Experimental mucopolysaccharidosis: Preservation and ultrastructural visualization of intralysosomal glycosaminoglycans by use of the cationic dyes cuprolinic blue and toluidine blue

Summary The cationic dyes Cuprolinic Blue (CB) and Toluidine Blue (TB) were used to preserve the intralysosomal storage material accumulating in tilorone-induced mucopolysaccharidosis. As shown in previous studies, the stored glycosaminoglycans (GAGs) are leached during the conventional fixation procedure, with the result that the lysosomes appear empty. In the present study, the liver, spleen, and cornea-conjunctiva of tilorone-treated rats were examined. The application of CB in the presence of 0.1 M or 0.3 M MgCl₂ simultaneously with, or subsequently to the primary fixative yielded electron-dense precipitates within the storage lysosomes. When TB (0.1%) was added to the primary fixative, the storage lysosomes contained filamentous structures arranged in reticular patterns. With increasing TB concentrations (up to 1%) the lysosomes increasingly often showed apparently amorphous storage material which was continuous with the reticular filamentous structures. Similar ultrastructural patterns were obtained with GAG-TB complexes prepared in vitro. The intralysosomal storage material preserved by TB is interpreted as GAG-TB precipitates. In conclusion, the use of CB provides a method which allows direct cytochemical demonstration of the subcellular sites of GAG-storage. The use of TB represents an easy method to obtain electron micrographs pathognomonic of the mucopolysaccharidosis induced by tilorone and congeners. Either method may be helpful to detect this adverse drug effect at the subcellular level.     

Ultrastructure of proteoglycans in the specific granules of guinea-pig basophilic leukocytes as demonstrated by cuprolinic blue staining

The ultrastructure of sulphate proteoglycans in basophil granules was examined using cytochemical procedures designed to stabilize and visualize these highly anionic macromolecules in situ. Unfixed or glutaraldehyde-prefixed guinea-pig spleen cells were submitted to fixation/staining in 2.5% glutaraldehyde, 0.2% cuprolinic blue (CB; a cationic phthalocyanin dye) and 0.2 or 0.3M MgCl₂ with or without glycosidase treatments. Abundant electron-dense precipitates were present throughout the granule matrix. The stained structures were often arranged in a quasi-crystalline typical banded pattern. Negative control basophils had no electrondense precipitates. Digestion with chondroitinase ABC destroyed the CB-positive electron-dense banded or filamentous patterns while sialidase treatment did not, but led to larger CB-positive filaments in the cytoplasm near the granules. Taking into account their high anionicity, as shown by the stability of dye binding in the presence of 0.3M MgCl₂, and their susceptibility to chondroitinase ABC, the CB-precipitates are assumed to be related to the sulphated proteoglycans previously characterized in basophil granules. The CB-positive crystalline or filamentous network of the granule matrix is also assumed to reflect the in situ location and organization of these intracellular proteoglycans and may be involved in maintaining the shape of the granule.     

Acridine Orange, a precipitant for sulfated glycosaminoglycans, causes mucopolysaccharidosis in cultured fibroblasts

The purpose of the present investigation was to examine whether or not a di-cationic amphiphilic compound that is known (1) to be accumulated in lysosomes and (2) to form insoluble complexes with sulfated glycosaminoglycans (sGAG) in vitro, is able to interfere with the lysosomal degradation of sGAG, thus causing mucopolysaccharidosis (MPS) in cultured cells. Acridine Orange (AO) was chosen for this study since it is known to meet the above requirements. Cultured fibroblasts from rat cornea were exposed to AO (0.7 microM to 30 microM) for 72 h; tilorone served as reference compound. AO (1.75 microM to 10 microM) caused MPS in a concentration-dependent manner, higher concentrations were cytotoxic. MPS was demonstrated by cytochemical staining with cuprolinic blue and by measuring the intracellular accumulation of [35S]-GAG. The sGAG-complexing properties of AO were demonstrated by using it as a fixative for the intralysosomal sGAG accumulated in tilorone-treated cells. The present findings give support to the working hypothesis that the MPS induced by di-cationic amphiphilic drugs is due to the formation of insoluble sGAG-drug complexes, with the result that the sGAG become resistant to lysosomal degradation.     

