Dynamics of epidermal growth factor receptor internalization studied by Nanovid light microscopy and electron microscopy in combination with immunogold labeling

Individual gold particles with a diameter of approximately 10 to 40 nm can be visualized using video-enhanced contrast microscopy (Nanovid) (De Brabander et al., Cell Motil. Cytoskel. 6, 105-113 (1986)). This technique allows a study of the dynamic properties of receptors and ligands in living cells at high resolution. We have studied epidermal growth factor (EGF) receptor internalization in human epidermoid carcinoma A431 cells, using a monoclonal anti-EGF-receptor antibody conjugated to 20-nm gold particles, referred to as 2E9-gold. Exposure of A431 cells to 2E9-gold at 37 degrees C resulted in binding of the complex at the cell surface. Most of the gold particles exhibit a Brownian type of movement, while a minority appeared immobile. Binding of the 2E9-gold complex is followed by internalization, as judged from Nanovid light microscopy studies in combination with electron microscopic observations. The internalized gold particles clearly cluster into large aggregates, most likely multivesicular bodies. Individual gold particles as well as aggregates are characterized by a saltatory movement, by which the gold particles eventually move from the cell periphery towards the cell center. Addition of EGF results in an increased rate of internalization of 2E9-gold, while Na-azide and nocodazole completely immobilize the intracellular gold particles, as has been demonstrated previously for the transferrin receptor.     

Direct detection of immunogold reactions by real-time video microscopy

Summary Video-enhanced microscopy allows the detection and tracking of individual colloidal gold particles. The analysis of immunogold reactions can also be conducted as a function of time and thus allows the study of dynamic events in living cells. The direct visualization in real time is reported of the reaction of immunogold particles with a surface antigen. This time-resolved immunocytochemistry was achieved by continuous observation of living cells infected with a virus (respiratory syncytial virus) following their incubation with colloidal gold (30 nm) coated with antiviral antibodies. The progress of the immunoreaction was visualized as a sequential deposition of individual gold granules on the viral particles until saturation was reached after 60 min. Binding of colloidal gold was an irreversible event as no elution or dislocation of surface-bound granules took place. Comparative imaging of colloidal gold particles by electron microscopy and by video microscopy demonstrated that the video-imaged immunoreactions represented events involving single gold particles; their signal was sometimes clearly enhanced by secondary depositions taking place in close proximity, i.e. at a distance below the lateral resolution of the light microscope. Our experiments demonstrate that video-enhanced microscopy provides a powerful tool for studying antibody-antigen reactions with a high spatial and temporal resolution.     

Direct detection of immunogold reactions by real-time video microscopy.

Video-enhanced microscopy allows the detection and tracking of individual colloidal gold particles. The analysis of immunogold reactions can also be conducted as a function of time and thus allows the study of dynamic events in living cells. The direct visualization in real time is reported of the reaction of immunogold particles with a surface antigen. This time-resolved immunocytochemistry was achieved by continuous observation of living cells infected with a virus (respiratory syncytial virus) following their incubation with colloidal gold (30 nm) coated with antiviral antibodies. The progress of the immunoreaction was visualized as a sequential deposition of individual gold granules on the viral particles until saturation was reached after 60 min. Binding of colloidal gold was an irreversible event as no elution or dislocation of surface-bound granules took place. Comparative imaging of colloidal gold particles by electron microscopy and by video microscopy demonstrated that the video-imaged immunoreactions represented events involving single gold particles; their signal was sometimes clearly enhanced by secondary depositions taking place in close proximity, i.e. at a distance below the lateral resolution of the light microscope. Our experiments demonstrate that video-enhanced microscopy provides a powerful tool for studying antibody-antigen reactions with a high spatial and temporal resolution.     

Confined lateral diffusion of membrane receptors as studied by single particle tracking (nanovid microscopy). Effects of calcium-induced differentiation in cultured epithelial cells.

