Mouse models of Tay-Sachs and Sandhoff diseases differ in neurologic phenotype and ganglioside metabolism.

Tay-Sachs and Sandhoff diseases are clinically similar neurodegenerative disorders. These two sphingolipidoses are characterized by a heritable absence of beta-hexosaminidase A resulting in defective GM2 ganglioside degradation. Through disruption of the Hexa and Hexb genes in embryonic stem cells, we have established mouse models corresponding to each disease. Unlike the two human disorders, the two mouse models show very different neurologic phenotypes. Although exhibiting biochemical and pathologic features of the disease, the Tay-Sachs model showed no neurological abnormalities. In contrast, the Sandhoff model was severely affected. The phenotypic difference between the two mouse models is the result of differences in the ganglioside degradation pathway between mice and humans.

Mice lacking both subunits of lysosomal beta-hexosaminidase display gangliosidosis and mucopolysaccharidosis.

The GM2 gangliosidoses, Tay-Sachs and Sandhoff diseases, are caused by mutations in the HEXA (alpha-subunit) and HEXB (beta-subunit) genes, respectively. Each gene encodes a subunit for the heterodimeric lysosomal enzyme, beta-hexosaminidase A (alpha beta), as well as for the homodimers beta-hexosaminidase B (beta beta) and S (alpha alpha). In this study, we have produced mice that have both Hexa and Hexb genes disrupted through interbreeding Tay-Sachs (Hexa-/-) and Sandhoff (Hexb-/-) disease model mice. Lacking both the alpha and beta-subunits these 'double knockout' mice displayed a total deficiency of all forms of lysosomal beta-hexosaminidase including the small amount of beta-hexosaminidase S present in the Sandhoff disease model mice. More surprisingly, these mice showed the phenotypic, pathologic and biochemical features of the mucopolysaccharidoses, lysosomal storage diseases caused by the accumulation of glycosaminoglycans. The mucopolysaccharidosis phenotype is not seen in the Tay-Sachs or Sandhoff disease model mice or in the corresponding human patients. This result demonstrates that glycosaminoglycans are crucial substrates for beta-hexosaminidase and that their lack of storage in Tay-Sachs and Sandhoff diseases is due to functional redundancy in the beta-hexosaminidase enzyme system.

The mutations in Ashkenazi Jews with adult GM2 gangliosidosis, the adult form of Tay-Sachs disease.

The adult form of Tay-Sachs disease, adult GM2 gangliosidosis, is an autosomal recessive disorder that results from mutations in the alpha chain of beta-hexosaminidase A. This disorder, like infantile Tay-Sachs disease, is more frequent in the Ashkenazi Jewish population. A point mutation in the alpha-chain gene was identified that results in the substitution of Gly with Ser in eight Ashkenazi adult GM2 gangliosidosis patients from five different families. This amino acid substitution was shown to depress drastically the catalytic activity of the alpha chain after expression in COS-1 cells. All of these patients proved to be compound heterozygotes of the allele with the Gly to Ser change and one of the two Ashkenazi infantile Tay-Sachs alleles. These findings will aid in the diagnosis and understanding of beta-hexosaminidase A deficiency disorders.

Prevention of lysosomal storage in Tay-Sachs mice treated with N-butyldeoxynojirimycin.

The glycosphingolipid (GSL) lysosomal storage diseases result from the inheritance of defects in the genes encoding the enzymes required for catabolism of GSLs within lysosomes. A strategy for the treatment of these diseases, based on an inhibitor of GSL biosynthesis N-butyldeoxynojirimycin, was evaluated in a mouse model of Tay-Sachs disease. When Tay-Sachs mice were treated with N-butyldeoxynojirimycin, the accumulation of GM2 in the brain was prevented, with the number of storage neurons and the quantity of ganglioside stored per cell markedly reduced. Thus, limiting the biosynthesis of the substrate (GM2) for the defective enzyme (beta-hexosaminidase A) prevents GSL accumulation and the neuropathology associated with its lysosomal storage.

