Isolation of a domain of the plasma membrane in Chinese hamster ovary cells which contains iodinatable, acidic glycoproteins of high molecular weight

Biogenesis of Exosomes Laden with Metallic Silver-Copper Nanoparticles Liaised by Wheat Germ Agglutinin for Targeted Delivery of Therapeutics to Breast Cancer

The anticancer property of silver-copper metallic nanoparticles (AgCu-NPs) is of greater interest in cancer therapeutics; however, its off-target toxicity limits its therapeutic application. Exosomes emerge as one of the leading idiosyncratic nanocarrier choices for cancer therapeutics due to their size, stability, and phenotypic diversity; however, to encapsulate NPs in extracellular vesicles (EVs) without disrupting their inherited functions is far from the expectations. Here, the loading strategy of AgCu-NP conjugated with wheat germ agglutinin (AgCu-NP-WGA) in exosomes during biogenesis for the targeted delivery of anticancer therapeutics to breast cancer is reported. Based on the intrinsic mechanism of endocytosis of WGA, results show that internalization of WGA or AgCu-NP-WGA bypasses the lysosomal pathway and recycles in EVs. On the contrary, the transport of naked AgCu-NPs to lysosomes; mechanistically, an acidic environment causes oxidation of AgCu-NP. Next, the analysis of EVs harvested by differential centrifugation shows that only AgCu-NPs-WGA (Exo-NP) retain their metallic state. Furthermore, Exo-NP cytotoxicity results manifest that MCF10A-derived Exo-NPs are toxic to its homologous breast cancer cells (MCF-7 and MDA-MB 231) and nontoxic to heterologous cancers NC1-1975 and MCF 10A. In conclusion, this study shows the self-assembly of AgCu-NP in exosomes to target and deliver therapeutics for breast cancer.

Rapid endocytosis and recycling of wheat germ agglutinin binding sites on CHO cells: evidence for two compartments in a nondegradative pathway

The internalization and recycling of CHO cell plasma membrane components have been quantified by using iodinated wheat germ agglutinin (WGA) as an adsorptive tracer. Most of these binding sites are thought to be composed of a subpopulation of plasma membrane proteins called high-molecular-weight acidic glycoproteins (HMWAG). Greater than 90% of the WGA bound on the cell surface can be removed by brief treatment with N-acetylglucosamine (GlcNAc). At 37 degrees C, endocytosis of WGA that had been allowed to bind to the surface at 4 degrees C is curvilinear with an initial rapid phase occurring with a t1/2 of 6-8 min. Within 20 min, accumulation has slowed gradually to steady-state with 65% of the cell-associated WGA located intracellularly or resistant to removal by GlcNAc. These portions are unaffected by increasing the extracellular concentration of WGA from 0.003 microM to 2.8 microM. By using pulse-chase experiments, the observed decrease in rate of endocytosis is shown to be due to return of the WGA-HMWAG complexes to the cell surface. More than 60% of the WGA that had been internalized is recycled within 30 min, with a mean t1/2 of 17 min. Recycling involved at least two intracellular populations where a significant fraction (less than 30%) of the WGA-HMWAG complexes are lost gradually from the rapidly recycling pool. Most of the WGA-HMWAG complexes that had internalized are not delivered to the lysosome. These results demonstrate the magnitude of rapid and continuous recycling of WGA binding sites between the cell surface and endosomes in fibroblasts.

Endocytosis of wheat germ agglutinin binding sites from the cell surface into a tubular endosomal network

By using fluorescence and electron microscopy, the endocytic pathway encountered by cell surface components after they had bound wheat germ agglutinin (WGA) was visualized. The majority of these components are thought to consist of sialylated glycoproteins (HMWAG) that represent a subpopulation of the total cell surface proteins but most of the externally disposed plasma membrane proteins of the cell. Examination of semi-thin sections by medium- and high-voltage electron microscopy revealed the three-dimensional organization of vesicular and tubular endosomes. Binding of either fluorescein isothiocyanate-, horseradish peroxidase-, or ferritin-conjugated WGA to cells at 4 degrees C showed that the HMWAG were distributed uniformly over the cell surface. Warming of surface-labeled cells to 37 degrees C resulted in the endocytosis of WGA into peripheral endosomes via invagination of regions of both coated and uncoated membrane. The peripheral endosome appeared as isolated complexes comprising a vesicular element (300-400 nm diam.) surrounded by and continuous with tubular cisternae (45-60 nm diam.), which did not interconnect the endosomes. After 30 min or more label also became localized in a network of anastomosing tubules (45-60 nm diam.) that were located in the centrosomal region of the cell. Endocytosed WGA-HMWAG complexes did not become associated with cisternae of the Golgi apparatus, although tubular and vesicular endosomes were noted in the vicinity of the trans-Golgi region. The accumulation of WGA-HMWAG in the endosomes within the centrosomal region was inhibited when cells were incubated at 18 degrees C. None of these compartments contained acid phosphatase activity, a result that is consistent with other data that the HMWAG do not pass through lysosomes initially. The kinetics of labeling were consistent with the interpretation that recycling of most of the WGA binding surface glycoproteins occurred rapidly from early peripheral endosomes followed by the late trans-Golgi compartment. In conclusion, a portion of cell surface glycoproteins are routed to a complex arrangement of tubular and vesicular compartments following endocytosis that includes a putative post-endosomal, tubular reticulum that appears to be separate from the trans-most Golgi saccule.

