Presidential address. The role of neuronal golgi apparatus in a centripetal membrane vesicular traffic

Endocytosis of horseradish peroxidase-poly-lysine conjugate by glomerular epithelial cells: an in vivo study

Native horseradish peroxidase (HRP) is known to pass rapidly through glomeruli when injected into rats. We have found that a conjugate of HRP with poly-lysine is readily endocytosed by glomerular epithelial cells (GEC). We have used this conjugate to study the GEC endocytotic process in male Wistar rats. The conjugate has an approximate molecular weight of 55-58,000, a pI of greater than 10.0, and almost the same secondary conformation as HRP; it does not increase urinary protein excretion significantly or alter the morphology of the renal glomeruli. After intravenous injection of the conjugate, it could be found in the GBM from 1 min to 4 h. At 1 min, it was evenly distributed on GEC foot processes and plasma membrane. GEC start to take up the conjugate from 1 min post-injection, by cellular membrane invagination. This reached a maximum at 4 h. Some of the endocytosed conjugate passed to lysosomes from the endosomal system. The amount of peroxidase demonstrable in the glomerular epithelial cells was considerably reduced by 24 h.

Transcytotic pathway for blood-borne protein through the blood-brain barrier

The transcytosis of blood-borne protein through the blood-brain barrier, a consequence of recruitment of the Golgi complex within nonfenestrated cerebral endothelia, was identified in mice and rats injected intravenously with the lectin wheat germ agglutinin (WGA) conjugated to the enzymatic tracer horseradish peroxidase (HRP). WGA enters cells by adsorptive endocytosis after binding to specific cell surface oligosaccharides. Blood-borne WGA-HRP labeled the entire cerebrovascular tree from the luminal side 5 min after injection; pericytes, located on the abluminal surface of cerebral endothelia, sequestered the lectin conjugate 6 hr later. Endothelial organelles harboring WGA-HRP 3 hr after injection included the luminal plasmalemma, endocytic vesicles, endosomes (prelysosomes), secondary lysosomes, and the Golgi complex. The peroxidase reaction product labeled the abluminal surface of cerebral endothelia and occupied the perivascular clefts by 6 hr. Within 12 hr, organelles labeled with WGA-HRP in pericytes were identical to those observed in endothelia. Blood-borne native HRP, entering cells by bulk-phase endocytosis, was neither directed to the Golgi complex nor transferred across nonfenestrated cerebral endothelia. The results suggest that blood-borne molecules taken into the cerebral endothelium by adsorptive endocytosis and conveyed to the Golgi complex can, either by themselves or as vehicles for other molecules excluded from the brain, undergo transcytosis through the blood-brain barrier without compromising the integrity of the barrier.

Quantitative ultrastructural, autoradiographic evidence for the magnitude and early involvement of the Golgi apparatus complex in the endocytosis of wheat germ agglutinin by cultured neuroblastoma

Several ligands undergo endocytosis into the Golgi apparatus. We have examined with a quantitative ultrastructural, autoradiographic method the sequential endocytosis of tritiated wheat germ agglutinin (3H-WGA) by cultured murine neuroblastoma cells. Cells were incubated with 3H-WGA for 1 hour at 4 degrees C, washed, and incubated in complete medium without ligand at 37 degrees C for 5, 15, 30, and 120 minutes. At 5 minutes, the optimized sources/micron 2 of neuroblastoma cell area, which represented the grain density of each compartment, were as follows: smooth vesicles and tubules, 1.03 +/- 0.88; Golgi-associated vesicles, i.e., clusters of vesicles within a 1 micron radius of the Golgi cisterns, 1.03 +/- 0.31; Golgi cisterns, less than 0.01; and lysosomes, 0.26 +/- 0.16. At 15 minutes grain densities were: smooth vesicles and tubules, 0.9 +/- 0.34; Golgi-associated vesicles, 1.41 +/- 0.28; Golgi cisterns, 0.73 +/- 0.41; and lysosomes, 0.1 +/- 0.09. At 30 minutes grain densities were: smooth vesicles and tubules, 0.46 +/- 0.46; Golgi-associated vesicles, 1.78 +/- 0.34; Golgi cisterns, 0.89 +/- 0.78; and lysosomes, 0.39 +/- 0.14. At 2 hours, smooth vesicles, tubules, and Golgi cisterns were not labeled, Golgi-associated vesicles were still labeled (0.71 +/- 0.1), and lysosomes were heavily labeled (2.17 +/- 0.22). These results are consistent with the hypotheses that either the Golgi complex (cisterns and associated vesicles) is an early and intermediate step of the endocytosis of 3H-WGA into lysosomes or that it constitutes part of a separate and quantitatively significant pathway of endocytosis of this ligand.

