A major susceptibility locus to murine lung carcinogenesis maps on chromosome 6.

Lung tumours represent a major cause of death in humans, and although smoking represents the main pathogenetic factor, inheritance also plays a part. However, the identification of possible predisposing genetic factors is difficult, because of their low penetrance. We took advantage of murine strains that are genetically susceptible or resistant to lung tumour development, to map murine genes associated with susceptibility to lung carcinogenesis. An F2 population of urethan-treated A/J x C3H/He mice was scored with 83 genetic markers. A chromosome 6 distal region, spanning mice was scored with 83 genetic markers. A chromosome 6 distal region, spanning 35 centiMorgans, contained a major lung tumour susceptibility locus. No other chromosomal region was significantly associated with lung tumour development.

The full oncogenic activity of Ret/ptc2 depends on tyrosine 539, a docking site for phospholipase Cgamma.

RET/PTC oncogenes, generated by chromosomal rearrangements in papillary thyroid carcinomas, are constitutively activated versions of proto-RET, a gene coding for a receptor-type tyrosine kinase (TK) whose ligand is still unknown. RET/PTCs encode fusion proteins in which proto-RET TK and C-terminal domains are fused to different donor genes. The respective Ret/ptc oncoproteins display constitutive TK activity and tyrosine phosphorylation. We found that Ret/ptcs associate with and phosphorylate the SH2-containing transducer phospholipase Cgamma (PLCgamma). Two putative PLCgamma docking sites, Tyr-505 and Tyr-539, have been identified on Ret/ptc2 by competition experiments using phosphorylated peptides modelled on Ret sequence. Transfection experiments and biochemical analysis using Tyr-->Phe mutants of Ret/ptc2 allowed us to rule out Tyr-505 and to identify Tyr-539 as a functional PLCgamma docking site in vivo. Moreover, kinetic measurements showed that Tyr-539 is able to mediate high-affinity interaction with PLCgamma. Mutation of Tyr-539 resulted in a drastically reduced oncogenic activity of Ret/ptc2 on NIH 3T3 cells (75 to 90% reduction) both in vitro and in vivo, which correlates with impaired ability of Ret/ptc2 to activate PLCgamma. In conclusion, this paper demonstrates that Tyr-539 of Ret/ptc2 (Tyr-761 on the proto-RET product) is an essential docking site for the full transforming potential of the oncogene. In addition, the present data identify PLCgamma as a downstream effector of Ret/ptcs and suggest that this transducing molecule could play a crucial role in neoplastic signalling triggered by Ret/ptc oncoproteins.

Key role of Shc signaling in the transforming pathway triggered by Ret/ptc2 oncoprotein.

The RET/PTC oncogenes, generated by chromosomal rearrangements in papillary thyroid carcinomas, are constitutively activated versions of protoRET, a gene encoding two protein isoforms of a transmembrane tyrosine kinase receptor. By using Ret/ptc2 short isoform (iso9), we have previously demonstrated that Tyr586 (Tyr1062 of protoRet) is the docking site for both the PTB and the SH2 domains of Shc. To determine the relevance of this interaction for the transforming activity of Ret/ptc oncogenes, we have generated and characterized novel Ret/ptc mutants unable to activate Shc: Ret/ptc2 long isoform (iso51)-Y586F and both isoforms of Ret/ptc2-N583A. These mutants neither activate Shc nor transform NIH3T3 cells. Since Tyr1062 shows features of a multifunctional docking site, we have used a Shc mutant (Shc Y317F) to directly assess Shc role. We have demonstrated that in our cell system Shc Y317F behaves like a dominant interfering mutant on the activation of the Grb2-Sos pathway by endogenous Shc triggered by Ret/ptc2. A strong reduction of the transforming activity of Ret/ptc2 in presence of this mutant was also demonstrated. Our data suggest that Shc activation play a key role in the transforming pathways triggered by Ret/ptc oncoproteins. Moreover, we have shown that coexpression of the Shc-Y317F mutant with Ret/ptc2 specifically causes apoptosis, and that the surviving cells lose the long-term expression of one of the two genes.

Loss of heterozygosity in human germinal tumors.

The frequency of losses of heterozygosity has been investigated in 14 germinal tumors of the testis. Nonrandom deletion of whole or part of chromosome 11 was observed in four cases. In addition, loss of heterozygosity of all the informative loci analyzed was detected in one ovarian teratoma, indicating its post-meiotic origin. These results suggest that different genetic mechanisms (chromosomal deletions or meiotic segregation) that unmask putative recessive mutations are involved in the onset of germinal tumors.

Allelotyping in Wilms tumors identifies a putative third tumor suppressor gene on chromosome 11.

An analysis of loss of heterozygosity for markers on both the short and the long arm of chromosome 11 was performed in 24 sporadic Wilms tumors. Six cases (25%) showed allelic losses involving the entire chromosome. In one case (4%) the loss was restricted solely to the WT1 gene on band p13. Two cases (8%) displayed allelic losses for WT1 and for markers on band p15.5, where the putative tumor suppressor gene WT2 has been mapped, but retained heterozygosity for markers on the long arm. In three tumors (13%) the loss of heterozygosity involved markers mapped to chromosomal regions p15.5 and q23.3-qter, but did not affect WT1 and markers on q12-q13. Altogether, the proportion of cases showing allelic losses at the distal region of 11q (37%) was comparable to that of cases with LOH affecting the WT1 (37%) or the WT2 (46%) loci, thus suggesting the existence of a third chromosome 11 tumor suppressor gene involved in the pathogenesis of Wilms tumors.

Screening for mutations of the APC gene in 66 Italian familial adenomatous polyposis patients: evidence for phenotypic differences in cases with and without identified mutation.

Germline mutations in the APC gene are responsible for familial adenomatous polyposis (FAP), a dominantly inherited syndrome characterized by the development of hundreds to thousands of polyps in the colon and in the rectum of affected individuals and by variable extracolonic manifestations (gastric and duodenal polyps, osteomas, retinal lesions, and desmoid tumors). Through the combined use of single-strand conformation polymorphism (SSCP) analysis and the protein truncation test (PTT), we have screened 66 Italian FAP patients and found 29 different APC mutations in a total of 34 cases. Of the identified mutations, 15 were nonsense, 12 were 1- to 5-bp deletions or insertions and two were complex rearrangements, all leading to the formation of premature stop codons. Only 10 mutations had been already previously described at the germline level, confirming the high heterogeneity of the APC mutational spectrum. The mean age of diagnosis in mutation positive cases and their affected relatives was significantly lower than in cases without identified mutation (30.6 vs 39.1 years, respectively; p = 0.003). In addition, among patients without a family history of polyposis, all mutation-positive cases displayed at least one of the extracolonic manifestations usually associated with FAP, whereas in one-half of the cases without identified mutation, none of these phenotypes was observed. Although a fraction of apparently mutation-negative cases were likely to be due to limitations of the mutation screening strategy, our results suggest, in agreement with previous reports, that allelic and/or genetic heterogeneity might be responsible for the phenotypic variability observed in FAP patients.