Plasminogen Binds Specifically to α-Enolase on Rat Neuronal Plasma Membrane

Abstract: Plasminogen (PGn) that we identified in microglial-conditioned medium has a neurotrophic factor-like effect on cultured neurons. We have also shown that PGn binds specifically to a protein with a molecular mass of 45 kDa in the neuronal plasma membrane. As a candidate PGn receptor-like molecule on the neuronal surface, this 45-kDa protein was purified from the plasma membrane of embryonic rat brain. Amino acid sequence analysis of polypeptides derived from the cleavage of the protein with cyanogen bromide and V8 protease revealed that the 45-kDa protein is identical to rat α-enolase. In fact, PGn was found to bind to purified rat α-enolase and also to a synthetic peptide (30 residues) that corresponds to the carboxyl terminal region of rat α-enolase. Physical properties of the 45-kDa protein, such as molecular mass, isoelectric point, and the ability to form dimers, are quite similar to those of α-enolase. The 45-kDa PGn-binding protein in the plasma membrane was also recognized by anti-rat α-enolase antibody, and pretreatment with α-enolase antibody markedly diminished the PGn-binding to the plasma membrane. In addition, immunocytochemical staining of the cultured cells under the nonpermeable condition showed that α-enolase is present on the cell surface of a certain population of neurons. These results suggest that α-enolase may function as a PGn-binding molecule on the neuronal cell surface.     

Human γγ-Enolase: Two-Site Immunoradiometric Assay with a Single Monoclonal Antibody

Abstract: A monoclonal antibody (mAb), termed BBS/NC/VI-H14 (H14), that reacts with the human enzyme γγ-enolase was prepared. It was directed against the γ-subunit and did not cross-react with the α- or β-subunit. The mAb H14 can be used for quantitative determination of γγ-enolase in a two-site immunoradiometric assay (two-site IRMA). It is also suitable for immunostaining formalin-fixed tissues. The specific identification of γγ-enolase provided by the two-site IRMA with H14 is discussed in relation to the cellular distribution of this protein.     

Differential analysis of D-beta-Asp-containing proteins found in normal and infrared irradiated rabbit lens

Although proteins are generally composed of l-alpha-amino acids, d-beta-aspartic acid (Asp)-containing proteins have been reported in various elderly tissues. Our previous study detected several d-beta-Asp-containing proteins in a rabbit lens derived from epithelial cell line by Western blot analysis of a 2D-gel using a polyclonal antibody that is highly specific for d-beta-Asp-containing proteins. The identity of each spot was subsequently determined by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and the Ms-Fit online database searching algorithm. In this study, we discovered novel d-beta-Asp-containing proteins from rabbit lens. The results indicate that beta-crystallin A3, beta-crystallin A4, beta-crystallin B1, beta-crystallin B2, beta-crystallin B3, gamma-crystallin C, gamma-crystallin D, and lambda-crystallin in rabbit lens contain d-beta-Asp residues. Furthermore, the occurrence of d-beta-Asp residues increases with infrared ray (IR) irradiation. Additionally, some d-beta-Asp-containing proteins only appear after IR irradiation. One such protein is the alpha-enolase, which shows homology to tau-crystallin.     

Hyper-phosphorylation of alpha-enolase in hypertrophied left ventricle of spontaneously hypertensive rat

Cardiac hypertrophy is one of the main target organ damages of essential hypertension and predicts a poor prognosis of the disease. The molecules involved in this event, especially their posttranslational modifications, remain largely unknown to date. With a combination of phosphoprotein column enrichment and two-dimensional gel electrophoresis separation, here we compared the profiling of enriched phosphoproteins from the left ventricle (LV) of spontaneously hypertensive rats (SHR) to that of age-matched Wistar Kyoto rats. As a result, 19 differential proteins were found in the hypertrophied LV of SHR. Among them, we focused on a glycolysis enzyme α-enolase, of which the hyper-phosphorylation was shown in the hypertrophied LV but not in non-hypertrophied atrium and right ventricle of SHR. Furthermore, the α-enolase hyper-phosphorylation was accompanied by decreased enzymatic activity. The further investigation based on these results would provide new clues to understand the pathological process of cardiac hypertrophy in SHR.     

