The role of autophagic and lysosomal pathways in ischemic brain injury******

Autophagy is involved in neural cell death after cerebral ischemia. Our previous studies showed that rapamycin-induced autophagy decreased the rate of apoptosis, but the rate of apoptosis was in-creased after the autophagy inhibitor, 3-methyladenine, was used. In this study, a suture-occluded method was performed to generate a rat model of brain ischemia. Under a transmission electron microscope, autophagic bodies and autophagy lysosomes were markedly accumulated in neurons at 4 hours post brain ischemic injury, with their numbers gradually reducing over time. Western blotting demonstrated that protein levels of light chain 3-II and cathepsin B were significantly in-creased within 4 hours of ischemic injury, but these levels were not persistently upregulated over time. Confocal microscopy showed that autophagy was mainly found in neurons with positive light chain 3 signal. Injection of rapamycin via tail vein promoted the occurrence of autophagy in rat brain tissue after cerebral ischemia and elevated light chain 3 and cathepsin B expression. However, in-jection of 3-methyladenine significantly diminished light chain 3-II and cathepsin B expression. Results verified that autophagic and lysosomal activity is increased in ischemic neurons. Abnormal components in cells can be eliminated through upregulating cell autophagy or inhibiting autophagy after ischemic brain injury, resulting in a dynamic balance of substances in cells. Moreover, drugs that interfere with autophagy may be potential therapies for the treatment of brain injury.     

Mitochondrial control of autophagic lysosomal pathway in Alzheimer's disease

When first described by Alois Alzheimer in 1907, AD was seen as a disorder that causes dementia and characterized by two defining neuropathological lesions, later associated with all forms of AD. While the etiology of AD remains largely unclear, there is accumulating evidence suggesting that mitochondrial dysfunction occurs prior to the onset of symptoms in AD. Mitochondria are exceptionally poised to play a crucial role in neuronal cell survival or death because they are regulators of both energy metabolism and apoptotic pathways. This review is mainly focused in the discussion of evidence suggesting a clear association between mitochondrial dysfunction, autophagy impairment and amyloid-β accumulation in Alzheimer's disease pathophysiology. The knowledge that autophagic insufficiency may compromise the cellular degradation mechanisms that may culminate in the progressive accumulation of dysfunctional mitochondria, aberrant protein aggregates buildup and lysossomal burden shield new insights to the way we address Alzheimer's disease. In line with this knowledge an innovative window for new therapeutic strategies aimed to activate or ameliorate macroautophagy may be opened.     

Abnormalities in neural progenitor cells in a dog model of lysosomal storage disease

Lysosomal storage disorders constitute a large group of genetic diseases, many of which are characterized by mental retardation and other neurologic symptoms. The mechanisms of neural dysfunction remain poorly understood. Because neural progenitor cells (NPCs) are fundamentally important to normal brain development and function, we investigated NPC properties in a canine model of mucopolysaccharidosis VII (MPS VII). MPS VII is a lysosomal storage disorder characterized by defects in the catabolism of glycosaminoglycans. NPCs were isolated from the olfactory bulb, cerebellum, and striatal subventricular zone of normal and MPS VII (beta-glucuronidase-deficient) postnatal dog brains. Canine NPCs (cNPCs) from normal and MPS VII brains had similar growth curves, but cerebellar-derived cNPCs grew significantly slower than those derived from other regions. In differentiation assays, MPS VII cNPCs from the striatal subventricular zone and cerebellum generated fewer mature neuronal and/or glial cells than normal, and MPS VII olfactory bulb-derived cNPCs retained significantly more phenotypically immature cells. These differences were only present at the earliest time point after isolation; at later passages, there were no differences attributable to genotype. The data suggest that MPS VII cNPCs respond differently to developmental cues in vivo, probably because of the diseased neural microenvironment rather than intrinsic cellular deficits.     

"Salla disease": a new lysosomal storage disorder.

Severe mental retardation, coarse facial features, clumsiness, and speech failure were common findings in three brothers and one female third-cousin of a family from northern Finland. All the patients had vacuolated lymphocytes in peripheral blood smears, and electron microscopy of fresh skin biopsy specimens showed abundant cytoplasmic inclusions in various types of cells of the skin. Eight lysosomal hydrolases were assayed in peripheral blood lymphocytes and cultured skin fibroblasts, but no enzyme deficiency was detected. Urinary excretion of mucopolysaccharides, amino acids, glycoasparagines, and oligosaccharides was normal. Clinical findings, course of the disease, and the presence of cytoplasmic inclusions, indicating lysosomal storage phenomenon, suggest that the patients suffer from a genetic lysosomal storage disorder not described earlier. The eponym "Salla disease" was introduced, referring to the geographically restricted area where the family resides.     