A genetic model of substrate deprivation therapy for a glycosphingolipid storage disorder.

Inherited defects in the degradation of glycosphingolipids (GSLs) cause a group of severe diseases known as GSL storage disorders. There are currently no effective treatments for the majority of these disorders. We have explored a new treatment paradigm, substrate deprivation therapy, by constructing a genetic model in mice. Sandhoff's disease mice, which abnormally accumulate GSLs, were bred with mice that were blocked in their synthesis of GSLs. The mice with simultaneous defects in GSL synthesis and degradation no longer accumulated GSLs, had improved neurologic function, and had a much longer life span. However, these mice eventually developed a late-onset neurologic disease because of accumulation of another class of substrate, oligosaccharides. The results support the validity of the substrate deprivation therapy and also highlight some limitations.

Bone marrow transplantation prolongs life span and ameliorates neurologic manifestations in Sandhoff disease mice.

The GM2 gangliosidoses are a group of severe, neurodegenerative conditions that include Tay-Sachs disease, Sandhoff disease, and the GM2 activator deficiency. Bone marrow transplantation (BMT) was examined as a potential treatment for these disorders using a Sandhoff disease mouse model. BMT extended the life span of these mice from approximately 4.5 mo to up to 8 mo and slowed their neurologic deterioration. BMT also corrected biochemical deficiencies in somatic tissues as indicated by decreased excretion of urinary oligosaccharides, and lower glycolipid storage and increased levels of beta-hexosaminidase activity in visceral organs. Even with neurologic improvement, neither clear reduction of brain glycolipid storage nor improvement in neuronal pathology could be detected, suggesting a complex pathogenic mechanism. Histological analysis revealed beta-hexosaminidase-positive cells in the central nervous system and visceral organs with a concomitant reduction of colloidal iron-positive macrophages. These results may be important for the design of treatment approaches for the GM2 gangliosidoses.

Edg-1, the G protein-coupled receptor for sphingosine-1-phosphate, is essential for vascular maturation.

Sphingolipid signaling pathways have been implicated in many critical cellular events. Sphingosine-1-phosphate (SPP), a sphingolipid metabolite found in high concentrations in platelets and blood, stimulates members of the endothelial differentiation gene (Edg) family of G protein-coupled receptors and triggers diverse effects, including cell growth, survival, migration, and morphogenesis. To determine the in vivo functions of the SPP/Edg signaling pathway, we disrupted the Edg1 gene in mice. Edg1(-/-) mice exhibited embryonic hemorrhage leading to intrauterine death between E12.5 and E14.5. Vasculogenesis and angiogenesis appeared normal in the mutant embryos. However, vascular maturation was incomplete due to a deficiency of vascular smooth muscle cells/pericytes. We also show that Edg-1 mediates an SPP-induced migration response that is defective in mutant cells due to an inability to activate the small GTPase, Rac. Our data reveal Edg-1 to be the first G protein-coupled receptor required for blood vessel formation and show that sphingolipid signaling is essential during mammalian development.

Quantification of mRNAs encoding proteins of the glycosphingolipid catabolism in mouse models of GM2 gangliosidoses and sphingolipid activator protein precursor (prosaposin) deficiency.

We have investigated the mRNA amounts of six lysosomal proteins (beta-hexosaminidase alpha- and beta-subunit, sphingolipid activator protein precursor, GM2 activator protein, lysosomal sialidase, beta-glucocerebrosidase) involved in the degradation of glycosphingolipids. We analyzed extracts from brain tissues of mouse models for lysosomal storage diseases, i.e., the GM2 gangliosidoses and the deficiency of the sphingolipid activator protein precursor (prosaposin). The mRNA levels were quantified by real-time reverse transcription-polymerase chain reaction. Although storage of the respective lysosomal proteins has been reported in human and mice, no increase of their mRNA amounts could be detected here. Our results indicate that there is no transcriptional upregulation of lysosomal proteins in the examined neuronal storage disorders.

