Distribution of beta-enolase in normal and tumor rat cells.

Enolase - a glycolytic enzyme is also expressed on the surface of eukaryotic cells such as macrophages, neutrophils, endothelial, neuronal, tumor cells. Surface enolase as plasminogen receptor plays an important role in myogenesis, tumorgenesis and angiogenesis. Determination of enolase localization in the cell lines may give rise to the elucidation of its receptor function in tumor cells. The cellular localization of the muscle-specific isoform of the enolase in normal rat cardiomyocytes (H9c2, an embryonic rat heart-derived cell line) and a rat sarcoma (R1) cell line is reported here. Immunocytochemical assays showed that this enolase isoform is freely diffused in the sarcoplasm of rat cells. The evident location of enolase molecules on the perinuclear surface is observed in immunofluorescence assays. Enolase localization on the surface of some intact normal rat cardiomyocytes was also observed. This surface protein maintains enolase catalytic activity

Distribution of beta-enolase in normal and tumor rat cells.

Enolase - a glycolytic enzyme is also expressed on the surface of eukaryotic cells such as macrophages, neutrophils, endothelial, neuronal, tumor cells. Surface enolase as plasminogen receptor plays an important role in myogenesis, tumorgenesis and angiogenesis. Determination of enolase localization in the cell lines may give rise to the elucidation of its receptor function in tumor cells. The cellular localization of the muscle-specific isoform of the enolase in normal rat cardiomyocytes (H9c2, an embryonic rat heart-derived cell line) and a rat sarcoma (R1) cell line is reported here. Immunocytochemical assays showed that this enolase isoform is freely diffused in the sarcoplasm of rat cells. The evident location of enolase molecules on the perinuclear surface is observed in immunofluorescence assays. Enolase localization on the surface of some intact normal rat cardiomyocytes was also observed. This surface protein maintains enolase catalytic activity

Experimental and bioinformatic approach to identifying antigenic epitopes in human α- and β-enolases

Human α- and β-enolases are highly homologous enzymes, difficult to differentiate immunologically. In this work, we describe production, purification and properties of anti-α- and anti-β-enolase polyclonal antibodies. To raise antibodies, rabbits were injected with enolase isoenzymes that were purified from human kidney (α-enolase) and skeletal muscle (β-enolase). Selective anti-α- and anti-β-enolase antibodies were obtained by affinity chromatography on either α- or β-enolase-Sepharose columns. On Western blots, antibodies directed against human β-enolase, did not react with human α-isoenzyme, but recognized pig and rat β-enolase. To determine what makes these antibodies selective bioinformatic tools were used to predict conformational epitopes for both enolase isoenzymes. Three predicted epitopes were mapped to the same regions in both α- and β-enolase. Peptides corresponding to predicted epitopes were synthesized and tested against purified antibodies. One of the pin-attached peptides representing α-enolase epitope (the C-terminal portion of the epitope 3 - S262PDDPSRYISPDQ273) reacted with anti-α-enolase, while the other also derived from the α-enolase sequence (epitope 2 - N193VIKEKYGKDATN205) was recognized by anti-β-enolase antibodies. Interestingly, neither anti-α- nor anti-β-antibody reacted with a peptide corresponding to the epitope 2 in β-enolase (G194VIKAKYGKDATN206). Further analysis showed that substitution of E197 with A in α-enolase epitope 2 peptide lead to 70% loss of immunological activity, while replacement of A198 with E in peptide representing β-enolase epitope 2, caused 67% increase in immunological activity. Our results suggest that E197 is essential for preserving immunologically active conformation in epitope 2 peptidic homolog, while it is not crucial for this epitope's antigenic activity in native β-enolase. Keywords: Enolase purification, Mass spectrometry, Epitope prediction, Specific antibodies, Cross-reactivit