Metabolic turnover of methotrexate polyglutamates in lysosomes derived from S180 cells. Definition of a two-step process limited by mediated lysosomal permeation of polyglutamates and activating reduced sulfhydryl compounds.

Transport and metabolic turnover of methotrexate (MTX) polyglutamates were examined in lysosomes derived from S180 cells. These studies extend prior work from this laboratory (Barrueco, J. R., and Sirotnak, F. M. (1991) J. Biol. Chem 266, 11732-11737) which described basic properties of a facilitative transport system in lysosomes capable of mediating intralysosomal accumulation of MTX polyglutamates. In the present report, we show that the rate of turnover of MTX polyglutamates in lysosomes, which releases MTX in the extralysosomal space, is limited by the extent of mediated intralysosomal accumulation of the polyglutamate and reduced sulfhydryls that activate the enzyme folylpolyglutamate hydrolase. Evidence is presented that cysteine functions as the naturally occurring reduced sulfhydryl compound in lysosomes being equipotent to 2-mercaptoethanol as an activator of folylpolyglutamate hydrolase. Folylpolyglutamate hydrolase in permeabilized lysosomes from S180 cells exhibited a low pH optimum characteristic of a lysosomal enzyme, was activated at concentrations of reduced sulfhydryl at 0.1 mM and above, and exhibited Km values in the range of 0.2-3 microM that decreased with increase in polyglutamate chain length. Values for Km for MTX polyglutamates of folylpolyglutamate hydrolase activity were 100-200-fold lower than values for Km or Ki for facilitated intralysosomal transport, whereas capacities for both processes were similar. This relationship between the kinetic properties of each process ensures efficient hydrolysis of MTX polyglutamates within the lysosome.     

On the alcianophilia of the drug suramin used as a tool for inducing experimental mucopolysaccharidosis

Summary The trypanocidal drug suramin was previously reported to induce mucopolysaccharidosis in rats; apart from the biochemical demonstration of increased tissue concentrations of sulfated glycosaminoglycans (GAGs), a strongly positive staining reaction with the cationic dye Alcian Blue was taken as indicating GAG-storage (Constantopoulos et al. 1983). The purpose of the present report is to point out a methodical pitfall. In model experiments it was found that suramin itself, being a polysulfated compound, gives a strongly positive reaction with Alcian Blue pH 1. It is known that suramin is accumulated in the lysosomes and that high drug concentrations are retained in the tissues for weeks. Therefore a positive staining reaction with Alcian Blue observed in a given cell cannot be conclusively attributed to the storage of sulfated GAGs as has been done in the past. The present report may be a warning that, in the case of the suramin-induced animal model of mucopolysaccharidosis, the usual histochemical strategy, i.e. staining with cationic dyes, is not suitable for analysing the cellular distribution pattern of GAG-storage, since the inducing drug by itself reacts with the indicator dye.     

On the alcianophilia of the drug suramin used as a tool for inducing experimental mucopolysaccharidosis

The trypanocidal drug suramin was previously reported to induce mucopolysaccharidosis in rats; apart from the biochemical demonstration of increased tissue concentrations of sulfated glycosaminoglycans (GAGs), a strongly positive staining reaction with the cationic dye Alcian Blue was taken as indicating GAG-storage (Constantopoulos et al. 1983). The purpose of the present report is to point out a methodical pitfall. In model experiments it was found that suramin itself, being a polysulfated compound, gives a strongly positive reaction with Alcian Blue at pH 1. It is known that suramin is accumulated in the lysosomes and that high drug concentrations are retained in the tissues for weeks. Therefore a positive staining reaction with Alcian Blue observed in a given cell cannot be conclusively attributed to the storage of sulfated GAGs as has been done in the past. The present report may be a warning that, in the case of the suramin-induced animal model of mucopolysaccharidosis, the usual histochemical strategy, i.e. staining with cationic dyes, is not suitable for analysing the cellular distribution pattern of GAG-storage, since the inducing drug by itself reacts with the indicator dye.     

