Aberrant TP53 detected by combining immunohistochemistry and DNA-FISH improves Barrett's esophagus progression prediction: a prospective follow-up study.

Barrett's esophagus (BE) goes through a sequence of low grade dysplasia (LGD) and high grade dysplasia (HGD) to esophageal adenocarcinoma (EAC). The current gold standard for BE outcome prediction, histopathological staging, can be unreliable. TP53 abnormalities may serve as prognostic biomarkers. TP53 protein accumulation detected by immunohistochemistry (IHC) indirectly assesses TP53 mutations. DNA fluorescent in situ hybridization (FISH) on brush cytology specimens directly evaluates gene locus loss. We evaluated if IHC and FISH are complementary tools to assess TP53 abnormalities and tested their prognostic value in a long-term prospective follow-up of a BE cohort. TP53 IHC on tissue sections and FISH on brush cytology specimens were evaluated for 116 BE patients with respect to the different histological stages. The TP53 abnormalities were further studied in a panel of cell lines representative of the Barrett's carcinogenic sequence. For 91patients, the predictive value of TP53 abnormalities with respect to progression to HGD/EAC was tested after long term follow-up. The frequency of IHC and FISH TP53 abnormalities increased significantly with increasing histological stage (P < 0.001, Chi(2) -test). Combining the techniques detected TP53 abnormalities in 100% of patients with LGD, HGD, and EAC. Multivariate analysis showed that IHC (hazard ratio: 17, 95% CI: 3.2-96, P = 0.001) and FISH (hazard ratio: 7.3, 95% CI: 1.3-41, P = 0.02) were both independent significant predictors of progression. Combining FISH and IHC in assessing TP53 abnormalities leads to an increased detection rate of TP53 aberrations and improved accuracy for predicting BE progression.

Active matrix metalloproteases are expressed early on and are high during the Barrett's esophagus malignancy sequence.

OBJECTIVE: Molecular processes underlying Barrett's malignant development are poorly understood. Matrix metalloproteases (MMPs) are enzymes involved in inflammation, tissue remodeling, and malignant development. Therefore, active MMPs may have a role in early metaplasia development and Barrett's esophagus' malignant progression. We desired to gain more insight into the role of MMPs during the Barrett's esophagus pathogenesis sequence. MATERIAL AND METHODS: In a surgical Barrett's mouse model, and in nonmalignant Barrett's and malignant esophageal cell lines, the activity of MMPs was investigated using a MMP activatable probe. MMP activity was further validated in Barrett's esophagus and esophageal adenocarcinoma patient biopsies and was further differentiated by investigating MMP9 and MMP13 expressions. RESULTS: The mouse model showed probe activation in stromal cells early on in the esophagitis and metaplasia stages. MMP probe activation was higher in the Barrett's and cancer cell lines and biopsies as compared to normal cells and tissues. Co-immunostainings confirmed that, at the tissue level, the probe activation was mostly confined to CD45-positive stromal cells. MMP13 expression was highest in Barrett's metaplasia, whereas MMP9 was highest in the esophageal adenocarcinomas. CONCLUSION: During the Barrett's pathogenesis process, MMP activity is increased early on in the inflamed esophagus and remains high in metaplasia and esophageal adenocarcinoma. However, there is a switch of MMP13 to MMP9 expression once neoplasia develops. In the future, detecting specific MMP subtypes could be used for distinguishing nonmalignant from neoplastic Barrett's esophagus.

Increased phosphorylation on residue S795 of the retinoblastoma protein in esophageal adenocarcinoma.

Due to its increasing incidence and relatively poor prognosis, esophageal adenocarcinoma (EAC) is becoming a significant health problem. Elucidating the mechanisms underlying EAC development is of great importance to improve upon current conventional treatment strategies. Insight into phosphorylation has proven to be useful for the development of diagnostic and molecular treatment strategies in cancer. A pathway largely dependent on phosphorylation and frequently deregulated in cancer is the cell cycle regulating p16-retinoblastoma (Rb) pathway. We investigated kinase activity, specifically phosphorylation within the p16-Rb pathway, in EAC. A high-throughput peptide tyrosine kinase array containing short peptides representing 100 proteins with known phosphorylation sites, was used to assess phosphorylation activity in EAC. Also, specific phosphorylation changes of the cell cycle protein Rb and its upstream regulator P16 were validated through immunoblotting in EAC and normal esophageal cells and tissues. Phosphorylation activity was higher in EAC tissues as compared to normal squamous esophageal tissues. A majority of the proteins significantly higher phosphorylated in EAC were found to be involved in cell structure maintenance and immunity. Validation of Rb phosphorylation in EAC biopsy specimens and cell lines showed hyper phosphorylation of Rb associated with aberrant P16 expression in the cancer tissues. The specific Rb (S795) residue was significantly higher phosphorylated in EAC compared to normal esophageal tissue (Wilcoxon paired rank test, p=0.004). Investigation of Rb (S795) phosphorylation may indicate targets for intervention and give more molecular insight in EAC.