Biglycan is required for adaptive remodeling after myocardial infarction.

BACKGROUND: After myocardial infarction (MI), extensive remodeling of extracellular matrix contributes to scar formation and preservation of hemodynamic function. On the other hand, adverse and excessive extracellular matrix remodeling leads to fibrosis and impaired function. The present study investigates the role of the small leucine-rich proteoglycan biglycan during cardiac extracellular matrix remodeling and cardiac hemodynamics after MI. METHODS AND RESULTS: Experimental MI was induced in wild-type (WT) and bgn(-/0) mice by permanent ligation of the left anterior descending coronary artery. Biglycan expression was strongly increased at 3, 7, and 14 days after MI in WT mice. bgn(-/0) mice showed increased mortality rates after MI as a result of frequent left ventricular (LV) ruptures. Furthermore, tensile strength of the LV derived from bgn(-/0) mice 21 days after MI was reduced as measured ex vivo. Collagen matrix organization was severely impaired in bgn(-/0) mice, as shown by birefringence analysis of Sirius red staining and electron microscopy of collagen fibrils. At 21 days after MI, LV hemodynamic parameters were assessed by pressure-volume measurements in vivo to obtain LV end-diastolic pressure, end-diastolic volume, and end-systolic volume. bgn(-/0) mice were characterized by aggravated LV dilation evidenced by increased LV end-diastolic volume (bgn(-/0), 111+/-4.2 microL versus WT, 96+/-4.4 microL; P<0.05) and LV end-diastolic pressure (bgn(-/0), 24+/-2.7 versus WT, 18+/-1.8 mm Hg; P<0.05) and severely impaired LV function (EF, bgn(-/0), 12+/-2% versus WT, 21+/-4%; P<0.05) 21 days after MI. CONCLUSIONS: Biglycan is required for stable collagen matrix formation of infarct scars and for preservation of cardiac hemodynamic function.

Modest phenotypic improvements in ASA-deficient mice with only one UDP-galactose:ceramide-galactosyltransferase gene.

BACKGROUND: Arylsulfatase A (ASA)-deficient mice are a model for the lysosomal storage disorder metachromatic leukodystrophy. This lipidosis is characterised by the lysosomal accumulation of the sphingolipid sulfatide. Storage of this lipid is associated with progressive demyelination. We have mated ASA-deficient mice with mice heterozygous for a non-functional allele of UDP-galactose:ceramide-galactosyltransferase (CGT). This deficiency is known to lead to a decreased synthesis of galactosylceramide and sulfatide, which should reduce sulfatide storage and improve pathology in ASA-deficient mice. RESULTS: ASA-/- CGT+/- mice, however, showed no detectable decrease in sulfatide storage. Neuronal degeneration of cells in the spiral ganglion of the inner ear, however, was decreased. Behavioural tests showed small but clear improvements of the phenotype in ASA-/- CGT+/- mice. CONCLUSION: Thus the reduction of galactosylceramide and sulfatide biosynthesis by genetic means overall causes modest improvements of pathology.

Freeze-fracture studies of cytoplasmic inclusions occurring in experimental lipidosis as induced by amphiphilic cationic drugs.

The ultrastructure of cytoplasmic inclusions, which characterize experimental lipidosis as induced by several amphiphilic cationic drugs, was studied by means of freeze-fracturing and thin-sectioning. Retinal and adrenal tissues of rats chronically treated with high oral doses of chlorphentermine were used. In thin sections the cytoplasmic inclusions, which were previously shown to represent lysosomes overloaded with polar lipids, exhibit lamellated or lattice-like internal patterns. The present freeze-fracture observations are interpreted as to indicate that the lamellated inclusions contain polar lipids in the lamellar phase, whereas those with lattice-like patterns contain polar lipids in a hexagonal phase.

Disease model: LAMP-2 enlightens Danon disease.

Danon disease ('lysosomal glycogen storage disease with normal acid maltase') is characterized by a cardiomyopathy, myopathy and variable mental retardation. Mutations in the coding sequence of the lysosomal-associated membrane protein 2 (LAMP-2) were shown to cause a LAMP-2 deficiency in patients with Danon disease. LAMP-2 deficient mice manifest a similar vacuolar cardioskeletal myopathy. In addition to the patient reports LAMP-2 deficiency in mice causes pancreatic, hepatocytic, endothelial and leucocyte vacuolation. LAMP-2 deficient mice represent a valuable animal model of Danon disease. They will further be used to study the exact role of LAMP-2 in autophagy and to analyse the consequences of an impaired autophagic pathway in various tissues.