Intravital determination of pH gradient between the cytoplasm and lysosomes in human fibroblasts in the normal state and in hereditary storage diseases

Presented are the results of measurements of pH in cytoplasm and lysosomes of skin fibroblasts of healthy donors and patients with lysosomal storage diseases, mannosidosis, Fabry, Krabbe disease. The pH value was estimated in the stationary phase of growth using neutral red (lysosomes) and fluorescein diacetate (cytoplasm). It was shown that the cytoplasmic pH value in pathological cells didn't virtually differ from the control values. The intralysosomal pH value in fibroblasts of patients with mannosidosis and Fabry disease was essentially increased, which correlated with the size increase of these organelles upon the accumulation of unsplit compounds. This led to the decrease in pH gradient between the cytoplasm and lysosomes in the pathological cells, an increase in intralysosomal pH along with hereditary deficiency of enzymes could bring about the retardation of catabolic processes in lysosomes.     

Complications encountered using cibacron blue F3G-A as a ligand for affinity precipitation of lactate dehydrogenase

The use of the affinity interaction between Cibacron Blue F3G-A (CB) and NADH-dependent enzymes to selectively precipitate these enzymes has been examined. An attempt was made to form crosslinked precipitates of lactate dehydrogenase (LDH) using bis- and poly-CB conjugates. When precipitation was not observed, an examination of the interaction between the enzyme and the conjugated CB was made. Quasielastic light scattering indicated only a slight radius increase, the greatest being from 50 to 130 A, when a CB-dextran conjugate was added to a solution of LDH, and no increase when bis-CB made with a 1, 6-diaminohexane spacer was added to a similar solution. The results of enzyme inhibition studies showed that conjugated CB bound at the NAD(+) site of LDH. Spectral measurements of the conjugated CB below 5 muM were similar to those reported for a stacking interaction that occurs in solutions with CB concentrations above 5 muM We conclude that the conjugated CB is binding to the LDH, but that a competing dye stacking interaction prevents extensive cross-linking of the LDH, and thus inhibits precipitation.     

The effect of Triton WR-1339 on the subcellular distribution of Trypan Blue and 125I-labelled albumin in rat liver

1. The density-gradient distribution patterns of acid phosphatase, Trypan Blue and denatured (125)I-labelled albumin were studied by discontinuous sucrose- and isopycnic sucrose-density-gradient centrifugation on combined heavy and light mitochondrial (M+L) fractions of liver isolated from normal rats and from rats injected with Triton WR-1339. 2. The results obtained from the subfractionation of the M+L pellet of normal animals indicate that the equilibrium density of Trypan Blue and acid-insoluble radioactivity is the same as that for acid phosphatase, which suggests they are bound by a common membrane to form a distinct subcellular population of lysosomal nature. 3. In contrast, the analysis of the isopycnic gradients obtained on subfractionation of M+L pellets of liver isolated from rats treated with Triton WR-1339 show that the acid-insoluble radioactivity has an equilibrium density around 1.21, whereas the acid hydrolases, including cathepsin D, show the characteristic shift to an equilibrium density of around 1.12. Trypan Blue is distributed along the gradient with distinct peaks at densities 1.22 and 1.12. 4. Similar equilibrium-density distribution patterns were obtained with M+L pellets isolated from rats pretreated with Triton WR-1339 but not injected with Trypan Blue. 5. Treatment of the rats with Triton WR-1339 does not affect albumin digestion of isolated intact lysosomes despite the fact that most of the cathepsin D and the albumin ingested by phagocytosis are located in different vacuoles. 6. It is concluded from these experiments that in the liver of animals treated with Triton WR-1339 (125)I-labelled albumin is located within heterophagosomes which do not fuse with heterolysosomes containing the non-ionic detergent Triton WR-1339. The inability of these two lysosomal populations to fuse is not due to Trypan Blue.     

Role of lysosomes in gallium concentration by mammalian tissues

Two microanalytical methods, electron probe X ray analysis (E P M A) and ion mass analysis (I A M) were used to study gallium incorporation in normal tissues (kidney, liver, mammary gland, bone marrow, bone tissue) and in experimental tumors. The very high sensitivity of I M A makes possible the detection of very low concentration of gallium (1 ppm) with a spatial resolution of 0.5 micron, on the other hand, E P M A of lower sensitivity (100 ppm) makes possible the relation between the gallium concentration and the ultrastructure of the cell. It was shown that gallium is concentrated in the lysosomes of both types of tissues, where it is precipitated in an insoluble form. In addition, gallium is systematically combined with phosphorus in these precipitates. These observations suggest an active intralysosomal concentrating mechanism related to the presence of local phosphatase activity.     