Expression of the Neuron-Specific Enolase Gene by Rat Oligodendroglial Cells During Their Differentiation

Abstract: We have examined the regulation of neuron-specific γ-enolase gene (NSE) expression in oligodendrocytes at various steps of their differentiation/maturation. We have demonstrated for the first time that NSE is expressed in oligodendroglial cells in vitro and in vivo, and only at a certain stage of differentiation. A heterogeneity of the γ subunit was observed in cultured oligodendrocytes and the same one was found in adult rat brain. The level of γ mRNA increased when precursor cells differentiated into oligodendrocytes. By contrast, no significant change in α-enolase gene expression was observed. High NSE (γγ and αγ) enolase activity was detected in cultured oligodendrocytes. Treatment with basic fibroblast growth factor, which stimulates the proliferation of oligodendrocyte precursor cells and reversibly blocks their differentiation, resulted in lower αγ- and γγ-enolase activities in these cells, but it enhanced αα-enolase activity slightly. These data indicate that γ-enolase gene expression is associated with the differentiation of the oligodendrocytes and that it is repressed in adult fully mature cells.     

αγ-Enolase in the Rat: Ontogeny and Tissue Distribution

Abstract: The rat brain enolases are dimers composed of α and γ subunits. At pH 8.6 αγ-enolase seemed to be stable, and no evidence was found for the possible formation of αγ-enolase from αα-enolase and γγ-enolase in the course of rat brain homogenization. During ontogeny of the rat forebrain, αγ-enolase was formed before γγ-enolase. The half-maximal specific concentrations were reached at postnatal days 14 and 23, respectively. The distribution of αγ- and γγ-enolase in various rat brain areas was also investigated. In all areas both forms were present. In neuroendocrine tissues αγ-enolase was present at a much higher concentration than γγ-enolase. The ratio between γγ-enolase and αγ-enolase may be indicative of the degree of neuronal maturation, a conclusion further substantiated by the high ratio observed in cerebellum and the low ratio observed in olfactory bulbs, both compared with the ratio in forebrain.     

The role of corneal crystallins in the cellular defense mechanisms against oxidative stress

The refracton hypothesis describes the lens and cornea together as a functional unit that provides the proper ocular transparent and refractive properties for the basis of normal vision. Similarities between the lens and corneal crystallins also suggest that both elements of the refracton may also contribute to the antioxidant defenses of the entire eye. The cornea is the primary physical barrier against environmental assault to the eye and functions as a dominant filter of UV radiation. It is routinely exposed to reactive oxygen species (ROS)-generating UV light and molecular O(2) making it a target vulnerable to UV-induced damage. The cornea is equipped with several defensive mechanisms to counteract the deleterious effects of UV-induced oxidative damage. These comprise both non-enzymatic elements that include proteins and low molecular weight compounds (ferritin, glutathione, NAD(P)H, ascorbate and alpha-tocopherol) as well as various enzymes (catalase, glucose-6-phosphate dehydrogenase, glutathione peroxidase, glutathione reductase, and superoxide dismutase). Several proteins accumulate in the cornea at unusually high concentrations and have been classified as corneal crystallins based on the analogy of these proteins with the abundant taxon-specific lens crystallins. In addition to performing a structural role related to ocular transparency, corneal crystallins may also contribute to the corneal antioxidant systems through a variety of mechanisms including the direct scavenging of free radicals, the production of NAD(P)H, the metabolism and/or detoxification of toxic compounds (i.e. reactive aldehydes), and the direct absorption of UV radiation. In this review, we extend the discussion of the antioxidant defenses of the cornea to include these highly expressed corneal crystallins and address their specific capacities to minimize oxidative damage.     

Molecular characterization of soluble factors from human menstrual effluent that induce epithelial to mesenchymal transitions in mesothelial cells

We have studied menstrual effluent in order to identify soluble menstrual factors that induce epithelial to mesenchymal transitions (EMT) in mesothelial cells. A variety of molecules, such as nitric oxide and its reaction products, proteases (i.e. matrix metalloproteinases, plasmin) and proteins and/or peptides (i.e. growth factors: b-fibroblast growth factor, epidermal growth factor, hepatocyte growth factor, transforming growth factor-β; cytokines: interleukin 1β, tumour necrosis factor-α [TNF-α]) may be involved in this process. We have demonstrated that TNF-α is involved in EMT, whereas the other molecules are not. Biochemical analysis has shown that the inducing menstrual factors are heat-labile molecules, are uncharged at neutral pH, have a molecular weight between 50–70 kDa (or are bound in complexes of that size) and are eluted in the albumin fraction during gel filtration chromatography. Further analysis of this fraction by using proteomics and mass spectrometry has led to the identification of α-enolase and haemoglobin whose inhibition partially prevents EMT. When antibodies against TNF-α, α-enolase and haemoglobin are combined, EMT is almost completely inhibited. Thus, the candidates for soluble menstrual factors that induce mesothelial EMT are TNF-α, α-enolase and haemoglobin.