Bone marrow stem cell gene therapy of arylsulfatase A-deficient mice, using an arylsulfatase A mutant that is hypersecreted from retrovirally transduced donor-type cells.

Arylsulfatase A (ASA)-deficient mice represent an animal model for the fatal lysosomal storage disease metachromatic leukodystrophy, which is characterized by widespread intralysosomal deposition of sulfatide. Bone marrow stem cell gene therapy in mice, using a retroviral vector mediating expression of wild-type human ASA, has the potential to ameliorate the visceral pathology, but improves the prevailing brain disease and neurologic symptoms only marginally. One factor that influences the efficacy of bone marrow transplantation therapy in lysosomal storage diseases is the secretion level of the therapeutic enzyme from donor-type cells. Here we test the potential of a hypersecreted glycosylation variant of ASA. Although this mutant lacks mannose 6-phosphate residues it is taken up by cells by a mannose 6-phosphate receptor-independent pathway and causes partial metabolic correction of ASA-deficient mouse cells. Retrovirally mediated transfer of the mutant cDNA into ASA-deficient mice results in the sustained expression of the transgene. Serum levels argue for an increased secretion of the glycosylation mutant also in vivo. Tissue levels were reduced to 2% in liver and up to 40% in kidney compared with animals treated with the wild-type enzyme, indicating reduced endocytosis. Thus, the limited uptake of the variant enzyme outweighs the putative advantageous effect of improved supply. Although the mutant enzyme is able to correct the metabolic defect partially, histological examinations did not reveal any reduction of sulfatide storage in treated animals. Surprisingly, analysis of neurologic symptoms indicated a significant improvement of the gait pattern.

The effects of taipoxin and notexin on the function and fine structure of the murine neuromuscular junction.

The isolated neurotoxins taipoxin and notexin from the venoms of the Elapidae, Oxyuranus scutellatus and Notechis scutatus scutatus respectively cause a neuromuscular block when administered to the mouse in vivo or to the phrenic nerve-hemidiaphragm preparation in vitro. The block is preceded by a latency period during which the toxins bind irreversibly to the nerve. The period is shortened by nerve activity. The frequency of the miniature end-plate potentials is gradually reduced, almost to zero, and their amplitude distribution is altered; small and very large miniature endplate potentials appearing. Ultrastructurally the endplates are altered in the presynaptic portion but not in the postsynaptic part. In an early stage of poisoning the axolemma has an increased number of omega-shaped indentations similar in size to synaptic vesicles. At a later stage, when the animals die of respiratory paralysis, the axolemmal indentations are more numerous and the synaptic vesicles greatly reduced in number, the remaining vesicles having a variable and frequently larger than normal size. When impulse activity in the phrenic nerve is stopped by cutting the nerve before the administration of toxin there is no reduction in the number of synaptic vesicles, only the appearance of an increased number of axolemmal indentations. It is suggested that taipoxin and notexin irreversibly interfere with the formation of synaptic vesicles by arresting vesicle membrane recycling at the level of the axolemma. When the pre-existing store of vesicles is depleted, by nerve activity, a neuromuscular block results.

Tilorone-induced lysosomal storage of sulphated glycosaminoglycans can be separated from tilorone-induced enhancement of lysosomal enzyme secretion.

