Assessment of tumor characteristics based on glycoform analysis of membrane-tethered MUC1.

Clinical tissue specimens are useful for pathological diagnosis, which is, in some cases, supported by visualization of biomolecule localization. In general, diagnostic specificity in molecular pathology is increased by the acquisition of a probe to distinguish the modification of isomers. Although glycosylation is one of the candidate modifications in a protein, comparative glycan analysis of disease-associated proteins derived from a single tissue section is still challenging because of the lack of analytical sensitivity. Here we demonstrate a possible method for differential glycoform analysis of an endogenous tumor-associated glycoprotein MUC1 by an antibody-overlay lectin microarray. Tissue sections (5 µm thick) of patients with cholangiocarcinoma (CCA; n=21) and pancreatic ductal adenocarcinoma (PDAC; n=50) were stained with an anti-MUC1 antibody MY.1E12 that was established as a monoclonal antibody recognizing an MUC1 glycosylation isoform with a sialyl-core 1 structure (NeuAcα2-3galactosyl ß1-3-N-acetylgalactosamine). MY.1E12-positive tissue areas (2.5 mm2) were selectively dissected with a laser capture microdissection procedure. The membrane MUC1 was enriched by immunoprecipitation with MY.1E12 and subjected to lectin microarray analysis. Even though the reactivities of MY.1E12 between CCA and PDAC were similar, the lectin-binding patterns varied. We found Maackia amurensis leukoagglutinin and pokeweed lectin distinguished MY.1E12-reactive MUC1 of CCA from that of PDAC. Moreover, MUC1 with M. amurensis hemagglutinin (MAH) reactivity potentially reflected the degree of malignancy. These results were confirmed with MAH-MY.1E12 double fluorescent immunostaining. These glycan changes on MUC1 were detected with high sensitivity owing to the cluster effect of immobilized lectins on a tandem repeat peptide antigen covered with highly dense glycosylation such as mucin. Our approach provides the information to investigate novel glycodynamics in biology, for example, glycoalteration, as well as diseases related to not only MUC1 but also other membrane proteins.

MUC1 mucin and trefoil factor 1 protein expression in renal cell carcinoma: correlation with prognosis.

This study examines the coexpression of MUC1 mucin and trefoil factor 1 (TFF1) and their relationship to progression of renal cell carcinoma (RCC). Immunohistochemistry was performed on tumor and adjacent normal tissue from clear-cell RCC (n = 60) and tissues from normal controls (n = 5) using a set of well-characterized monoclonal antibodies recognizing different epitopes of MUC1 and TFF1. Results of immunohistochemistry were compared with clinical parameters, including tumor grade, tumor size, presence of metastasis, and progression-free survival of patients after surgery. In normal tissue, MUC1 and TFF1 were absent from the normal proximal tubular epithelium but were identified in distal and collecting tubular epithelium. In RCC, increased MUC1 expression positively correlated to tumor progression. MUC1 recognized by HMFG1 was associated with large tumor size (P < .05), distant metastasis (P < .05), and invasion of large veins (P < .05). Expression of the under-glycosylated form of MUC1 recognized by SM3 was found to correlate to time to progression (recurrence, metastasis, or death of patient; P < .001). Expression of TFF1 did not significantly correlate with any prognostic parameters. However, there was a significant correlation (P < .01) between TFF1 and MUC1 expression (HMFG2 epitope) in RCCs. These results are consistent with the following conclusions: (1) MUC1 may be an independent prognostic marker in RCC; (2) TFF1 is frequently coexpressed with MUC1 and may act synergistically; and (3) RCC may originate from distal tubular epithelium.