The status of hematopoietic stem cell transplantation in lysosomal storage disease

Lysosomal storage diseases are a group of disorders which have in common an inherited defect in lysosomal function—in most cases, a missing intralysosomal enzyme. Research into potential treatment options for this group of disorders has focused on enzyme replacement. Over the past two decades, hematopoietic stem cell transplantation has been used with increasing frequency to treat patients with lysosomal storage disease by providing a population of cells with the capacity to produce the missing enzyme. The success of marrow transplantation depends on the specific enzyme deficiency and the stage of the disease. Generally, visceral symptoms can be improved, whereas skeletal lesions remain relatively unaffected. The effect on neurologic symptoms varies. Hematopoietic stem cell transplantation remains a viable treatment option in those lysosomal storage diseases where data supportive of disease stabilization or amelioration are known. Early transplantation is the goal so that enzyme replacement may occur before extensive central nervous system injury becomes evident. When inadequate clinical data are available, the decision to perform transplantation requires experimental data demonstrating that the enzyme in question is both excreted from normal cells and taken up by affected cells as evidenced by elimination of storage material in vitro.     

Adult-onset lysosomal storage disease in a Schipperke dog: clinical,morphological and biochemical studies

Summary An adult-onset lysosomal storage disorder was diagnosed in a 5-year-old Schipperke dog with progressive cerebellar and central vestibular signs. It was characterized by cerebellar atrophy with extensive loss of Purkinje and granular cells, and hydrocephalus. Enlarged and vacuolated neurons were observed in spinal cord and brain; pancreatic centrolobular and islet cells were also vacuolated. Ultrastructurally, enlarged secondary lysosomes laden with lamellated membrane structures were present in neurons and empty enlarged vacuoles were found in pancreatic centroacinar, ductal, and islet cells. On frozen sections neurons stained with Ricinus communis agglutinin-I and wheat germ agglutinin. On paraffin sections neurons stained with luxol fast blue, periodic acid-Schiff, Concanavalia ensiformis agglutinin, and were autofluorescent. These findings indicate an accumulation of glycolipids containing terminal -galactosyl and -sialyl residues, and N-linked oligosaccharides. Tissue activity of lysosomal -galactosidase was 50% of normal and the activity of -hexosaminidase was elevated. Brain lipid-bound sialic acid was twice normal, with a small increase of G_M1-ganglioside, but there was a significant elevation of G_M2 (G_D2) and G_M3 (G_D3). In addition, significant elevations of sialylated and non-sialylated oligosaccharides were noted. These clinical, biochemical and pathological findings are similar to those observed in human patients with adult-onset galactosialidosis.     

Developmental analysis of CNS pathology in the lysosomal storage disease alpha-mannosidosis

The lysosomal storage disease alpha-mannosidosis is due to absence or defective function of lysosomal alpha-mannosidase, resulting in primary storage of undegraded mannose-rich oligosaccharides. Disease has been described in humans, cattle, cats, mice, and guinea pigs and is characterized in all species by progressive neurologic deterioration and premature death. We analyzed the neurodegenerative processes relative to clinical disease in alpha-mannosidosis guinea pigs as a human disease model, from birth to end-stage disease. Before the onset of obvious neurologic abnormalities at 2 months, we observed widespread neuronal lysosomal vacuolation including secondary accumulation of GM3 ganglioside, widespread axonal spheroids, and reduced myelination of white matter. Histopathologic changes subsequently showed rapid progression in severity in a pattern common to a number of different lysosomal storage disorders, with additional abnormalities including accumulation of GM2 ganglioside and cholesterol, astrogliosis, neuron loss particularly in the cerebellum, and activation and infiltration of the CNS with microglia/macrophages. End-stage clinical disease was seen at 10 to 14 months of age. Our findings show that complex neuropathologic changes in alpha-mannosidosis guinea pigs are already present at birth, before clinical changes are evident, and similar events are likely to occur in patients with this disorder.     

Lectin histochemistry of infantile lysosomal storage disease associated with osteopetrosis

In infantile lysosomal storage disease associated with osteopetrosis the nature of the enzyme deficiency as well as the type of material accumulated are both unknown. We used lectin histochemistry to characterize the storage material of previously reported cases. Using paraffin sections neurons stained positively with Luxol fast blue (LFB), periodic acid-Schiff (PAS), Concanavalia ensiformis agglutinin, Datura stramonium agglutinin, Griffonia simplicifolia-I, Lens culinaris agglutinin, Ricinus communis agglutinin-I, succinylated wheat germ aggluninin and wheat germ agglutinin, indicating an accumulation of fucosylated N-glycosidically linked oligosaccharides containing - and -galactosyl residues and compounds containing N-acetyllactos-amine. Reticuloendothelial cells in liver and in spleen did not stain with LFB, but did stain with PAS and the above lectins. These results indicate that there is storage of both carbohydrates and lipids in neurons, and stored carbohydrates with similar residues in reticuloendothelial cells in this disease, where the primary defect is still unknown.     

