Studies of salivary pepsin in patients with gastro-oesophageal reflux disease.

BACKGROUND: Gastro-oesophageal reflux disease (GERD) is difficult to diagnose without invasive testing. Peptest (RD Biomed, Hull, UK) is a recently marketed diagnostic tool which aims to quantify salivary pepsin as a marker of reflux, providing a rapid alternative to invasive procedures. AIM: To evaluate optimal timing for sampling, and to evaluate the accuracy of Peptest against an independent measure. METHODS: Thirty diagnosed GERD patients (12 female, mean age 49 [range 20-72]) and 20 asymptomatic subjects (14 female, mean age 56 [range 21-56]) were subject to diurnal saliva sampling, with additional samples for 60 minutes following self-reported reflux symptoms and triggering of a proximal reflux alarm. Saliva samples were split and were analysed by both Peptest and ELISA with operators for each blinded to sample identity. RESULTS: Salivary pepsin was detectable in most patients and most volunteers. Peptest scores were significantly lower for patients than controls (P < 0.005). ELISA scores showed no difference between patients and controls. There was no effect of diurnal sampling time (P = 0.75) or time after symptoms (P = 0.76) on Peptest readout. There was no correlation between Peptest and Pepsin ELISA (P = 0.55); Bland-Altman analysis suggested no agreement between the tests (P = 0.414). Receiver-operator curve suggests that neither Peptest (P = 0.3328) nor pepsin (P = 0.4476) is useful for predicting GERD. CONCLUSION: Salivary pepsin is not a reliable tool for the diagnosis of GERD.

Application of high content biology to yield quantitative spatial proteomic information on protein acetylations.

High content analysis (HCA; also referred to as high content biology) is a quantitative, automated, medium-throughput microscopy approach whereby cell images are segmented into relevant compartments (nuclei, cytoplasm) and the staining in each compartment quantified by computer algorithms. The extraction of quantitative information from the cell image generates a wealth of data which contributes significantly to the acceleration of drug discovery and biological research. Here we have adapted HCA to analyze protein acetylations in the cytoskeleton. This approach yields associative information on the link between acetylation and cytoskeletal organization. The protocol also describes optimization steps for cytoskeletal analysis and its application across different cell types, and HCA platforms. The methods described herein are readily adaptable to non-cytoskeletal acetylations and have been applied to the analysis of transcription factors.

Alteration in composition of keratin intermediate filaments in a model of breast cancer progression and the potential to reverse hallmarks of metastasis.

BACKGROUND: In breast cancer the development of metastasis is a major turning point in the treatment and outcome of the disease. Throughout tumour development, and especially in the development of metastasis, epithelial mesenchymal transition takes place. During this transformation into a mesenchymal phenotype, the tumour cells undergo a series of structural changes. The loss of structural integrity and adoption of mesenchymal filaments enables cells to detach from the epithelial cell layer and metastasise. Keratins form the intermediate filaments of the cytoskeleton and provide scaffold structures within cells. During cancer progression the intermediate filaments are reorganised, and dramatic changes are seen in their protein components. Keratins K8, K18, K19 and vimentin are intermediate filament proteins with altered expression profiles during tumour development. METHOD: We have used in vivo and in vitro models to analyse changes in intermediate filament proteins. Antibody-based methods were used to study K8 levels and proteomic analysis to profile the protein content of metastatic breast cancer cell variants. RESULTS: K8 expression declines as human breast tumours progress into an invasive phenotype. Analysis of IF proteins indicated altered expression profiles of K8, K18, K19 and vimentin, with K8, K18, K19 expressed in high levels in the T47D and MCF-7 cell lines, whereas the highly metastatic cell lines expressed lower levels of K8 and K18 and no detectable K19. Vimentin showed reverse expression profile with T47D and MCF-7 cells having no detectable vimentin expression whereas the highly metastatic MDA-MB-231 and MDA-MB-436 showed high levels. Analysis of acetylation status using specific antibodies suggested acetylation occurred within the central coiled domain in the MCF-7 and T47D cells. Inhibition of tumour growth by tissue factor (TF) shRNA resulted in a dramatic re-elevation of expression of K8 in xenographs of the highly metastatic MDA-MB-436 line. CONCLUSION: Intermediate filament expression alters during epithelial mesenchymal transition. Identified post translational modifications may play a role in alterations seen in the organisation, solubility and stability of these filaments. Epithelial mesenchymal transition can be reversed and an epithelial phenotype re-established.

A proteomic analysis of differential cellular responses to the short-chain fatty acids butyrate, valerate and propionate in colon epithelial cancer cells.

The short chain fatty acids (SCFAs) are inhibitors of histone deacetylases (HDACi); they are produced naturally in the colon by fermentation. They affect cellular processes at a molecular and transcriptional level, the mechanisms of which may involve large numbers of proteins and integrated pathways. Butyrate is the most biologically potent of the SCFAs in colon epithelial cells, inhibiting human colon carcinoma cell proliferation and inducing apoptosis in vitro. In order to investigate the hypothesis that propionate and valerate possess unique and independent actions from butyrate, we combined proteomic and cellomic approaches for large-scale comparative analysis. Proteomic evaluation was undertaken using an iTRAQ tandem mass-spectrometry workflow and high-throughput High-content Analysis microscopy (HCA) was applied to generate cellomic information on the cell cycle and the cytoskeletal structure. Our results show that these SCFAs possess specific effects. Butyrate was shown to have more pronounced effects on the keratins and intermediate filaments (IFs); while valerate altered the ß-tubulin isotypes' expression and the microtubules (MTs); propionate was involved in both mechanisms, displaying intermediate effects. These data suggest distinct physiological roles for SCFAs in colon epithelial function, offering new possibilities for cancer therapeutics.