Cell surface glycoproteins of CHO cells. II. Surface distribution and pathway of internalization

The surface distribution and pathway for internalization of the major cell surface proteins of Chinese hamster ovary (CHO) cells have been investigated after reacting cells at 4 degrees C with the membrane-impermeant reagent trinitrobenzenesulfonate. Molecules, haptenized with trinitrophenol groups, the majority of which are in a group of high molecular weight acidic glycoproteins (HMWAG), were labelled at 4 degrees C with anti-dinitrophenol immunoglobulins coupled to fluorescein isothiocyanate (FITC), horseradish peroxidase, or colloidal gold and either immediately fixed for mapping their distribution or followed intracellularly after warming to allow endocytosis to proceed. The distribution of label on the CHO cell surface was non-random with a large proportion arranged in clusters from 100 to 300 nm in diameter. Antibody label was concentrated heavily on microvilli, and about 10% of the molecules were always associated with clathrin-coated pits. Upon warming the cells to 37 degrees C, HMWAG were internalized immediately into smooth-membraned tubules (less than 80 nm luminal diameter) that appeared to connect with vesicles (less than 300 nm luminal diameter) located in the cortical cytoplasm. By 60 min, labelled antibody was located within larger vesicles (greater than 300 nm luminal diameter) that had a morphology characteristic of multivesicular bodies and not lysosomes. There was no evidence for entry of labelled molecules into either electron-dense, secondary lysosomes or into the Golgi cisternae, suggesting that neither compartment is involved in the major pathway of cell surface endocytosis. Our results are consistent with the view that the majority of plasma membrane protein are internalized as small discrete domains by a pathway very similar to that described by others for adsorptive endocytosis.

Cell surface glycoproteins of CHO cells. I. Internalization and rapid recycling

The major cell surface proteins of Chinese hamster ovary (CHO) cells have been investigated after reacting cells at 4 degrees C with the membrane-impermeant reagent, trinitrobenzenesulfonate (TNBS). Immunoprecipitation and subsequent two-dimensional, sodium-dodecyl sulfate, polyacrylamide gel electrophoresis (SDS-PAGE) of proteins from derivatized cells that had been labelled previously with [3H]D-glucosamine or [3H]L-leucine showed that TNBS reacted with most of the high molecular weight (HMW) acidic glycoproteins that became labelled with iodine by the lactoperoxidase technique and that bind the lectin, wheat germ agglutinin (WGA). After warming the cells to allow endocytosis to proceed, molecules haptenized with trinitrophenol (TNP) groups were followed radiochemically by means of [125I]anti-DNP antibodies. The half-life for internalization of proteins tagged with either [125I]anti-DNP IgG or Fab averaged about 5 min. A similar result was obtained when a monoclonal antibody directed against a single plasma membrane glycoprotein was used, or when the rate of surface loss of TNP groups unoccupied by antibodies was measured. Within 15 min at 37 degrees C, a steady-state between surface and cytoplasmic label was reached, with about 65% of the hapten located internally. Recycling of internalized TNP groups back to the cell surface also occurred rapidly (t 1/2 approximately 5 min). Most of the intracellular radioactivity was associated with a membrane fraction of density similar to that of the plasma membrane. Over a 4-h period, there was no significant entry of labeled molecules into lysosomes. By contrast, the fluid-phase marker, horseradish peroxidase, became associated with the lysosomes within 1 h. Our results are consistent with the view that the majority of plasma membrane glycoproteins are continuously being internalized and recycled at a high rate.

Cell surface properties of high- and low-metastatic cell lines selected from a spontaneous mouse lung carcinoma

The surface oligosaccharide residues, glycoproteins and sialyl components of CMT64 lung carcinoma cells and high-metastatic sublines CMT167 and CMT181 have been studied in culture. (1) The total cellular sialic acid content did not differ appreciably between the three lines. However, the accessibility of surface sialyl groups, measured by metabolic incorporation of [3H]NAcmannosamine followed by neuraminidase hydrolysis, was decreased from 42% in CMT64 to 25% hydrolyzed in CMT181. (2) The major plasma membrane glycoproteins of the lines were radiolabelled by lactoperoxidase iodination, metabolic incorporation of [3H]fucose or labelling in the terminal sialyl residues by the NaIO4-NaB[3H]4 method and the labelled glycoproteins were analyzed by two-dimensional gel electrophoresis. Each labelling technique identified a complex pattern of glycoproteins including a prominently labelled group of high-molecular-weight acidic sialoglycoproteins: GP200/4.9-5.1 (apparent molecular weight X 10(-3)/pl of iodoprotein); GP150/5.1-5.6; GP130/5.0-5.6; GP110/5.0; GP100/4.8 and GP100/5.0-5.4. (3) The neuraminidase-susceptible glycoproteins on CMT64 and CMT181 were identified in the isoelectric focusing separation of the two-dimensional gel separation by the charge difference caused by desialylation. The glycoproteins most susceptible to neuraminidase were the high-molecular-weight acidic glycoproteins which showed marked charge heterogeneity: GP150/5.1-5.6, GP130/5.0-5.6; GP100/5.0-5.4 and GP100/4.8. (4) Using these procedures we did not detect modifications between CMT181 and CMT64 and we conclude that the cultured cells of the sublines do not display marked surface glycoprotein alterations that reflect their enhanced spontaneous metastatic potential.