Autophagy, heterophagy, microautophagy and crinophagy as the means for intracellular degradation

It is generally accepted that the lysosomal compartment plays an important role in the degradation of cellular components. In this communication we discuss various experimental models which have been used to study mechanisms of intralysosomal degradation and also discuss the evidence obtained in support of the following proposals: 1. The autophagosomes can be isolated into high purity and are the subcellular locus of induced protein degradation. 2. Different membrane components such as proteins and lipids are degraded at different rates inside the lysosomes. Intralysosomal hydrolysis is not the rate limiting step in degradation. 3. Lysosomes take up soluble material in vitro by invagination and pinching off of their membranes (microautophagy). 4. Secretory vesicles can degrade their secretory contents by fusing with the lysosomes.     

Histochemical demonstration of hyaluronic acid molecules by Alcian Blue

Summary Specimens of vitreous humour (monkey eye), Wharton jelly (human umbilical cord) and commercial hyaluronates were immersed in buffered fixative solutions containing either aldehydes and Alcian Blue, or aldehydes and Alcian Blue with MgCl₂ as electrolyte. Two MgCl₂ concentrations were used, 0.025m and 0.3m. Immersion in both solutions induced formation of precipitates which were postfixed in OsO₄, dehydrated and embedded for thin section electron microscopy. The use of the same fixative solution produced morphologically comparable precipitates from all three materials. The precipitates, especially after fixation in the presence of electrolyte, were composed of linear, unbranched filaments, frequently aggregated into bundles. The filaments were considered to be molecules of hyaluronic acid.Part of this work was presented at the 10th Meeting of the European Club for Ophthalmic Fine Structure, Copenhagen, September 3–4, 1982.     

An improved procedure for the histochemical demonstration of cathepsin D by the mercury-labeled pepstatin method

The desirable fixation conditions for the histochemical demonstration of cathepsin D using mercury-labeled pepstatin as an enzyme inhibitor were examined biochemically and histochemically. Four well known fixatives, namely, glutaraldehyde (GA), paraformaldehyde (PFA), glutaraldehyde with paraformaldehyde (GA-PFA) and periodate-lysine-paraformaldehyde (PLP), were applied to the prefixation of tissues prior to the reaction of the labeled inhibitor to the enzyme-active site. The effects of fixatives on cathepsin D were biochemically examined using subcellular fractionated lysosomes. Cathepsin D from rat liver lysosomes was rapidly inactivated by the fixatives containing glutaraldehyde, i.e., GA and GA-PFA, whereas the activity of cathepsin D was sufficiently maintained after fixing the enzyme in the PFA or PLP preparations. Effects of the PLP fixative on lysosomal cathepsin D in liver tissues using the mercury-labeled pepstatin method were also studied histochemically. The best result for the visualization of lysosomal cathepsin D in liver tissues was obtained using the PLP fixative with the prefixation time of three hours or more.     

Histochemical evidence for lysosomal storage of acid glycosaminoglycans in splenic cells of rats treated with tilorone

Tilorone, an agent with antiviral and antitumor activities, has previously been reported to produce clear cytoplasmic vacuoles in many cell types of the rat. The present study on rat spleen was planned to investigate the ultrastructural and histochemical features of the tilorone-induced vacuoles occurring in sinus endothelium, trabecular smooth muscle cells, and macrophages of the red pulp. Evidence was obtained that the vacuoles represent lysosomes overloaded with acid glycosaminoglycans (aGAG). The main purpose of the present study was to overcome the technical difficulties of preserving the intralysosomal storage materials which were highly water-soluble and non-fixable by aldehyde fixatives. Preservation, at least for the light microscopical level, was achieved by freeze drying and by means of cationic dyes which served also to characterize the storage materials on the basis of their acidities. Tissue slices were used to determine the critical MgCl2 concentration necessary to abolish Alcian blue staining; cartilage and mast cells served as references. For the storage material in sinus endothelium, the critical MgCl2 concentration was found to be greater than 0.7 M, as compared to greater than 0.5 M for cartilage and greater than 0.9 M for mast cells. The storage materials in trabecular cells and macrophages were slightly less acidic than cartilaginous matrix and more heterogeneous than that in sinus endothelium. Ultrastructurally, positive staining with high iron diamine (HID) confirmed the presence of aGAG within the tilorone-induced vacuoles.     

