The insulin receptor is a transmembrane protein of the plasma membrane, where it recognizes extracellular insulin and transmits signals into the cellular signaling network. We report that insulin receptors are localized and signal in caveolae microdomains of adipocyte plasma membrane. Immunogold electron microscopy and immunofluorescence microscopy show that insulin receptors are restricted to caveolae and are colocalized with caveolin over the plasma membrane. Insulin receptor was enriched in a caveolae-enriched fraction of plasma membrane. By extraction with beta-cyclodextrin or destruction with cholesterol oxidase, cholesterol reduction attenuated insulin receptor signaling to protein phosphorylation or glucose transport. Insulin signaling was regained by spontaneous recovery or by exogenous replenishment of cholesterol. beta-Cyclodextrin treatment caused a nearly complete annihilation of caveolae invaginations as examined by electron microscopy. This suggests that the receptor is dependent on the caveolae environment for signaling. Insulin stimulation of cells prior to isolation of caveolae or insulin stimulation of the isolated caveolae fraction increased tyrosine phosphorylation of the insulin receptor in caveolae, demonstrating that insulin receptors in caveolae are functional. Our results indicate that insulin receptors are localized to caveolae in the plasma membrane of adipocytes, are signaling in caveolae, and are dependent on caveolae for signaling.
The causative agent of tuberculosis, Mycobacterium tuberculosis, shares several characteristics with organisms that produce biofilms during infections. One of these is the ability to form tight bundles also known as cords. However, little is known of the physiological relevance of the cording phenotype. In this study, we investigated whether cord-forming M. tuberculosis induce the formation of macrophage extracellular traps (METs) in human monocyte-derived macrophages. Macrophages have previously been shown to produce extracellular traps in response to various stimuli. We optimized bacterial culturing conditions that favored the formation of the cord-forming phenotype as verified by scanning electron microscopy. Microscopy analysis of METs formation during experimental infection of macrophages with M. tuberculosis revealed that cord-forming M. tuberculosis induced significantly more METs compared to the non-cording phenotype. Deletion of early secreted antigenic target-6 which is an important virulence factor of M. tuberculosis, abrogated the ability of the bacteria to induce METs. The release of extracellular DNA from host cells during infection may represent a defense mechanism against pathogens that are difficult to internalize, including cord-forming M. tuberculosis.
This paper describes the use of sputter coating to prepare detergent-extracted cytoskeletons for observation by scanning (SEM), scanning transmission (STEM), inverted contrast STEM, and transmission (TEM) electron microscopy. Sputtered coats of 1-2 nm of platinum or tungsten provide both an adequate secondary electron signal for SEM and good contrast for STEM and TEM. At the same time, the grain size of the coating is sufficiently fine to be just at (platinum) or below (tungsten) the limit of resolution for SEM and STEM. In TEM, the granular structure of platinum coats is resolved, and platinum decoration artifacts are observed on the surface of structures. The platinum is deposited as small islands with a periodic distribution that may reveal information about the underlying molecular structure. This method produces samples that are similar in appearance to replicas prepared by low-angle rotary shadowing with platinum and carbon. However, the sputter-coating method is easier to use; more widely available to investigators; and compatible with SEM, STEM, and TEM. It may also be combined with immunogold and other labeling methods. While TEM provides the highest resolution images of sputter-coated cytoskeletons, it also damages the specimens owing to heating in the beam. In SEM and STEM cytoskeletons are stable and the resolution is adequate to resolve individual microfilaments. The best single method for visualizing cytoskeletons is inverted contrast STEM, which images both the metal-coated cytoskeletal structures and electron-dense material within the nucleus and cytoplasm as white against a dark background. STEM and TEM were both suitable for visualizing colloidal gold particles in immunolabeled samples.