High and low molecular weight tracers for the electron microscopical detection of sialoglycoconjugates

Hydrazide-derivative tracers of different molecular weights have been synthesized for use in the electron microscopical detection of sodium periodate-oxidized sialyl residues of glycoconjugates in various tissues and cells. Haemundecapeptide hydrazide, horseradish peroxidase hydrazide, and Limulus polyphemus haemocyanin hydrazide were obtained by coupling adipic acid dihydrazide to the tracers with the aid of water-soluble carbodiimide. The enzymatic tracers thus prepared retained their peroxidatic activity. On conversion to the hydrazide derivative, the haemocyanin molecule dissociated into its hexameric subunits. In order to test by transmission electron microscopy the ability of the conjugates to bind to the sialoglycoconjugates of endothelial cell surfaces, each tracer was perfused in situ into rat pancreatic vasculature previously oxidized with 1 mM sodium periodate. The three tracers characteristically labelled the various microdomains of the luminal cell coat of the capillary endothelial cell. The electron opacity of the haemocyanin subunits allowed their easy detection when bound to the cell surface or to components of the extracellular matrix. The bound markers were not displaced by a high ionic strength buffer, and did not label desialylated cell surfaces. These results indicate that the three hydrazide-derivative tracers may be useful tools for the electron microscopical detection of cellular and extracellular sialoglycoconjugates.

Endocytic and exocytic pathways of the neuronal secretory process and trans-synaptic transfer of wheat germ agglutinin-horseradish peroxidase in vivo

The lectin wheat germ agglutinin (WGA) conjugated to horseradish peroxidase (HRP) was employed to study the endocytic and exocytic pathways of the secretory process in neurons and the potential for trans-synaptic transfer of molecules within the CNS. WGA-HRP binds to surface membrane oligosaccharides and enters cells by adsorptive endocytosis. The lectin conjugate was administered intranasally or into the cerebral ventricles of mice; postinjection survival times ranged from 5 minutes to 6 days. Due to binding of the lectin to ependymal cells subsequent to an intraventricular injection, only select populations of neurons (i.e., hippocampal formation; paraventricular nuclei; midbrain raphe; VI, X, XII motor nuclei; among others) were exposed extracellularly to WGA-HRP and became labeled by retrograde axoplasmic transport from axon terminals or by direct cell body/dendritic uptake. WGA-HRP delivered intranasally was endocytosed by first-order olfactory neurons and transported by anterograde axoplasmic flow to the terminal field within the glomerular layer of the main olfactory bulb; eventually perikarya of the mitral cell layer were labeled, presumably by anterograde trans-synaptic transfer of the lectin conjugate. In the variety of neurons analyzed ultrastructurally following exposure to WGA-HRP, the proposed sequence of intracellular pathways through which peroxidase reaction product was traced over time was: cell surface membrane----endocytic structures----endosomes (presecondary lysosomes)----transfer vesicles----transmost Golgi saccule----vesicles, vacuoles, and/or dense core granules. WGA-HRP also labeled vesicles and tubules that were channeled to and/or derived from spherical endosomes, dense bodies, and multivesicular bodies. The peroxidase-positive, membrane-delimited products of the trans Golgi saccule contributed to anterograde axonal transport vectors and accumulated within axon terminals. A second contribution to these vectors was provided by peroxidase-labeled tubules and dense bodies believed to represent components of the lysosomal compartment. Profiles of the axonal reticulum comparable to those that stained cytochemically for glucose-6-phosphatase activity, a marker for the endoplasmic reticulum, were not associated with the transport of WGA-HRP. Trans-synaptic transfer of WGA-HRP from primary olfactory neurons to postsynaptic cells in the olfactory bulb was reflected in peroxidase-positive endocytic vesicles, endosomes, dense bodies, and the trans Golgi saccule.(ABSTRACT TRUNCATED AT 400 WORDS)