This investigation deals with a drug side-effect. The immunomodulatory drug tilorone (2,7-bis[2-(diethylamino)ethoxy]fluoren-9-one) and congeners induce lysosomal storage of sulphated glycosaminoglycans (GAGs) in animals and in cultured cells. At high tilorone concentrations, GAG storage in cultured fibroblasts was previously reported to be accompanied, and presumably caused by, disturbance of intracellular targeting of lysosomal enzyme precursors, which leads to enhanced secretion and thus loss of lysosomal enzymes. The purpose of the present study was to examine whether the GAG storage induced in cultured bovine fibroblasts by low tilorone concentrations is also accompanied by enhanced lysosomal enzyme release. Enhanced secretion of beta-hexosaminidase (EC 3.2.1.52) was taken as indicating the intracellular mistargeting of lysosomal enzyme precursors. Dose-response curves were established for (a) the intracellular accumulation of 35S-GAGs and (b) the release of beta-hexosaminidase after exposure (72 hr) to tilorone (1-35 microM). For positive controls, the classical lysosomotropic agents NH4Cl (1-30 mM) and chloroquine (1-60 microM) were used. With NH4Cl, 35S-GAG storage was accompanied by enhanced enzyme release throughout the concentration range (EC50 at 3.3 mM for either effect). With chloroquine, low concentrations (< or = 5 microM) caused a small increase in 35S-GAG accumulation without abnormal enzyme secretion; at higher concentrations both drug effects were produced (EC50 around 15 microM for either effect). With tilorone, low concentrations (< or = 5 microM) caused marked 35S-GAG accumulation without enhancement of enzyme release. The EC50 for tilorone-induced 35S-GAG storage was 3 microM, as opposed to 15 microM for enzyme release. The results indicate that GAG storage induced by low concentrations of tilorone is due to mechanisms other than mistargeting and loss of lysosomal enzymes. On the basis of previous results it may be hypothesized that tilorone and other symmetrically substituted dicationic compounds form complexes with the polyanionic GAG chains and thereby impair their enzymic degradation.

Sulfatide storage in visceral organs of arylsulfatase A-deficient mice.

The inherited deficiency of arylsulfatase A (ASA) in humans causes lysosomal accumulation of sulfatides in visceral organs and in the nervous system and leads to wide-spread demyelination (metachromatic leukodystrophy, MLD). ASA-deficient mice have previously been generated by means of targeted gene disruption. In the present study, visceral organs of ASA-deficient mice were investigated. A simple technique for the histochemical detection of accumulated sulfatides was elaborated using pre-embedding staining with alcian blue. The gall bladder, intrahepatic bile ducts, exocrine pancreatic ducts, respiratory epithelium and, with low degree, testicular Sertoli cells, showed sulfolipid storage. The storage pattern in the kidney will be described in a separate publication. Hepatocytes, pancreatic islets, adrenal glands, and gastric epithelium were unaffected. Ultrastructurally, the intralysosomal storage material displayed parallel and concentric lamellar patterns. Apart from some differences, the topographic distribution of the sulfatide storage resembled that in human MLD. In addition to being an animal model of the human disease, the ASA-deficient mouse may be useful for investigating the cell biology of sulfolipids in visceral organs.

Decline in brainstem auditory-evoked potentials coincides with loss of spiral ganglion cells in arylsulfatase A-deficient mice.

Arylsulfatase A (ASA)-deficient mice constitute an animal model for the inherited lysosomal storage disease, metachromatic leukodystrophy (MLD). Brainstem auditory-evoked potentials (BAEPs) were recorded in control and ASA-deficient mice of 3, 6, 9 and 12 months. BAEPs were evoked in control mice of all ages studied, but were completely absent in ASA (-/-) mice of 9 and 12 months. A significant delay in the wave pattern was noted in 6-month-old ASA (-/-) mice. Histological examination and morphometric analysis showed that the decline of BAEPs in ASA (-/-) mice was paralleled by a decrease in spiral ganglion cell numbers.

Mucopolysaccharidosis and lipidosis in rats treated with tilorone analogues.

The experimental immunomodulatory agent tilorone was previously reported to induce generalized mucopolysaccharidosis (lysosomal storage of sulfated glycosaminoglycans) and lipidosis in rats. While lipidosis is a side effect common to many cationic amphiphilic compounds, none of them except tilorone has been known to cause mucopolysaccharidosis in intact animals. The purpose of the present histochemical and ultrastructural study was to examine whether or not mucopolysaccharidosis can be induced by tilorone analogues. Three analogues were selected and administered to rats in short-term and subchronic experiments, and liver, spleen, kidney, and cornea were examined. The analogues caused generalized cellular lesions which had the same histochemical and cytological characteristics and the same distribution as the lesions produced by tilorone. The results show that the ability to induce mucopolysaccharidosis is not a unique property of tilorone; this drug side effect should be taken into account when developing new drugs with molecular structures resembling that of tilorone.