Hepatic involvement in a case of lysosomal glycogen storage disease with normal acid maltase]

A 19-year-old man, who could run only slowly since childhood and who walked on his toes since 12 years of age, noted difficulty in climbing upstairs at 17 years of age. He was admitted to Kyushu University Hospital because of elevated AST, ALT and CK levels. On admission, the liver was palpable two fingerbreadths beneath the right costal margin. A neurological examination revealed a low IQ on WAIS-R, a decreased muscle tonus in his four limbs, moderate weakness of the neck flexor and bilateral tibialis anterior muscles, contracture of the ankle joints, and bilateral pes cavus. The serum CK was elevated to 1,124U/l. Hepatic enzymes, such as AST, ALT, LDH and gamma-GTP were also moderately increased in the sera. A needle EMG disclosed myogenic patterns in the limb muscles. Biopsied biceps brachii muscle showed a mild variation in the fiber size and multiple tiny vacuoles in 5-10% of the muscle fibers. PAS and acid phosphatase were strongly positive in some vacuoles. On electron microscopy, numerous autophagic vacuoles containing glycogen granules were observed. The acid maltase activities were, however, normal in the peripheral blood lymphocytes, the biopsied muscle, and the cultured skin fibroblasts. He was thus diagnosed to have lysosomal glycogen storage disease with normal acid maltase. A histological examination of the biopsied liver revealed the portal and central veins to be slightly sclerotic. In addition, mild fatty changes and frequent nuclear vacuolization were present in the hepatocytes. On electron microscopy, enlarged mitochondria with irregular cristae were also observed. Due to the fact that the cardiac function was well preserved, these hepatic lesions were thought to result from the metabolic abnormalities underlying in this disorder.     

Adult onset lysosomal storage disease in a Tibetan terrier: Clinical,morphological and biochemical studies

Summary We describe a novel late-onset lysosomal lipid storage disease affecting a Tibetan terrier. The principal clinical manifestations include visual loss, progressive cerebellar ataxia and dementia. A necropsy of an affected 10-year-old dog demonstrated cerebellar atrophy. Histological analysis revealed extensive loss of retinal ganglion cells and cerebellar Purkinje cells, and mild to moderate loss of neurons in the cerebrum, basal ganglia and spinal cord. There were generalized neuronal hypertrophy and multifocal neuronal necrosis associated with the presence of enlarged macrophages. Neurons and perineuronal macrophages contained cytoplasmic granules that stained with PAS, luxol fast blue and several lectins. The granules were sudanophilic and autofluorescent. Electron microscopic analysis revealed lysosomes laden with lamellated membrane structures in neurons, pancreatic ductal and centroacinar cells and in cultured fibroblasts. These findings indicate lysosomal storage of both lipid and carbohydrate. Biochemical analysis of brain lipids and numerous lysosomal enzyme assays of leukocytes and cultured fibroblasts were unsuccessful in elucidating the underlying enzyme defect, although a generalized increase of brain gangliosides was noted.     

Familial lysosomal storage disease with generalized vacuolization and sialic aciduria. Sporadic Salla disease

Two eight- and sixteen-year-old children with severe progressive neurologic disease revealed an ultrastructural finding of lysosomal vacuolization in mesenchymal or parenchymal cells of different organ biopsies (skin, muscle, nerve and liver), which may be very suggestive of mucolipidosis. However, in our patients biochemical tests available for these diseases yielded negative results, except for increased excretion of free sialic acid in urine and sialic acid storage in cultured fibroblasts. The clinical picture and the ultrastructural and biochemical findings were compatible with Salla disease, a rare lysosomal storage disease originally observed in Finland.     

Pompe's disease: An inborn lysosomal disorder with storage of glycogen

Summary Anatomopathological studies are reported in a new case of Pompe's disease (glycogenosis type II). The topography of the selective neuronal involvement is again stressed and more accurately localized regarding the thalamus. The accumulation of glycogen-filled vacuoles in astroglia, Schwann cells and myenteric plexus is demonstrated by light or electron microscopy or both.The histochemical features of the basophilic material coexisting with glycogen in striated muscle are described. Our results indicate a close relationship between glycogen and the basophilic material; they indicate that phosphate groups may be responsible for the alcianophilia and metachromasia at low pH.Ultrastructural studies of biopsy and autopsy specimens of striated muscle show that much of the glycogen is in vacuoles which are most probably of lysosomal nature.     

