FGFR2 mutations are associated with poor outcomes in endometrioid endometrial cancer: An NRG Oncology/Gynecologic Oncology Group study.

PURPOSE: Activating FGFR2 mutations have been identified in ~10% of endometrioid endometrial cancers (ECs). We have previously reported that mutations in FGFR2 are associated with shorter disease free survival (DFS) in stage I/II EC patients. Here we sought to validate the prognostic importance of FGFR2 mutations in a large, multi-institutional patient cohort. METHODS: Tumors were collected as part of the GOG 210 clinical trial "Molecular Staging of Endometrial Cancer" where samples underwent rigorous pathological review and had more than three years of detailed clinical follow-up. DNA was extracted and four exons encompassing the FGFR2 mutation hotspots were amplified and sequenced. RESULTS: Mutations were identified in 144 of the 973 endometrioid ECs, of which 125 were classified as known activating mutations and were included in the statistical analyses. Consistent with FGFR2 having an association with more aggressive disease, FGFR2 mutations were more common in patients initially diagnosed with stage III/IV EC (29/170;17%) versus stage I/II EC (96/803; 12%; p=0.07, Chi-square test). Additionally, incidence of progression (progressed, recurred or died from disease) was significantly more prevalent (32/125, 26%) among patients with FGFR2 mutation versus wild type (120/848, 14%; p<0.001, Chi-square test). Using Cox regression analysis adjusting for known prognostic factors, patients with FGFR2 mutation had significantly (p<0.025) shorter progression-free survival (PFS; HR 1.903; 95% CI 1.177-3.076) and endometrial cancer specific survival (ECS; HR 2.013; 95% CI 1.096-3.696). CONCLUSION: In summary, our findings suggest that clinical trials testing the efficacy of FGFR inhibitors in the adjuvant setting to prevent recurrence and death are warranted.

Genotype-phenotype associations in patients with severe hyperinsulinism of infancy.

In hyperinsulinism of infancy (HI), unregulated insulin secretion causes hypoglycemia. Pancreatectomy may be required in severe cases, most of which result from a defect in the beta-cell KATP channel, encoded by ABCC8 and KCNJ11. Pancreatic histology may be classified as diffuse or focal disease (the latter associated with single paternal ABCC8 mutations), indicated by the presence of islet cell nuclear enlargement in areas of diffuse abnormality. We investigated genotype-phenotype associations in a heterogeneous Australian cohort. ABCC8 and KCNJ11 genes were sequenced and case histology was reviewed in 21 infants who had pancreatectomy. Ninety-eight control DNA samples were tested by single nucleotide polymorphism analysis. Eighteen ABCC8 mutations were identified, 10 novel. Eleven patients (4 compound heterozygote, 4 single mutation, 3 no mutation detected) had diffuse hyperinsulinism. Nine patients had focal hyperinsulinism (6 single paternal mutation, 2 single mutation of undetermined parental origin, 1 none found) with absence of islet cell nuclear enlargement outside the focal area, although centroacinar cell proliferation and/or nesidiodysplasia was present in 7 cases. Regeneration after near-total pancreatectomy was documented in 4 patients, with aggregates of endocrine tissue observed at subsequent operations in 3. Although the absence of enlarged islet cell nuclei is a useful discriminant of focal hyperinsulinism associated with a paternal ABCC8 mutation, further research is needed to understand the pathophysiology of other histological abnormalities in patients with HI, which may have implications for mechanisms of ductal and islet cell proliferation. Previous surgery should be taken into account when interpreting pancreatic histology.

Familial hyperaldosteronism type II is linked to the chromosome 7p22 region but also shows predicted heterogeneity.

BACKGROUND: Familial hyperaldosteronism type II (FH-II) is characterized by the familial occurrence of primary aldosteronism; unlike FH-I, it is not glucocorticoid-remediable and not associated with the hybrid CYP11B1/CYP11B2 gene mutation. Linkage to a 5-Mbp region of chromosome 7p22 was previously reported in an Australian family with eight affected members. Mutations in the exons or intron-exon boundaries of PRKAR1B (7p22, closely related to PRKAR1A, which is mutated in Carney complex) have been excluded in this family. OBJECTIVE: To refine the region of linkage, and to seek evidence of linkage in a South American family and in three other Australian families with FH-II, using seven closely spaced markers at 7p22. METHODS: To establish phenotypes (affected, uncertain or unaffected), blood pressure, plasma aldosterone and plasma renin (activity or concentration) were measured and the aldosterone: renin ratio (ARR) calculated. Individuals with consistently increased ARR underwent fludrocortisone suppression testing. The genotypes of the five pedigrees were analysed using seven closely spaced microsatellite markers at 7p22, and two-point and multipoint logarithm of odds (LOD) scores were calculated to assess linkage with FH-II. RESULTS: The combined multipoint LOD score for three families (the original Australian, the South American and a new Australian family) showing linkage at 7p22 was highly significant at 4.61 (theta = 0) for markers D7S462 and D7S517. A newly found recombination event in the first Australian family narrowed the area of linkage by 1.8 Mbp, permitting exclusion of approximately half the candidate genes in the originally reported locus. It was not possible to demonstrate linkage at the 7p22 region in the remaining two Australian families. CONCLUSION: This study provides further evidence for linkage of FH-II to 7p22, refines the locus, and supports the notion that FH-II may be genetically heterogeneous.

Genomic structure of the human gene for protein kinase A regulatory subunit R1-beta (PRKAR1B) on 7p22: no evidence for mutations in familial hyperaldosteronism type II in a large affected kindred.

OBJECTIVE: Familial hyperaldosteronism type II (FH-II) is characterized by inheritance of primary aldosteronism (PAL) but, unlike FH-I, is not glucocorticoid remediable and not associated with the hybrid CYP11B1/CYP11B2 gene mutation. Analysis of two pedigrees previously demonstrated linkage of FH-II with a locus at chromosome 7p22. We sought to determine whether mutations in the exons or intron/exon boundaries in PRKAR1B (encoding protein kinase A regulatory subunit R1-beta), which resides within the linked locus, are associated with FH-II. METHODS: Primers enabling sequencing of all exons and intron/exon boundaries were designed by BLAT search using known mRNA sequence, and comparison with an orthologous mouse gene. Sequences from four affected and two unaffected subjects from an Australian family with FH-II demonstrating linkage at 7p22 were compared with published sequences. RESULTS: A probable two-nucleotide GenBank sequence error, resulting in an amino acid change, was detected. Two of seven single nucleotide polymorphisms (SNPs) identified were in exons and five in introns. Neither exon-localized SNP resulted in an amino acid change. All intron-localized SNPs were at least 16 nucleotides from the closest intron/exon boundary and therefore unlikely to interfere with gene splicing. Importantly, none of the identified SNPs was exclusively associated with affectation status. CONCLUSIONS: Mutations in the exons or intron/exon boundaries of PRKAR1B do not appear to be responsible for FH-II in this family, but a mutation in the promoter or remaining intronic or 5' or 3' untranslated regions could be. Alternatively, a mutation within another gene residing at the 7p22 locus may be responsible.