The antimalarials quinacrine and chloroquine induce weak lysosomal storage of sulphated glycosaminoglycans in cell culture and in vivo.

The antimalarial agents quinacrine and chloroquine are well known as potent inducers of lysosomal storage of polar lipids (lipidosis) in cell culture and in vivo. In previous experiments on cultured fibroblasts, chloroquine was shown to additionally cause weak lysosomal storage of sulphated glycosaminoglycans (GAGs) thus inducing mucopolysaccharidosis (MPS). In the present study, quinacrine was investigated for this ability, because we wished to know whether or not the acridine ring system in quinacrine would enhance the MPS-inducing potency as compared to chloroquine carrying an isoquinoline ring system. Tilorone (2,7-bis[2-(diethylamino)ethoxy]fluoren-9-one) known as a potent inducer of MPS served as reference compound. The compounds were compared at a concentration (3 microM) which did not enhance the secretion of the lysosomal enzyme beta-hexosaminidase (E.C. 3.2.1.52), since this would be an indication of unspecific drug effects upon the endosomal/lysosomal compartments of the cell. Additionally the liver of quinacrine- and chloroquine-treated rats was examined with the question whether the lysosomal GAG storage induced by either drug in cell culture had an equivalent in intact organisms. Both, in cell culture and in vivo, quinacrine was found to be a more potent inducer of lysosomal GAG storage than was chloroquine. The results suggest that the acridine ring system favours this drug side effect as compared with the bicyclic isoquinoline ring system. On the other hand, quinacrine was significantly less potent than tilorone and the Symmetrically substituted acridine derivative 3,6-bis[2-(diethylamino)ethoxy]acridine investigated previously. This suggests that the asymmetric structure of the quinacrine molecule reduces the potency as compared to the symmetrically substituted bisbasic compounds with planary tricyclic ring systems such as tilorone and congeners.

Drug-induced lysosomal storage of sulfated glycosaminoglycans. Studies on the underlying structure-activity relationships.

Some immunomodulatory drugs have previously been shown to induce lysosomal storage of sulfated glycosaminoglycans (sGAG) in intact organisms and cultured cells. These compounds consist of a planary aromatic ring system and two symmetric side chains each carrying a protonizable nitrogen. The purpose of this study was to test a larger collection of such compounds for their potencies to induce lysosomal storage of sGAG in cultured fibroblasts of rat cornea. The cells were exposed (72 h) to various compounds differing with respect to the aromatic ring system or the side chains. Lysosomal sGAG-storage was demonstrated by selective cytochemical staining with cuprolinic blue. The threshold concentration, i.e., the concentration necessary to induce cuprolinic blue-positive cytoplasmic inclusions in at least 1% of the cells, was determined for each compound. The threshold concentrations were distributed over a range of 0.3-30 microM. It should be emphasized that the threshold concentration of a given compound is not a constant, but depends on the volume of cell culture medium per surface area of cell monolayer, since the lysosomal accumulation lowers the initial drug concentration in the medium. If the ratio of medium volume:cell monolayer surface is increased as compared with standard cell culture conditions, the threshold concentration will be lowered. The compounds were ranked according to their threshold concentrations as determined under standard conditions. The following conclusions can be drawn from the ranking: the type of the central aromatic ring system and the distance between the ring system and the protonizable nitrogen atoms of the side chains influence the potency to induce lysosomal sGAG-storage. Regarding the ring system, the potency decreases as follows: acridine approximately anthrachinone > fenfluorenone approximately fenfluorene > xanthenone; xanthene > dibenzofuran approximately dibenzothiophene. In intact organisms, these structure-activity relationships may be superimposed by drug metabolism and pharmacokinetic factors.

Amantadine-induced lipidosis. A cytological and physicochemical study.