Molecular heterogeneity in lysosomal storage diseases

Molecular and chemical neuropathology - The availability of specific antibodies and cDNA probes for lysosomal hydrolases has revealed unexpected heterogeneity among the human inherited lysosomal...     

Fabry's disease: new therapeutic options for this lysosomal storage disorder

Fabry's disease is an x-linked, recessive, lysosomal storage disorder that results from deficient alpha-galactosidase A activity with pathological sphingolipid deposition mainly in endothelium, smooth muscle cells, kidneys, central and peripheral nervous system, and myocardium. Clinical manifestation mostly occurs during childhood and adolescence with severe pain attacks or chronic pain mainly in hands and feet, hypohydrosis, and skin lesions (angiokeratoma). In more advanced disease stages, renal and cerebrovascular complications develop with proteinuria and later renal failure and cerebral ischemia caused by cerebral microangiopathy, dilatative arteriopathy, or cardiac embolism. Heterozygote female carriers are severely affected more often than was previously considered. The diagnosis is based on the detection of deficient alpha-galactosidase A activity in leukocytes, fibroblasts, or tissue biopsies. Two randomised placebo-controlled studies showed that enzyme replacement is effective by demonstrating either reduced pain or reduced tissue sphingolipid deposition. Early diagnosis of Fabry's disease is important in view of these new causal therapeutic options.     

Altered lysosomal positioning affects lysosomal functions in a cellular model of Huntington's disease

Huntington's disease (HD) is a hereditary and devastating neurodegenerative disorder caused by a mutation in the huntingtin protein. Understanding the functions of normal and mutant huntingtin protein is the key to revealing the pathogenesis of HD and developing therapeutic targets. Huntingtin plays an important role in vesicular and organelle trafficking. Lysosomes are dynamic organelles that integrate several degradative pathways and regulate the activity of mammalian target of rapamycin complex 1 (mTORC1). In the present study, we found that the perinuclear accumulation of lysosomes was increased in a cellular model of HD derived from HD knock‐in mice and primary fibroblasts from an HD patient. This perinuclear lysosomal accumulation could be reversed when normal huntingtin was overexpressed in HD cells. When we further investigated the functional significance of the increased perinuclear lysosomal accumulation in HD cells, we demonstrated that basal mTORC1 activity was increased in HD cells. In addition, autophagic influx was also increased in HD cells in response to serum deprivation, which leads to premature fusion of lysosomes with autophagosomes. Taken together, our data suggest that the increased perinuclear accumulation of lysosomes may play an important role in HD pathogenesis by altering lysosomal‐dependent functions.     

Immune system irregularities in lysosomal storage disorders

Lysosomal storage disorders (LSDs) are genetically inherited diseases characterized by the accumulation of disease-specific biological materials such as proteolipids or metabolic intermediates within the lysosome. The lysosomal compartment’s central importance to normal cellular function can be appreciated by examining the various pathologies that arise in LSDs. These disorders are invariably fatal, and many display profound neurological impairment that begins in childhood. However, recent studies have revealed that several LSDs also have irregularities in the function of the immune system. Gaucher disease, mucopolysaccharidosis VII, and α-mannosidosis are examples of a subset of LSD patients that are predisposed towards immune suppression. In contrast, GM2 gangliosidosis, globoid cell leukodystrophy, Niemann-Pick disease type C1 and juvenile neuronal ceroid lipofuscinosis are LSDs that are predisposed towards immune system hyperactivity. Antigen presentation and processing by dedicated antigen presenting cells (APCs), secretion of pore-forming perforins by cytotoxic-T lymphocytes, and release of pro-inflammatory mediators by mast cells are among the many crucial immune system functions in which the lysosome plays a central role. Although the relationship between the modification of the lysosomal compartment in LSDs and modulation of the immune system remains unknown, there is emerging evidence for early neuroimmune responses in a variety of LSDs. In this review we bridge biochemical studies on the lysosomal compartment’s role in the immune system with clinical data on immune system irregularities in a subset of LSDs.     

Early deficits in motor coordination and cognitive dysfunction in a mouse model of the neurodegenerative lysosomal storage disorder, Sandhoff disease

Mouse models of lysosomal storage diseases, including Sandhoff disease, are frequently employed to test therapies directed at the central nervous system. We backbred such mice and conducted a behavioral test battery which included sensorimotor and cognitive assessments. This is the first report of short-term memory deficits in a murine model of Sandhoff disease. We also document early onset of motor deficits using the balance beam test.