The movements of E-cadherin, epidermal growth factor receptor, and transferrin receptor in the plasma membrane of a cultured mouse keratinocyte cell line were studied using both single particle tracking (SPT; nanovid microscopy) and fluorescence photobleaching recovery (FPR). In the SPT technique, the receptor molecules are labeled with 40 nm-phi colloidal gold particles, and their movements are followed by video-enhanced differential interference contrast microscopy at a temporal resolution of 33 ms and at a nanometer-level spatial precision. The trajectories of the receptor molecules obtained by SPT were analyzed by developing a method that is based on the plot of the mean-square displacement against time. Four characteristic types of motion were observed: (a) stationary mode, in which the microscopic diffusion coefficient is less than 4.6 x 10(-12) cm2/s; (b) simple Brownian diffusion mode; (c) directed diffusion mode, in which unidirectional movements are superimposed on random motion; and (d) confined diffusion mode, in which particles undergoing Brownian diffusion (microscopic diffusion coefficient between 4.6 x 10(-12) and 1 x 10(-9) cm2/s) are confined within a limited area, probably by the membrane-associated cytoskeleton network. Comparison of these data obtained by SPT with those obtained by FPR suggests that the plasma membrane is compartmentalized into many small domains 300-600 nm in diameter (0.04-0.24 microns2 in area), in which receptor molecules are confined in the time scale of 3-30 s, and that the long-range diffusion observed by FPR can occur by successive movements of the receptors to adjacent compartments. Calcium-induced differentiation decreases the sum of the percentages of molecules in the directed diffusion and the stationary modes outside of the cell-cell contact regions on the cell surface (which is proposed to be the percentage of E-cadherin bound to the cytoskeleton/membrane-skeleton), from approximately 60% to 8% (low- and high-calcium mediums, respectively).     

Nanovid tracking: a new automatic method for the study of mobility in living cells based on colloidal gold and video microscopy.

We describe a new automatic technique for the study of intracellular mobility. It is based on the visualization of colloidal gold particles by video-enhanced contrast light microscopy (nanometer video microscopy) combined with modern tracking algorithms and image processing hardware. The approach can be used for determining the complete statistics of saltatory motility of a large number of individual moving markers. Complete distributions of jump time, jump velocity, stop time, and orientation can be generated. We also show that this method allows one to study the characteristics of random motion in the cytoplasm of living cells or on cell membranes. The concept is illustrated by two studies. First we present the motility of colloidal gold in an in vitro system of microtubules and a protein extract containing a kinesin-like factor. The algorithm is thoroughly tested by manual tracking of the videotapes. The second study involves the motion of gold particles microinjected in the cytoplasm of PTK-2 cells. Here the results are compared to a study using the spreading of colloidal gold particles after microinjection.     

A multiple-staining ultrastructural procedure simultaneously detecting three membrane antigens on suspended cells by monoclonal antibodies and preembedding immunogold labelling

Summary A triple ultrastructural immunogold staining method for the simultaneous demonstration of three surface antigens of peripheral blood mononuclear cells at the electron microscope level is described. A six-step pre-embedding immunoelectron microscopy procedure was developed, using commercially available reagents. The CD11b antigen was first detected, through a two-step (indirect) method with 40 nm-sized gold particles; after a blocking step, the HLA-DR surface antigen was subsequently detected, through a two-step (biotin-streptavidin) method with 20 nm-sized gold particles; the CD4 antigen was finally detected, through a one-step (direct) method, using 5 nm-sized gold particles. Electron microscopic examination revealed firstly the presence of a triple-labelled cell subpopulation, which showed gold granules of the three sizes simultaneously decorating the cell membrane. Thus, the cells of such a subset simultaneously expressed the three antigens investigated. In contrast, either gold particles of only one size or no gold particles were observed on the cell surface of other subpopulations. This technique is a model demonstrating the importance of varying the size of particles in pre-embedding gold immunoelectron microscopy for a better analysis of the expression of surface antigens in isolated cells.     

Quantitative characterization of aqueous solutions probed by the third-harmonic generation microscopy

Third-harmonic microscopy is one of the emerging techniques for noninvasive microscopic imaging of biological structures. We use a novel technique for nonlinear optical material characterization and study the effect of different environment and the structural sensitivity of the third harmonic. In particular, a transformation of collagen in solution is observed for the first time using third-harmonic generation. We also study the ultimate limits of the third harmonic to detect micro- and nanoscopic features inside living cells and find that structures as small as 50 nm can be detected using the current level of technology.     

Fluorescence in situ hybridisation coupled to ultra small immunogold detection to identify prokaryotic cells using transmission and scanning electron microscopy

We describe a method based on fluorescence in situ hybridisation (FISH) that allows the identification of individual cells by electron microscopy. We hybridised universal and specific fluorescein-labelled oligonucleotide probes to the ribosomal RNA of prokaryotic microorganisms in heterogeneous cell mixtures. We then used antibodies against fluorescein coupled to sub-nanometer gold particles to label the hybridised probes in the ribosome. After increasing the diameter of the metal particles by silver enhancement, the specific gold-silver signal was visualised by optical microscopy, transmission electron microscopy (TEM) and scanning electron microscopy (SEM). It is the first time that SEM is applied to the detection of gold nanoparticles hybridised to an intracellular target, such as the ribosome. The possibility to couple phylogenetic identification by FISH to cell surface and ultrastructure observation at electron microscopy resolution has promising potential applications in microbial ecology.     