The purpose of this study was to test whether or not the antiviral drug amantadine induces the structural features of lipidosis in intact animals (rats) and cultured cells, and to investigate the interactions between amantadine and phospholipids. Chlorphentermine was used as reference compound. When subchronically fed to rats at a daily dosage of approximately 180 mg/kg, amantadine induced ultrastructural symptoms of generalized lipidosis, the degree of which was, however, by far less marked than that previously reported for chlorphentermine. This was paralleled by the findings on cell cultures (rat peritoneal macrophages), where the lipidosis-inducing potency of amantadine was approximately 10-fold lower than that of chlorphentermine. As to drug-phospholipid interactions, amantadine had less marked effects than chlorphentermine upon the phase transition characteristics of phosphatidylcholine and phosphatidic acid; furthermore, amantadine was approximately 10-fold less potent than chlorphentermine in displacing Ca from phosphatidylserine monolayers. The present study has revealed a parallel between the comparatively low lipidosis-inducing efficacy inherent to amantadine and the comparatively low tendency to interact with phospholipids. It is suggested that the cage-like structure of the amantadine molecule hinders an effective intercalation of the drug into phospholipid aggregates, and that this is an essential factor responsible for the low inherent efficacy of amantadine with respect to lipidosis induction.

Lysosomal glycosaminoglycan storage as induced by dicationic amphiphilic drugs: investigation into the mechanisms underlying the slow reversibility.

Several dicationic amphiphilic compounds, such as the immunomodulator tilorone and analogues, impair the lysosomal catabolism of sulphated glycosaminoglycans (GAGs). Thereby they cause lysosomal GAG storage in rats and in cultured fibroblasts of several species including man. The GAG storage is rather slowly reversible in vivo; it persists for months after discontinuance of drug treatment. In the present study, we investigated the mechanisms underlying the slow reversibility. Cultured bovine corneal fibroblasts were pretreated for 4 days with tilorone (5 and 20 microM) or with compound CL-90.100 (3 and 10 microM) and further cultured in drug-free medium for periods up to 11 days. The intracellular GAG storage was analysed biochemically and demonstrated histochemically. The subcellular drug distribution (CL-90.100) was demonstrated by fluorescence microscopy. Dermatan sulphate (DS) provided the predominant contribution towards the GAG storage. After pretreatments with the low, as well as the high concentrations of either drug, the storage of DS was irreversible during the period of observation, whereas the minor storage of heparan sulphate was resolved. The enhanced secretion of the lysosomal enzyme beta-hexosaminidase (E.C. 3.2.1.52) caused by pretreatment with the high concentration of tilorone was also readily reversible. Thus, enzyme deprivation could not be the explanation for the sustained DS storage. The localization of the drug-related fluorescence within perinuclear cell organelles, presumably lysosomes, resembled that of the stored GAGs as visualized by histochemical staining. Both, the fluorescence and the positive GAG staining persisted with unchanged intracellular distribution throughout the recovery period. The present results suggest that the persistence of the DS storage is due to the formation of long-lived, non-degradable DS-drug complexes within the lysosomes.

Drug-induced intralysosomal storage of sulfated glycosaminoglycans (GAGs): a methodical pitfall occurring with acridine derivatives.

The present communication deals with an adverse drug action which is exerted by a series of dicationic amphiphilic compounds such as the immunomodulatory drug tilorone and congeners. The drugs induce lysosomal storage of sulfated glycosaminoglycans (GAGs) in intact organisms and in cultured cells by impairing the lysosomal GAG degradation. This impairment was proposed to be due to the formation of non-degradable GAG-drug complexes. GAGs are highly water-soluble and not preservable by aldehyde fixatives. Therefore, usually the lysosomes appear optically empty in histological preparations, unless the fixative is supplemented with a GAG-precipitating agent. When acridine derivatives were used for the induction of GAG-storage, the lysosomal storage material displayed unexpected and unsystematic variability with regard to its preservability and ultrastructure. In the present study, evidence is presented that the acridine derivatives (a) remain bound to the stored GAGs for some time after glutaraldehyde fixation; and (b) they precipitate GAGs in vitro. Thus, apart from their unwanted action in the living cell, i.e., disturbing lysosomal GAG-degradation, the drugs function as precipitants and "fixatives" for the intralysosomal GAGs. The uncontrolled persistence of the drugs after tissue fixation leads to variable degree of GAG-preservation and thus to unpredictable variability of the ultrastructure of the storage lysosomes. If this pitfall is not realized, the resulting inconsistencies may rise confusion among toxicologic pathologists who deal with drug-induced lysosomal storage disorders.