Transneuronal transport of lectins

Axonal and transneuronal transport of the plant lectins wheat germ agglutinin (WGA), Pisum sativum agglutinin (PSA), Lens culinaris agglutinin (LCA), soybean agglutinin (SBA), peanut agglutinin (PNA), Concanavalin A agglutinin (Con A), and Ulex europeus agglutinin (UEA) were examined and compared using an immunocytochemical staining method. WGA, which binds to N-acetylglucosamine and sialic acid carbohydrate residues, and the 3 mannose binding lectins (Con A, PSA and LCA) were found to undergo retrograde transport to the facial nucleus after injection into the facial muscles, and anterograde transport to the optic tectum after injection in the vitreous, and to the spinal trigeminal nucleus caudalis after injection into the mystatial vibrissae. SBA showed a slight tendency to be transported retrogradely, but not in the anterograde direction, whereas UEA and PNA were not axonally transported in any of these systems. All lectins which were transported in the anterograde direction labeled neuronal somata in their respective terminal fields indicating that transneuronal transport had taken place. Axonal and transneuronal transport of the lectins appears to be dependent upon their respective carbohydrate affinities. Transneuronal transport which can be demonstrated for certain lectins indicates that mechanisms exist whereby neurons exchange large molecules which could be involved in mediating trophic and other influences on target cells.

Isolation and characterization of an enriched Golgi fraction from neurons of developing rat brains

We report a method for the isolation of enriched fractions of intact Golgi apparatus from neurons of 10- to 12-day-old rat brains. Neurons were prepared according to a modified method of Farooq and Norton [J. Neurochem. 31, 887-894 (1978)]. Golgi-enriched fractions were obtained after centrifugation of postmitochondrial supernatants in a discontinuous sucrose gradient. Golgi fractions 1 and 2, recovered at the interfaces of 28-34% and 34-36% sucrose densities, respectively, were examined with morphometric and enzymatic methods. Morphometric analyses showed that 21-34% of fraction 1 and 11-29% of fraction 2 consisted of intact Golgi apparatus. Lysosomes, mitochondria, ribosomes, and rough endoplasmic reticulum contaminated fraction 1 (6-10%) and fraction 2 (14-26%). Golgi fraction 1 showed a 25- to 65-fold enrichment over neurons of UDP Gal:GlcNAc galactosyltransferase, CMP-sialic acid:lactosylceramide sialyltransferase, and PAPS:cerebroside sulfotransferase activities. Golgi fraction 2 showed a 8- to 23-fold enrichment over neurons of the activities of the above glycolipid- and glycoprotein-synthesizing enzymes. The activities of the possible marker enzymes rotenone-insensitive NADH-cytochrome c reductase, succinate-cytochrome c reductase, and arylsulfatase were low or minimally elevated in the Golgi fractions. A sevenfold enrichment of Na+, K+-ATPase activities was found in the Golgi fractions. This is consistent either with significant plasma membrane contamination or with the presence of this enzyme in the neuronal Golgi apparatus.

Endocytosis of nerve growth factor by 'differentiated' PC12 cells studied by quantitative ultrastructural autoradiography

The endocytosis of [125I]nerve growth factor (NGF) by rat pheochromocytoma cells (PC12 line), previously exposed to the growth factor ('differentiated' or 'primed' cells), was studied by ultrastructural quantitative autoradiography. Cells previously grown in the presence of NGF were incubated at 37 degrees C with [125I]NGF for periods of up to 24 h. Under these culture conditions, PC12 cells have a rich network of neurites. At the commencement of the experiment, after incubation of cells with [125I]NGF for 1 min at room temperature, the plasma membranes of perikarya and processes showed similar levels of labeling by [125I]NGF of 0.186 +/- 0.03 grains/micron and 0.152 +/- 0.013 grains/micron respectively. The density of grains per micron of plasma membrane of perikarya reached a plateau between 15 min to 2 h of incubation of cells at 37 degrees C with [125I]NGF (0.58 +/- 0.15 grains/micron and 0.65 +/- 0.18 grains/micron, respectively). The endocytosis of [125I]NGF in perikarya of cells incubated for 6 h at 37 degrees C was studied by the 'mask' analysis method of Salpeter et al.22. At this time, the greatest amount of endocytosis was observed, corresponding to 28.4% of total grain counts. The following optimized computed source densities, or relative specific activities +/- standard errors of measurement (S.E.M.), were obtained: plasma membrane, 16.52 +/- 0.86; multivesicular bodies, 9.58 +/- 2.84; endosomes, 5.00 +/- 0.97; smooth vesicles and tubules, 1.66 +/- 0.38; lysosomes, 1.13 +/- 0.20; mitochondria, 0.46 +/- 0.10; nuclear membranes or envelopes, 0.32 +/- 0.14; nuclei, 0.06 +/- 0.01; the Golgi apparatus, 0.08 +/- 0.06; and other cytoplasmic elements 0.07 +/- 0.03. Our findings indicate that smooth vesicles and tubules, endosomes, multivesicular bodies and lysosomes are part of the pathway(s) of endocytosis of NGF, while all other cytoplasmic and nuclear elements, including the nuclear membrane, are not. The heavy plasma membrane labeling of NGF and the relatively low degree of its endocytosis are consistent with the hypothesis that the NGF action is mediated through plasma membrane activated second messenger(s).

