LEF-1 is a Sensitive Marker of Cribriform Morular Variant of Papillary Thyroid Carcinoma

Many genes and signalling pathways controlling cell proliferation, death and differentiation, as well as genomic integrity, are involved in cancer development. New techniques, such as serial analysis of gene expression and cDNA microarrays, have enabled measurement of the expression of thousands of genes in a single experiment, revealing many new, potentially important cancer genes. These genome screening tools can comprehensively survey one tumor at a time; however, analysis of hundreds of specimens from patients in different stages of disease is needed to establish the diagnostic, prognostic and therapeutic importance of each of the emerging cancer gene candidates. Here we have developed an array-based high-throughput technique that facilitates gene expression and copy number surveys of very large numbers of tumors. As many as 1000 cylindrical tissue biopsies from individual tumors can be distributed in a single tumor tissue microarray. Sections of the microarray provide targets for parallel in situ detection of DNA, RNA and protein targets in each specimen on the array, and consecutive sections allow the rapid analysis of hundreds of molecular markers in the same set of specimens. Our detection of six gene amplifications as well as p53 and estrogen receptor expression in breast cancer demonstrates the power of this technique for defining new subgroups of tumors.

Thyroid carcinoma has been described as occurring more frequently than expected in association with familial adenomatous polyposis. The histology of these cases has not been described in detail, although the reported cases were usually diagnosed as papillary carcinoma. We now report the pathological features of four cases of thyroid carcinoma associated with familial adenomatous polyposis, and review the findings in the literature. The tumours in these four cases were all of follicular cell origin as shown by thyroglobulin immunohistochemistry. In three they were multifocal. The tumours showed some features of papillary carcinoma--grooved nuclei and papillary architecture, but these were not consistent. They also showed features that were unusual for papillary carcinoma--a cribriform pattern and solid areas with spindle cell component. Commonly the tumours combined both patterns. A review of the reported cases of thyroid cancer associated with familial adenomatous polyposis showed that they also were commonly multifocal and occurred predominantly in young women. When the histology was adequately reported or illustrated it was, in most instances, consistent with the findings in our own cases. We therefore suggest that these thyroid tumours form a distinct type with some unusual features. Clearly it is likely that the APC gene is associated with their pathogenesis, and that other factors contribute to the predominantly female incidence in this as in sporadic tumours. Six of 63 reported cases showed metastasis or died from thyroid carcinoma. In a number of cases the tumours presented before the familial adenomatous polyposis was recognized. The findings of these unusual histological features in a thyroid tumour, and particularly of multicentricity, should alert the pathologist to the possibility of familial adenomatous polyposis with its implications for family screening. The tumours are often well demarcated but, because of the multicentricity, total thyroidectomy should be advocated.

Solid-pseudopapillary neoplasms are rare, but are distinctive pancreatic tumors of low-malignant potential. While the histogenesis of these tumors is unclear, they are often associated with gain-of-function mutations in the catenin (cadherin-associated protein), beta 1 (88 kDa), or CTNNB1 gene, resulting in nuclear accumulation of CTNNB1. CTNNB1 is a central component of the Wnt signaling pathway and mediates gene expression through the lymphoid enhancer-binding factor 1 (LEF1) /T-cell factor transcription complex. Although LEF1 has a pivotal role in the transactivation of Wnt/CTNNB1 responsive genes, the status of LEF1 in solid-pseudopapillary neoplasms and other pancreatic tumors has not been examined. We analyzed both LEF1 and CTNNB1 in a large cohort of pancreatic tumors (n=155). In all cases of solid-pseudopapillary neoplasms including surgical resections (n=27) and cytologic samples (n=8) had strong and diffuse nuclear labeling for both LEF1 and CTNNB1. The surrounding uninvolved pancreatic parenchyma was devoid of any LEF1 staining. All resection and cytologic specimens from well-differentiated pancreatic neuroendocrine tumors (n=44; n=29, respectively), high-grade pancreatic neuroendocrine carcinomas (n=2; n=1), pancreatic ductal adenocarcinomas (n=25; n=12), and acinar cell carcinomas (n=9; n=2) studied were negative for both nuclear LEF1 and CTNNB1. However, nuclear LEF1 and CTNNB1 were detected in all four resected pancreatoblastomas (no cytologic specimens were available for immunolabeling), but primarily centered around and within squamoid corpuscles. In summary, abnormal CTNNB1 accumulation was accompanied by nuclear LEF1 overexpression in both solid-pseudopapillary neoplasms and pancreatoblastomas. But, in contrast to pancreatoblastomas, a diffuse, nuclear labeling was observed in solid-pseudopapillary neoplasms and further implicates the CTNNB1/LEF1 transcriptional complex in the development of solid-pseudopapillary neoplasms. In addition, as part of an immunohistochemical panel, LEF1 can be a useful ancillary stain in the diagnosis of solid-pseudopapillary neoplasms.