An improved method for the subcellular localization of calcium using a modification of the antimonate precipitation technique

A new variation of the antimonate precipitation technique, employing tannic acid in the primary aldehyde-antimonate fixative, is described for use in the subcellular localization of calcium in various tissues. Chelation studies and electron microscopic, X-ray microanalytical studies of antimonate precipitates in etiolated oat tissues indicate that calcium is the major cation localized using the present experimental protocol. Preservation of ultrastructural morphology in these tissues is greatly improved over that observed in tissues fixed with conventional antimonate-aldehyde or antimonate-osmium fixatives. The regularity and reproducibility of tissue precipitate patterns suggests that 1) penetration of the tissue by the fixative, and subsequent precipitation of calcium, is rapid and uniform and 2) ion displacement during sample preparation is negligible. Calcium appears to be immobilized efficiently in situ, with greater than 90% 45Ca retention in radiolabeled tissues prepared for electron microscopy. Quantitative aspects of calcium precipitation by antimonate in 45Ca-labeled CaCl2 solutions were examined over a wide range of calcium concentrations. Precipitation was essentially linear over the expected range of biological concentrations of calcium. Furthermore, the 3:1 antimonate to calcium ratio estimated for test tube precipitates was also established for Sb/Ca in tissue precipitates analyzed using energy dispersive x-ray microanalytical (EDX) techniques. These observations suggest that the present technique is potentially useful in the semiquantitative estimation of tissue calcium levels.     

Screening and optimization of ligand conjugates for lysosomal targeting

The use of lysosome-targeted liposomes may significantly improve the delivery of therapeutic enzymes and chaperones into lysosomes for the treatment of lysosomal storage disorders. The aim of this research was to synthesize new potentially lysosomotropic ligands on a base of Neutral Red and rhodamine B and to study their ability to enhance specific lysosomal delivery of surface-modified liposomes loaded with a model compound, fluorescein isothiocyanate-dextran (FD). The delivery of these liposomes and their content to lysosomes in HeLa cells was investigated by confocal immunofluorescent microscopy, subcellular fractionation, and flow cytometry. Confocal microscopy demonstrated that liposomes modified with derivatives of rhodamine B provide a good rate of colocalization with the specific lysosomal markers. The comparison of fluorescence of FD in lysosomes isolated by subcellular fractionation also showed that the efficiency of lysosomal delivery of the liposomal load by liposomes modified with some of synthesized ligands was significantly higher compared to that with plain liposomes. These results were additionally confirmed by flow cytometry of the intact cells treated with liposomes loaded with 5-dodecanoylaminofluorescein di-β-d-galactopyranoside, a specific substrate for the intralysosomal β-galactosidase, using a number of cell lines, including macrophages with induced phenotype of lysosomal enzyme deficiency; two of the synthesized ligands-rhodamine B DSPE-PEG(2k)-amide and 6-(3-(DSPE-PEG(2k))-thioureido) rhodamine B-demonstrated enhanced lysosomal delivery, in some cases, higher than that for commercially available rhodamine B octadecyl ester, with the best results (the enhancement of the lysosomal delivery up to 75% greater in comparison to plain liposomes) shown for the cells with induced lysosomal enzyme deficiency phenotype. Use of liposomes modified with rhodamine B derivatives may be advantageous for the development of drug delivery systems for the treatment of lysosome-associated disorders.     

Facilitation of the structural and functional disorders of liver lysosomes in toxic hepatitis due to the suppression of intralysosomal proteolysis

Suramin that accumulates in rat liver Kupffer cell lysosomes and inhibits the intralysosomal proteolysis was used to suppress the functional activity of these particles during liver damage (acute CCl4 hepatitis). Polyvinylpyrrolidone that does not disturb protein catabolism in liver lysosomes was employed for reference. According to the characteristic changes in lysosomes induced by suramin (inhibition of acid phosphatase, decrease of the rate of the intralysosomal proteolysis in the liver) and PVP the damaged liver was able to accumulate the lysosomotropic substances under study. Suramin aggravated liver damage and increased the lysosomal labilization, whereas PVP exhibited the protective action. The unfavourable effect of suramin may be linked with the suppression of catabolism of Kupffer cell lysosomes. The data obtained suggest the lack of safety of using the inhibitors of intralysosomal proteolysis in patients with acute hepatitis.     