Silver enhancement of protein A-gold probes on resin-embedded ultrathin sections. An electron microscopic localization of mouse mammary tumor virus (MMTV) antigens

A simple method is described allowing the enhancement of the visibility of small gold probes for the electron microscopy. This method, which allows the silver intensification of gold directly on epon-embedded ultrathin sections, was used for the electron microscopic localization of Mouse Mammary Tumor Virus (MMTV) antigens in cultured cells derived from GR and BALB/cfRIII mouse mammary tumors. After the immunostaining with the preembedding protein A-gold technique, the ultrathin sections, placed on 200 mesh copper grids, were rehydrated and exposed to a photographic developer containing silver nitrate. During this physical development gold particles are incapsulated in growing shells of metallic silver, which gradually become more and more visible. We were able to obtain a heavy labelling of the viral particles, well visible even at low magnification, with a negligeable background staining. The present technique can be useful whenever it is necessary to use the smallest gold probes today available.     

Investigation of immunogold-silver staining by electron microscopy

Deposition of metallic silver on colloidal gold immunoreagents has been shown to be a very sensitive immunostaining technique capable of detecting low levels of immunoreactivity in tissue sections. Using electron microscopy we have shown that immunolabelling is highest with small sizes of gold which can penetrate sections better and achieve higher densities of particles in the section than larger particles. Chemical permeabilisation of the embedding medium aids the penetration of colloidal gold. The silver enhancement step in immunogold-silver staining was shown to be progressive, allowing optimisation of staining and the selection of the final size of silver deposits required. Some poorly understood features of the technique are rationalised and the additional knowledge gained will aid the wider application of this method.     

Investigation of immunogold-silver staining by electron microscopy

Summary Deposition of metallic silver on colloidal gold immunoreagents has been shown to be a very sensitive immunostaining technique capable of detecting low levels of immunoreactivity in tissue sections. Using electron microscopy we have shown that immunolabelling is highest with small sizes of gold which can penetrate sections better and achieve higher densities of particles in the section than larger particles. Chemical permeabilisation of the embedding medium aids the penetration of colloidal gold. The silver enhancement step in immunogold-silver staining was shown to be progressive, allowing optimisation of staining and the selection of the final size of silver deposits required. Some poorly understood features of the technique are rationalised and the additional knowledge gained will aid the wider application of this method.     

Silver enhancement of protein A-gold probes on resin-embedded ultrathin sections

Summary A simple method is described allowing the enhancement of the visibility of small gold probes for the electron microscopy.This method, which allows the silver intensification of gold directly on epon-embedded ultrathin sections, was used for the electron microscopic localization of Mouse Mammary Tumor Virus (MMTV) antigens in cultured cells derived from GR and BALB/cfRIII mouse mammary tumors. After the immunostaining with the preembedding protein A-gold technique, the ultrathin sections, placed on 200 mesh copper grids, were rehydrated and exposed to a photographic developer containing silver nitrate. During this physical development gold particles are incapsulated in growing shells of metallic silver, which gradually become more and more visible. We were able to obtain a heavy labelling of the viral particles, well visible even at low magmfication, with a negligeable background staining.The present technique can be useful whenever it is necessary to use the smallest gold probes today available.Supported by contract No. 85.02038.44 from the National Research Council, Rome, Progetto Finalizzato Oncologia     

Nonlinear vibrational microscopy applied to lipid biology

Optical microscopy is an indispensable tool that is driving progress in cell biology. It still is the only practical means of obtaining spatial and temporal resolution within living cells and tissues. Most prominently, fluorescence microscopy based on dye-labeling or protein fusions with fluorescent tags is a highly sensitive and specific method of visualizing biomolecules within sub-cellular structures. It is however severely limited by labeling artifacts, photo-bleaching and cytotoxicity of the labels. Coherent Raman Scattering (CRS) has emerged in the last decade as a new multiphoton microscopy technique suited for imaging unlabeled living cells in real time with high three-dimensional spatial resolution and chemical specificity. This technique has proven to be particularly successful in imaging unstained lipids from artificial membrane model systems, to living cells and tissues to whole organisms. In this article, we will review the experimental implementations of CRS microscopy and their application to imaging lipids. We will cover the theoretical background of linear and non-linear vibrational micro-spectroscopy necessary for the understanding of CRS microscopy. The different experimental implementations of CRS will be compared in terms of sensitivity limits and excitation and detection methods. Finally, we will provide an overview of the applications of CRS microscopy to lipid biology.     

