Protein phosphorylation has been suggested as an important control mechanism for the events leading toward the initiation and completion of mitosis. Using a monoclonal antibody recognizing a class of phosphoproteins abundant in mitotic cells, we demonstrated the localization of a subset of these phosphoproteins to several discrete mitotic structures. Patchy immunofluorescence was present in the interphase nuclei, but a significant increase in nuclear immunofluorescence was apparent at prophase. Subsequent mitotic stages demonstrated that immunoreactive material was particularly apparent at microtubule organizing centers, namely, centrosomes, kinetochores, and midbodies. Intense centrosomal localization occurred at the prophase-prometaphase transition and persisted until the reformation of the nuclear membrane in early G1. The cytoplasm of mitotic cells also contained immunoreactive material in sharp contrast to interphase cells that exhibited no cytoplasmic fluorescent staining. Much of the diffuse immunofluorescent cytoplasmic material was removed by a brief lysis of the cells with 0.15% Triton X-100 prior to fixation. The localization of the remaining immunoreactive material after detergent lysis to mitotic microtubule organizing centers suggests that they contain phosphoprotein structural components important, perhaps, in the mitotic phase-interphase transition.The regulatory events controlling the initiation and completion of mitosis are poorly understood. It is apparent, however, that such varied cellular responses as reorganization of the microtubule network, chromosome condensation, centriole duplication, breakdown of the nuclear membrane, formation of the mitotic spindle, and cytokinesis must be coordinated closely for the cell to progress through mitosis.One possible mechanism for controlling these mitotic events would be through protein phosphorylation and dephosphorylation. In several systems, increased levels of protein phosphorylation are cell-cycle dependent phenomena. During meiotic maturation of Xenopus laevis oocytes, the incorporation of 32p into protein is maximal prior to mitosis (1). Similarly, in HeLa cells, nuclear matrix proteins are phosphorylated to a maximal extent during the premitotic (G2) phase (2). More specifically, the three major protein components of the nuclear lamina, lamins A, B, and C, incorporate 32p maximally at the time of nuclear-envelope dissolution (3). The presence of other mitosis-specific proteins has been detected also by two-dimensional gel electrophoretic analysis of synchronized HeLa cell populations (4).Davis et al. (5) have reported on the properties of a monoclonal antibody that recognized a set of phosphorylated proteins abundant in mitotic cells. Using one of these monoclonal antibodies, MPM-2 (5), we report here the localization of immunoreactive material to the centrosome, the kinetochore, and the midbody of mitotic cells. These results support the concept that specific protein phosphorylation may coordinate the transition of cells from interphas...
In pre-embedding EM immunocytochemistry with gold probes, the gold must be small enough to penetrate through cell membranes treated with mild detergents. Antibodies labeled with small gold probes (1-1.4 nm) are too small to be resolved in thin sections but can be seen if they are silver-enhanced after the gold has bound to the antigens in the cells. We investigated several aspects of gum arabic-silver lactate-hydroquinone enhancement solution (Danscher solution) by examining gold-conjugated antibodies embedded in agar, sectioned on a vibrotome, and enhanced with different solutions. The rate of silver enhancement was optimized in 50% gum arabic and 200 mM HEPES buffer, pH 5.8. We also examined chemicals used as developers and found that N-propyl gallate (NPG) gave a more uniform development than the routinely used hydroquinone (HQ). The diameter of the silver-enhanced particles after incubation in osmium tetratoxide (OSO4) decreased somewhat with longer incubation time and higher percentages, but the density (number per unit area) of silver-enhanced particles was little changed. The loss of silver-enhanced particle diameter was reduced by lowering the concentration of OSO4 to 0.1%. Comparison of commercial small gold probes showed that NPG enhancement of Nanogold gave more uniform particle size and a better correlation between enhancement time and particle density. When this procedure was applied to cell cultures with monoclonal antibodies, the silver-enhanced particles were similar to those in the agar sections. When free-floating tissue sections were used, longer silver enhancement times were needed to obtain similarly sized particles. This new NPG-silver-enhancement procedure offers a reliable and easy method to localize proteins in cultured cells and tissue sections by pre-embedding electron microscopic immunocytochemistry.