Intralysosomal accumulation of polyanions. I. Fusion of pinocytic and phagocytic vacuoles with secondary lysosomes

The long-term exposure of macrophages to low concentrations of a number of polyanions leads to their accumulation in high concentration within secondary lysosomes. This was associated with enlargement of the lysosomes, the presence of membranous whorls, and intense toluidine blue staining of the organelles at pH 1.0. After the ingestion of a particulate load by these cells, newly formed phagocytic vacuoles failed to fuse with polyanion-laden lysosomes. The lack of fusion was evident in both fluorescence and electron micrographic studies which followed the transfer of acridine orange or Thorotrast from 2 degrees lysosomes to phagosomes. Agents that inhibited phagosome-lysosome (P-L) fusion included molecules containing high densities of sulfate, sulfonate, or carboxylate residues. Dextran sulfate (DS) in microgram/ml quantities was an excellent inhibitor, whereas nonsulfated dextran (D) was without effect at 1,000-fold higher concentrations. In contrast to their effects on P-L fusion, polyanions failed to influence the fusion of pinocytic vesicles with 2 degrees lysosomes. The uptake, intravacuolar distribution, and intralysosomal digestion of fluid-phase pinocytic markers were unaltered in lysosomes containing either D or DS. Furthermore, subcellular fractionation studies showed that the fluid-phase pinocytic marker HRP was efficiently transferred from pinosomes to large, dense 2 degrees lysosomes containing DS.     

An Improved Procedure for the Histochemical Demonstration of Cathepsin D by the Mercury-Labeled Pepstatin Method

The desirable fixation conditions for the histochemical demonstration of cathepsin D using mercury-labeled pepstatin as an enzyme inhibitor were examined biochemically and histochemically. Four well known fixatives, namely, glutaraldehyde (GA), paraformaldehyde (PFA), glutaraldehyde with paraformaldehyde (GA-PFA) and periodate-lysine-paraformaldehyde (PLP), were applied to the prefixation of tissues prior to the reaction of the labeled inhibitor to the enzyme-active site. The effects of the fixatives on cathepsin D were biochemically examined using subcellular fractionated lysosomes. Cathepsin D from rat liver lysosomes was rapidly inactivated by the fixatives containing glutaraldehyde, i.e., GA and GA-PFA, whereas the activity of cathepsin D was sufficiently maintained after fixing the enzyme in the PFA or PLP preparations. Effects of the PLP fixative on lysosomal cathepsin D in liver tissues using the mercury-labeled pepstatin method were also studied histochemically. The best result for the visualization of lysosomal cathepsin D in liver tissues was obtained using the PLP fixative with the prefixation time of three hours or more.     

Histochemical evidence for lysosomal storage of acid glycosaminoglycans in splenic cells of rats treated with tilorone

Summary Tilorone, an agent with antiviral and antitumor activities, has previously been reported to produce clear cytoplasmic vacuoles in many cell types of the rat. The present study on rat spleen was planned to investigate the ultrastructural and histochemical features of the tilorone-induced vacuoles occurring in sinus endothelium, trabecular smooth muscle cells, and macrophages of the red pulp. Evidence was obtained that the vacuoles represent lysosomes overloaded with acid glycosaminoglycans (aGAG). The main purpose of the present study was to overcome the technical difficulties of preserving the intralysosomal storage materials which were highly water-soluble and non-fixable by aldehyde fixatives. Preservation, at least for the light microscopical level, was achieved by freeze drying and by means of cationic dyes which served also to characterize the storage materials on the basis of their acidities. Tissue slices were used to determine the critical MgCl₂ concentration necessary to abolish Alcian blue staining; cartilage and mast cells served as references. For the storage material in sinus endothelium, the critical MgCl₂ concentration was found to be >0.7 M, as compared to >0.5 M for cartilage and >0.9 M for mast cells. The storage materials in trabecular cells and macrophages were slightly less acidic than cartilagineous matrix and more heterogeneous than that in sinus endothelium. Ultrastructurally, positive staining with high iron diamine (HID) confirmed the presence of aGAG within the tilorone-induced vacuoles.