β-amylase in developing apple fruits: activities, amounts and subcellular localization

Starch degradation in cells is closely associated with cereal seed germination, photosynthesis in leaves, carbohydrate storage in tuberous roots, and fleshy fruit development. Based on previously reported in vitro assays, β-amylase is considered one of the key enzymes catalyzing starch breakdown, but up to date its role in starch breakdown in living cells remains unclear because the enzyme was shown often extrachloroplastic in living cells. The present experiment showed that β-amylase activity was progressively increasing concomitantly with decreasing starch concentrations during apple (Malus domestica Borkh cv. Starkrimson) fruit development. The apparent amount of β-amylase assessed by Western blotting also increased during the fruit development, which is consistent with the seasonal changes in the enzyme activity. The subcellular-localization studies via immunogold electron-microscopy technique showed that β-amylase visualized by gold particles was predominantly located in plastids especially at periphery of starch granules, but the gold particles were scarcely found in other subcellular compartments. These data proved for the first time that the enzyme is compartmented in its functional sites in plant living cells. The predominantly plastid-distributed pattern of β-amylase in cells was shown unchanged throughout the fruit development. The density of gold particles (β-amylase) in plastids was increasing during the fruit development, which is consistent with the results of Western blotting. So it is considered that β-amylase is involved in starch hydrolysis in plastids of the fruit cells.     

β-Amylase Is Predominantly Localized to Plastids in the Developing Tuberous Root of Sweet Potato

Starch degradation in cells is closely associated with cereal seed germination, photosynthesis in leaves, carbohydrate storage in tuber and tuberous roots, and fleshy fruit development. Based on previously reported in vitro assays, β amylase is considered as one of the key enzymes catalyzing starch breakdown, but up to date its role in starch breakdown in living cells remains unclear because the enzyme was shown often extrachloroplastic in living cells. Recently we have shown for the first time that β-amylase is predominantly immuno-localized to plastids in living cells of developing apple fruit. But it remains to know whether this model of β-amylase compartmentation is more widespread in plant living cells. The present experiment, conducted in tuberous root of sweet potato (Ipomea batatas Lam. cv. Xushu 18) and via immunogold electron-microscopy technique, showed that β amylase visualized by gold particles was predominantly localized in plastids especially at periphery of starch granules, but the gold particles were scarcely found in other subcellular compartments, indicating that the enzyme is subcellularly compartmented in the same zone as its starch substrates. The density of gold particles (β amylase) in plastids was increasing during growing season, but the predominantly plastid-distributed pattern of β amylase in cells was shown unchanged throughout the tuberous root development. These data prove that the enzyme is compartmented in its functional sites, and so provide evidence to support the possible widespread biological function of the enzyme in catalyzing starch breakdown in plant living cells or at least in living cells of plant storage organs.     

Alcohol abuse-related mesangial glomerulonephritis: immunoelectron microscopy

Immunoelectron microscopy, using post-embedding immunohistochemistry with colloidal gold, was performed on renal samples from forensic autopsies. We confirmed that electron-dense deposits seen in alcohol abuse-related mesangial nephritis correspond to immunoglobulins, as has been shown previously by others in idiopathic cases. We investigated seven control samples and 13 specimens from individuals with evidence of alcohol abuse, six of whom had mesangial nephritis with IgA deposition. We found concentration of the gold particles over large electron-dense deposits in four of six cases of mesangial nephritis, confirming that they correspond to the IgA shown by immunofluorescence. Furthermore, a similar concentration of gold particles was not observed in control cases or in alcoholics without mesangial glomerulonephritis (4/6 vs 0/14; p = 0.005). IgM, seen as small aggregates, was confirmed in only two of six of the same cases. This is the first time that immunoelectron microscopy is performed on tissues obtained post mortem.     

