affecting genes in this pathway, we used a combination of loss of heterozygosity (LOH) analysis, single-stranded conformational polymorphism (SSCP) analysis, and direct sequencing of DNA samples from sporadic primitive neuroectodermal tumors (PNETs). To identify alterations in the PTCH gene, we performed LOH analysis on 37 tumor DNA samples. Of those with matched constitutional DNA samples, one demonstrated LOH. Of those without matched constitutional DNA, six were homozygous with all markers. All exons of the PTCH gene were sequenced in these seven tumors, and three mutations were found. To identify alterations in the SHH and SMO genes, we analyzed all exons of both genes in 24 tumors with SSCP and sequenced any exons that showed aberrant band patterns. No mutations were found in either SHH or SMO in any tumor. We also identified the following genes as candidate tumor suppressors based on their roles in controlling hh/ptc signaling in Drosophila: EN-1 and EN-2, deletion of which results in a lack of cerebellar development in mice; SMAD family members 1-7, and protein kinase A subunits RIalpha, RIbeta, RIIbeta, Calpha, and Cbeta. Each of these genes was investigated in a panel of 24 matched constitutional and tumor DNA samples. Our search revealed no mutations in any of these genes. Thus, PTCH is the only gene in this complex pathway that is mutated with notable frequency in PNET. Genes Chromosomes Cancer 27:44-51, 2000.

Neurotrophins and Trk receptors in primitive neuroectodermal tumor cell lines.

OBJECTIVE: Primitive neuroectodermal tumors (PNETs) are thought to be derived from early central nervous system precursors. Therefore, we hypothesized that the neurotrophins (nerve growth factor, brain-derived neurotrophic factor, and neurotrophin-3) and their receptors (TrkA, TrkB, and TrkC), which are involved in the proliferation, differentiation, and survival of neuronal cells, might be important in regulating tumor growth. METHODS: Using ribonucleic acid (RNA) blotting and reverse transcription-polymerase chain reaction analysis, we investigated the expression of these ligands and their receptors in six PNET cell lines (Daoy, PFSK, D283 Med, UW288-1, CHP707m, and D341 Med). Neurotrophin protein levels were measured using enzyme-linked immunosorbent assay procedures. Receptor function was demonstrated by autophosphorylation. Induction of c-Fos expression and effects on cell proliferation were assessed after the addition of exogenous neurotrophin. RESULTS: Three cell lines expressed messenger RNA for all neurotrophins, whereas the other three expressed two of the three neurotrophins. Neurotrophin protein levels were low. All cell lines expressed trkA messenger RNA. Five expressed the amino terminus of trkB, but three of these did not express the carboxyl terminus. All cell lines contained trkC messenger RNA, but the receptor was truncated in two cell lines. No cell line contained message for a receptor containing an insertion in the tyrosine kinase domain. The addition of neurotrophin to PNET cells resulted in phosphorylation of a protein that was immunoprecipitated with an anti-pan-Trk antibody. c-Fos expression and cell growth were increased by preincubation with neurotrophins, but only in the cell lines expressing the relevant full-length receptors. CONCLUSION: The expression of neurotrophins and neurotrophin receptors by PNET cell lines is variable. The presence of activated Trk receptors in these cell lines may be required for rapid growth, via an autocrine loop mechanism. This will require further investigation.

Sporadic medulloblastomas contain oncogenic beta-catenin mutations.

The beta-catenin, glycogen synthase kinase 3beta (GSK-3beta), and adenomatous polyposis coli (APC) gene products interact to form a network that influences the rate of cell proliferation. Medulloblastoma occurs as part of Turcot's syndrome, and patients with Turcot's who develop medulloblastomas have been shown to harbor germ-line APC mutations. Although APC mutations have been investigated and not identified in sporadic medulloblastomas, the status of the beta-catenin and GSK-3beta genes has not been evaluated in this tumor. Here we show that 3 of 67 medulloblastomas harbor beta-catenin mutations, each of which converts a GSK-3beta phosphorylation site from serine to cysteine. The beta-catenin mutation seen in the tumors was not present in matched constitutional DNA in the two cases where matched DNA was available. A loss of heterozygosity analysis of 32 medulloblastomas with paired normal DNA samples was performed with four microsatellite markers flanking the GSK-3beta locus; loss of heterozygosity with at least one marker was identified in 7 tumors. Sequencing of the remaining GSK-3beta allele in these cases failed to identify any mutations. Taken together, these data suggest that activating mutations in the beta-catenin gene may be involved in the development of a subset of medulloblastomas. The GSK-3beta gene does not appear to be a target for inactivation in this tumor.

Ciliary neurotrophic factor expression in Schwann cells is induced by axonal contact.

In the PNS, ciliary neurotrophic factor (CNTF) is found in significant amounts in the adult sciatic nerve, localized to myelin-related Schwann cells (SCs). Levels are undetectable in newborn but high in adult animals. After crush injury, CNTF production is reduced, recovering only as the nerve regenerates; if regeneration does not occur, CNTF levels remain low. We have examined the coupling of CNTF expression to myelination in vitro and in vivo to determine if axon-SC contact without myelination is sufficient to induce CNTF expression. Embryonic day 15 (E15) rat dorsal root ganglion (DRG) neuron and SCs were cocultured. CNTF was not detected in the DRGs either at E15 or after 2 days in vitro (div) by western blotting. However, after 10 div, CNTF could be identified and remained at constant levels up to 30 div. Depriving the cultures of ascorbic acid prevents myelination but not axon-SC contact. This did not affect CNTF protein production. Using reverse transcriptase-linked PCR (RT-PCR) techniques, no CNTF message was present in DRG from day 14 or 15 fetal rats; but by 6 days in culture, message was detected in both myelinating and nonmyelinating cultures. Isolated SC cultures, without axonal contact, failed to express CNTF protein; however, mRNA was detected by RT-PCR. Embryonic SC can be induced to synthesize CNTF in culture by axonal contact. Active myelination is not required.