The human amnion is a major intrauterine source of prostaglandin (PG) E(2), a potent mediator of uterine contractions and cervical ripening. During parturition, inflammatory cytokines promote PGE(2) production through increased prostaglandin-endoperoxide synthase-2 (PTGS2, also known as cyclooxygenase-2) expression. This is mediated, in part, through activation of the transcription factor nuclear factor kappa B (NFkappaB). Prostaglandin E synthase (PTGES, also known as microsomal PGE synthase-1) acts downstream of PTGS2 and is inducibly expressed in most systems. We hypothesized that NFkappaB might regulate cytokine-induced PTGES expression in amnion cells. With amnion mesenchymal cells, we found that proinflammatory cytokines coordinately upregulated PTGS2 and PTGES mRNA expression. In parallel, increased expression of the PTGS2 and PTGES proteins was observed. In comparison, the expression of two other PGE synthases (PTGES2 and PTGES3) was unmodified. PTGES induction was blocked both in the presence of pharmacological NFkappaB inhibitors and following adenovirus-mediated overexpression of a dominant-negative NFkappaB pathway protein. In cells transiently transfected with a luciferase reporter bearing a portion (-597/+33) of the human PTGES gene promoter, interleukin-1beta (IL1B) produced a moderate increase in luciferase activity; this effect was abrogated in the presence of an indirect NFkappaB inhibitor (MG-132). Finally, a kappaB-like regulatory element was identified that, when mutated, markedly attenuated IL1B-responsive PTGES promoter activity. In conclusion, our results support a role for NFkappaB in cytokine-induced PTGES expression in amnion mesenchymal cells in vitro. By coordinately regulating PTGS2 and PTGES, NFkappaB may contribute to an inducible PGE(2) biosynthesis pathway during human parturition.
SUMMARYWe tested the immunoprobe FluoroNanogold (FNG) for its utility as an immunocytochemical labeling reagent. This immunoprobe consists of a 1.4-nm gold particle to which a specific Fab Ј fragment and a fluorochrome are conjugated. We employed the microtubules (MTs) of human phagocytic leukocytes as a model system for testing the usefulness of FNG as a secondary antibody for immunocytochemistry. We show that these fluorescently labeled ultrasmall immunogold particles are very efficient for labeling MTs in these cells. The signal from FNG can be detected directly by fluorescence microscopy or indirectly by other modes of optical microscopy and electron microscopy, after silverenhancement of the gold. The spatial resolution of immunolabeled MTs obtained with FNG and silver enhancement was comparable to that of conventional immunofluorescence detection. Colloidal gold (5-nm and 10-nm in diameter), on the other hand, failed to label MTs in cells prepared in a similar manner. This difference in labeling was due in large part to greater penetration of 1.4-nm gold into aldehyde-fixed cells than either 5-nm or 10-nm gold particles. The fluorescent 1.4-nm immunoprobe was shown to be an important new tool for general use in correlative microscopy. (J Histochem Cytochem 45:631-642, 1997)
A proteomics screen of human placental microvillous syncytiotrophoblasts (STBs) revealed the expression of dysferlin (DYSF), a plasma membrane repair protein associated with certain muscular dystrophies. This was unexpected given that previous studies of DYSF have been restricted to skeletal muscle. Within the placenta, DYSF localized to the STB and, with the exception of variable labeling in the fetal placental endothelium, none of the other cell types expressed detectable levels of DYSF. Such restricted expression was recapitulated using primary trophoblast cell cultures, because the syncytia expressed DYSF, but not the prefusion mononuclear cells. The apical plasma membrane of the STB contained approximately 4-fold more DYSF than the basal membrane, suggesting polarized trafficking. Unlike skeletal muscle, DYSF in the STB is localized to the plasma membrane in the absence of caveolin. DYSF expression in the STB was developmentally regulated, because first-trimester placentas expressed approximately 3-fold more DYSF than term placentas. As the current literature indicates that few cell types express DYSF, it is of interest that the two major syncytial structures in the human body, skeletal muscle and the STB, express this protein.
Alzheimer's Disease (AD) is characterized by the appearance of neurofibrillary and granulovacuolar lesions in the brains of affected individuals. The former is composed of hyperphosphorylated aggregates of the microtubule-associated protein tau. The latter is poorly characterized but reacts strongly with anti-phosphoepitope antibodies indicating that it too accumulates phosphoproteins. Both lesions react strongly with antibodies directed against members of the casein kinase-1 family of phosphotransferases, a group of closely related protein kinases that frequently function in tandem with the ubiquitin modification system. To determine whether individual members of the casein kinase-1 family differentially associate with AD lesions, hippocampal sections isolated from late stage cases of AD were subjected to double-label fluorescence immunohistochemistry using a panel of selective anti-casein kinase 1 antibodies and small-molecule fluorochromes thioflavin S and thiazin red. The resultant colocalization patterns revealed that the alpha CK1 isoform strongly correlated with thioflavin S and thiazin red fluorescence, indicating that it preferentially associated with neurofibrillary lesions. In contrast, the delta isoform staining pattern was dominated by colocalization with granulovacuolar degeneration bodies. These findings suggest that granulovacuolar and neurofibrillary lesions occupy separate populations of neurons, and implicate CK1 isoforms in the generation of lesion-associated phosphoepitopes. They also suggest a nexus between the phosphorylation and ubiquitination modifications found in both lesions.
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