Differences between the endocytosis of horseradish peroxidase and its conjugate with wheat germ agglutinin by cultured fibroblasts

A covalent conjugate of wheat germ agglutinin (WGA) with horseradish peroxidase (HRP) was used for a morphologic study of its adsorptive endocytosis by cultured human fibroblasts. Initial binding at 4 degrees C of the conjugate was observed over the entire plasma membrane, including "coated" and smooth pits. Endocytosis of HRP and the WGA-HRP conjugate was observed in lysosomes, but only the conjugate was seen in a cisterna of the Golgi apparatus (GERL), and in adjacent coated vesicles.

Horseradish peroxidase: a tool for study of the neuroendocrine cell and other peptide-secreting cells

The versatility of horseradish peroxidase is its usefulness both as an antigenic marker and as a probe molecule. We have demonstrated in the neuroendocrine cell that an HRP-bound antibody offers a high order of resolution for determining in which cellular compartment an antigen is located and where it is not. When native peroxidase is applied as an intracellular probe, it labels organelles associated with endocytosis in retrograde axonal transport and with the lysosomal system in both retrograde and orthograde axonal transport. The investigation that remains is the application of lectin-bound HRP to determine the pathways of membrane flow at the time when the neuroendocrine cell is stimulated to synthesize, transport, and secrete its peptide. For example, we are interested to know (1) whether internalized axon terminal membrane tagged with wheat germ agglutinin-HRP is channeled to all Golgi saccules engaged in the production of secretory granules in salt stimulated supraoptic neurons; and (2) if internalized cell membrane of the supraoptic cell body is tagged with wheat germ agglutinin-HRP and channeled to GERL, will this membrane be transferred from GERL to secretory granules, lysosomes in the cell body and axon, the axonal endoplasmic reticulum, and to autophagic/crinophagic vacuoles in axon terminals of salt-stressed supraoptic neurons? These additional studies should provide a more comprehensive, morphological picture of membrane flow in a neuroendocrine cell that is responding to the metabolic demands placed upon it.

Intracellular membrane traffic: pathways, carriers, and sorting devices

Multiple pathways of intracellular membrane traffic have been detected in various cell types. The major established routes are (a) the exocytosis pathway, utilized in secretory cells for the discharge of secretory products, and which is also believed to be used for delivery of intrinsic membrane glycoproteins in all cell types; (b) the plasmalemma to Golgi route, also highly developed in secretory cells, which is believed to be utilized for the recovery and recycling of the membranes of containers used in packaging of secretory products (i.e., secretory granules or vesicles); (c) the lysosomal pathway, which is available in all cells but is the major route utilized in phagocytic cells; (d) the transcellular route, which represents the major type of traffic encountered in nonfenestrated, capillary endothelial cells and also appears to be the preferred route for the transport of immunoglobulins (intact) across cells; and (e) the biosynthetic pathways used for transport of secretory products, lysosomal enzymes, and membrane proteins from the ER to the Golgi complex and for transport of lysosomal enzymes from the Golgi complex to lysosomes in all cell types. It has become clear that cells repeatedly reutilize or recycle the vesicular membranes involved in carrying out these various transport operations. Clathrin-coated vesicles have been found to be involved in transport along all the routes detected so far, suggesting that there are multiple populations of coated vesicles with different transport functions in every cell. It has become clear that considerable sorting of membrane constituents and ligands takes place at the plasmalemma (receptor-mediated uptake), in the Golgi complex, and in endosomes. The Golgi complex is the intracellular site where much of the biosynthetic and recycling membrane traffic converges and where products are sorted and directed to their correct destinations. In summary, we have become aware of the existence of multiple pathways of membrane traffic and of the extensive reutilization or recycling of membranes that occurs in cells. The basic pathways are similar in all cells except that some are emphasized or deemphasized according to the predominant function and organization of a given cell type. What now remains to be done is to determine how these transporting membranes and the membranes of the receiving compartments are constructed, how their specific interactions are controlled, and how individual cell types utilize these pathways to carry out their specific functions.(ABSTRACT TRUNCATED AT 400 WORDS)