Time course of the tilorone-induced lysosomal accumulation of sulphated glycosaminoglycans in cultured fibroblasts.

Dicationic amphiphilic drugs such as the immunomodulator tilorone [2,7-bis-[2-(diethylamino)ethoxy]fluoren-9-one] are accumulated in lysosomes and disturb the degradation of sulphated glycosaminoglycans (GAGs) thus leading to generalized lysosomal GAG storage (mainly dermatan sulphate) in vivo and in cultured cells. In the present study, the time course of the tilorone-induced GAG storage was determined in cultured bovine corneal fibroblasts by a radiochemical approach and by morphological examination. In contrast to the rapid lysosomal accumulation of the drug as reported previously, it took approximately 42 h to reach 50% of the GAG storage obtained after 96 h. This is thought to be due to the fact that the temporal development of storage of undigested GAGs depends on the natural delivery of GAGs towards the lysosomal apparatus.

Experimentally induced lipidosis in uterine and vaginal epithelium of rats.

The purpose of this study was to investigate the effects of two lipidosis-inducing drugs (the anorectic drug chlorphentermine and the tricyclic antidepressant-imipramine) upon the estrous cycle of rats and upon the morphology of the vaginal and uterine epithelia. After two weeks of continuous administration of high daily drug doses, the estrous cycle became stagnant. Ultrastructurally, the vaginal and uterine epithelia contained storage lysosomes which were filled with undigested polar lipids appearing as multilamellated material. The uterine luminal epithelium was most severely affected. The estrous cycle was abolished also by treatment with the anorexigenic drug phentermine, although this compound does not cause lipidosis. Therefore, the cessation of the estrous cycle cannot be attributed to the lipidosis as induced by chlorphentermine and imipramine; probably it is a consequence of the main actions of these psychotropic drugs. The biological basis for the exceedingly severe lipidosis in the uterine luminal epithelium is suggested to be the heavy load of polar lipids physiologically delivered to the lysosomal apparatus as long as the cycle-dependent apoptotic and autophagic processes were going on during the early period of drug treatment.

The structure and vascularization of the biceps brachii long head tendon.

In the present study we examined the structure and the blood supply of the long biceps tendon as well as the surface of the intertubercular sulcus, using tissue samples from children and adults. The applied methods were light and electron microscopy, immunohistochemistry, and arterial injection techniques. The tendon represents a sliding tendon with the intertubercular sulcus and humeral head as hypomochlion. The parts facing the humerus show some ultrastructural features of fibrous cartilage, the ovoid chondrocyte-like cells of the tendon lying within felt-like matrix. In the opposite part adjacent to the capsule, the tendon resembles a traction tendon. The intertubercular sulcus is covered by fibrous cartilage. The tendon is supplied with arteries from three different sources. The density of intratendinous vessels in the traction zone is comparable to that of other tendons, while in the sliding zone it is markably decreased. The immediate vicinity of the sliding surface is avascular. Our findings show that the long biceps tendon is structurally adapted to both its functions as sliding and traction tendon. The blood supply seems to be related to the metabolic requirements of the different parts of the tendon.

Metachromatic leukodystrophy: consequences of sulphatide accumulation.

UNLABELLED: Metachromatic leukodystrophy is a lysosomal lipid storage disorder. It is caused by mutations in the gene for arylsulphatase A, an enzyme involved in the degradation of the sphingolipid 3'-O-sulphogalactosylceramide (sulphatide). This membrane lipid can be found in various cell types, but in particularly high concentrations in the myelin of the nervous system. Patients suffer from progressive, finally lethal, demyelination due to accumulation of sulphatide. In the nervous system, lipid storage not only affects oligodendrocytes but also neurons and, in addition, leads to astrogliosis and activation of microglia. At the cellular level, lysosomal sulphatide storage also affects the lipid composition of myelin itself and has consequences for the amount and localization of particular myelin membrane-associated proteins. Here we review data, largely based on an arylsulphatase A knock-out mouse model of metachromatic leukodystrophy. CONCLUSION: The knock-out mouse model of metachromatic leukodystrophy has provided insights into the histopathological and cellular consequences of sulphatide storage.