Comparison of the pattern of expression of Leu-M1 antigen in adenocarcinomas,neutrophils and Hodgkin's disease by immunoelectron microscopy

The mouse monoclonal antibody anti-Leu-M1 (CD15) recognizes the carbohydrate determinant lacto-N-fucopentaose III, an oligosaccharide believed to be involved in cell-cell interactions. Anti-Leu-M1 is used in surgical pathology as an aid in the diagnosis of Hodgkin's disease. Additionally, adenocarcinomas derived from various organs stained positively with anti-Leu-M1 at the light microscopic level. Since mesotheliomas do not display positive reactivity to this antibody, Leu-M1 is clinically useful as part of a panel of antibodies in distinguishing adenocarcinomas from mesotheliomas. Previous work was carried out using post-embedding protein A-gold immunocytochemistry on thin sections embedded in Lowicryl K4M from a patient with Hodgkin's disease of the nodular sclerosing type; intense and precise labeling by gold particles was revealed in cytoplasmic granules, which were often clustered in a perinuclear location, in the Golgi apparatus, and focally along the plasma membrane of Reed-Sternberg cells. Moreover, polymorphonuclear leukocytes demonstrated similar labelling along the plasma membrane and over cytoplasmic granules. To define precisely the intracellular localization of Leu-M1 in human adenocarcinomas, we have performed post-embedding immunoelectron microscopy with the protein A-gold technique on sections embedded in Lowicryl K4M from neoplasms of the lung, stomach, colon, and breast. The pattern of labeling by gold particles indicative of Leu-M1 binding varied in adenocarcinomas of the different organs.     

Applications of immunocolloids in light microscopy. II. Demonstration of lectin-binding sites in paraffin sections by the use of lectin-gold or glycoprotein-gold complexes

A new procedure is presented for the light microscopic demonstration of specific sugar sequences of oligosaccharides in glycoconjugates by lectins combined with the colloidal gold marker system. Tissue sections from aldehyde-fixed and paraffin embedded rat kidney were stained either in a one-step method with lectin directly bound to particles of colloidal gold or in a two-step method using non-labeled lectin and glycoprotein labeled with colloidal gold. In both methods the presence of lectin-binding sites in the tissue sections is revealed by the appearance of a red coloration that is due to the accumulation of gold particles. The high specificity of the technique is combined with a good sensitivity and resolution as demonstrated by a differential plasma membrane staining in renal epithelial cells. The lectin-gold or glycoprotein-gold complexes remain stable for months and produce a permanent nonbleaching staining.     

Soft x-ray microscopy

Soft x-ray microscopes are beginning to provide information to complement that obtained from optical and electron microscopy. Soft x-ray microscopy can deliver 30-nm resolution images of hydrated cells up to approximately 10 microns thick, and efforts towards obtaining higher resolution are under way. Although living specimens cannot be studied readily except in single exposures, fixed samples can be imaged at high resolution, and flash-frozen specimens can be studied without chemical modification and without significant radiation damage. Tomography is being developed for 3-D imaging, and spectromicroscopy offers unique capabilities for biochemical mapping of unlabelled structures beyond those of gold and fluorescent labels. Currently, most soft x-ray microscopes operate at synchrotron radiation facilities, but laboratory-scale microscopes are being developed too.     

β-amylase in developing apple fruits: activities, amounts and subcellular localization

Starch degradation in cells is closely associated with cereal seed germination, photosynthesis in leaves, carbohydrate storage in tuberous roots, and fleshy fruit development. Based on previously reported in vitro assays, β-amylase is considered one of the key enzymes catalyzing starch breakdown, but up to date its role in starch breakdown in living cells remains unclear because the enzyme was shown often extrachloroplastic in living cells. The present experiment showed that β-amylase activity was progressively increasing concomitantly with decreasing starch concentrations during apple (Malus domestica Borkh cv. Starkrimson) fruit development. The apparent amount of β-amylase assessed by Western blotting also increased during the fruit development, which is consistent with the seasonal changes in the enzyme activity. The subcellular-localization studies via immunogold electron-microscopy technique showed that β-amylase visualized by gold particles was predominantly located in plastids especially at periphery of starch granules, but the gold particles were scarcely found in other subcellular compartments. These data proved for the first time that the enzyme is compartmented in its functional sites in plant living cells. The predominantly plastid-distributed pattern of β-amylase in cells was shown unchanged throughout the fruit development. The density of gold particles (β-amylase) in plastids was increasing during the fruit development, which is consistent with the results of Western blotting. So it is considered that β-amylase is involved in starch hydrolysis in plastids of the fruit cells.