Abstract. Most ligand-receptor interactions result in an immediate generation of various second messengers and a subsequent association of the ligund-receptor complex to the cytoskeleton. Depending on the receptor involved, this linkage to the cytoskeleton has been suggested to play a role in the termination of second messenger generation and/or the endocytic process whereby the ligand-receptor complex is internalized. We have studied how the binding of chemotactic peptide-receptor complexes to the cytoskeleton of human neutrophils is accomplished. As much as 76% of the tritiated formylmethionyl-leucyl-phenylalanine (fMet-Leu-[3H]Phe) specifically bound to intact cells, obtained by a 30-s stimulation with 20 nM fMet-Leu-[3H]Phe, still remained after Triton X-100 extraction. Preincubating intact cells with dihydrocytochalasin B (dhCB) or washing the cytoskeletal preparation with a high concentration of potassium, reduced the binding of ligand-receptor complexes to the cytoskeleton by 46% or more. Inhibition of fMet-Leu-Phe-induced generation of second messengers by ADP-ribosylating the ,-subunit of the receptor-coupled G-protein with pertussis toxin, did not reduce the binding of ligandreceptor complexes to the cytoskeleton. However, using guanosine-5'-O-(2-thiodiphosphate) (GDP/~S) to prevent the dissociation of the fMet-Leu-Phe-associated G-protein within electrically permeabilized cells, led to a pronounced reduction (62%) of the binding between ligand-receptor complexes and the cytoskeleton. In summary, in human neutrophils the rapid association between chemotactic peptide-receptor complexes and the cytoskeleton is dependent on filamentous actin. This association is most likely regulated by the activation and dissociation of the fMetLeu-Phe-associated G-protein.H UMAN neutrophils and macrophages play an important role in the body defense against microorganisms. A fundamental quality of these cells, enabling them to perform these duties, is their ability to move and engulf particles. These motile events are dependent on dynamic alterations and reorganization of their cytoskeleton (36).The motile activity is induced by the specific binding of a ligand, a chemotactic factor or a phagocytic opsonin, to its respective receptor. The formation of ligand-receptor complexes triggers the generation of various transmembrane signals responsible for the activation of different effector systems in these cells (35). The signal transduction system activated by chemotactic factors in human neutrophils is generally agreed to involve a guanine nucleotide binding protein, G-protein (15). Evidence for the involvement of this G-protein is usually tested by using pertussis toxin (1,4,8,25,31), which ADP-ribosylates and thereby inhibits the activity of the oL-subunit of the G-protein (9, 24). In the absence of permssis toxin the chemotactic factor-receptor complex, via the ¢x-subunit of the G-protein, causes an increase in the activity of phospholipase C. This results in an increased breakdown of phosphafidylinositol 4,5-bisphosphat...
PDGF and neomycin induce similar changes in the actin cytoskeleton in human fibroblasts
The addition of platelet-derived growth factor (PDGF) to serum-starved fibroblasts induces increased motility, formation of lamellipodia, increased ruffling activity, and actin ring structures associated with dorsal ruffles. Involvement of the phosphatidylinositol cycle (PI-cycle) in these morphological changes was investigated by observing the effects of neomycin, an inhibitor of the PI-cycle, on cultured human foreskin fibroblasts. The role of actin in the changes was investigated by using cytochalasin D (CD). Actin in detergent-extracted cells was labelled with TRITC-phalloidin and examined with fluorescence microscopy. Using PDGF and neomycin simultaneously potentiated lamellipodia formation, ruffling activity, as well as the number of cells with actin rings. Furthermore, neomycin by itself induced morphological changes similar to those induced by PDGF. Quantitation of actin rings showed dose and time dependency for PDGF and neomycin respectively, with a maximal number of cells containing rings after 15 min of exposure to either 3.5 mM neomycin or 10 ng PDGF/ml. Comparing the two substances, PDGF induced ring formation in a greater number of cells. These processes were inhibited by the presence of CD. PDGF- and neomycin-induced changes in the actin cytoskeleton were also observed in human embryonic lung fibroblasts, human glial cells, and embryonic mouse fibroblasts, all of which are known to express PDGF-receptors. In conclusion, the present study indicates that an increased turnover of the PI-cycle is not essential for the changes in actin organization induced by PDGF.
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