Mice deficient in all forms of lysosomal beta-hexosaminidase show mucopolysaccharidosis-like pathology.

Lysosomal beta-hexosaminidase consists of 2 subunits, alpha and beta. Mutations in the alpha-subunit gene cause Tay-Sachs disease, while mutations in the beta-subunit gene cause Sandhoff disease. Mice generated by targeted disruption of either the alpha- or beta-subunit genes displayed the pathological features of Tay-Sachs disease or Sandhoff disease, respectively. In this report we describe the pathologic features of mice that carry both disrupted genes and that are deficient in all forms of beta-hexosaminidase activity. These mice displayed physical dysmorphia and extensive neuro-visceral storage. Neurons in the CNS and PNS contained pleomorphic inclusions in addition to membranous cytoplasmic bodies characteristic of gangliosidosis. Diffuse hypomyelination was also apparent in the CNS. Vacuolated cytoplasm was a conspicuous feature of chondrocytes, osteocytes and renal tubular epithelium on routine hematoxylin and eosin (H&E) -stained sections. Numerous vacuolated cells were also noted in the connective tissue, cornea, heart valves, arterial walls, liver, spleen, skin and throughout other visceral organs. These vacuolated cells stained positive with PAS, colloidal iron and alcian blue, indicating an accumulation of glycosaminoglycans. Furthermore, cultured fibroblasts showed a defect in the degradation of glycosaminoglycans, and glycosaminoglycans were excreted in the urine of these mice (1). Thus, morphological and biochemical features in these mice are consistent with those of mucopolysaccharidosis and demonstrate an essential role of beta-hexosaminidase in the degradation of glycosaminoglycans.

Mouse models of human lysosomal diseases.

Genetically authentic animal models of human lysosomal diseases occur spontaneously in many mammalian species. However, most are among larger domestic or farm animals with only two well-defined genetic lysosomal diseases known among rodents. This status changed dramatically in recent years with the advent of the combined homologous recombination and embryonic stem cell technology, which allows directed generation of mouse models that are genetically equivalent to human diseases. Almost all known human sphingolipidoses, two mucopolysaccharidoses and aspartylglycosaminuria have so far been duplicated in mice and more are expected in the near future. This technology also allows generation of mouse mutants that are not known or are highly unlikely to exist in humans, such as "double-knockouts." These animal models will play an important role in studies of the pathogenesis and treatment of these disorders. While the utility of these mouse models is obvious, species differences in brain development and metabolic pathways must be always remembered, if the ultimate goal of the study is application to human patients.

Accumulation of protein-bound epidermal glucosylceramides in beta-glucocerebrosidase deficient type 2 Gaucher mice.

The epidermal permeability barrier for water is essentially maintained by extracellular lipid membranes within the interstices of the stratum corneum. Ceramides, the main components of these membranes, derive in large part from hydrolysis of glucosylceramides mediated by the lysosomal enzyme beta-glucocerebrosidase. As analyzed in this work, the beta-glucocerebrosidase deficiency in type 2 Gaucher mice (RecNci I) resulted in an accumulation of all epidermal glucosylceramide species accompanied with a decrease of the related ceramides. However, the levels of one ceramide subtype, which possesses an alpha-hydroxypalmitic acid, was not altered in RecNci I mice suggesting that the beta-glucocerebrosidase pathway is not required for targeting of this lipid to interstices of the stratum corneum. Most importantly, omega-hydroxylated glucosylceramides which are protein-bound to the epidermal cornified cell envelope of the transgenic mice accumulated up to 35-fold whereas levels of related protein-bound ceramides and fatty acids were decreased to 10% of normal control. These data support the hypothesis that in wild-type epidermis omega-hydroxylated glucosylceramides are first transferred enzymatically from their linoleic esters to proteins of the epidermal cornified cell envelope and then catabolized to protein-bound ceramides and fatty acids, thus contributing at least in part to the formation of the lipid-bound envelope.

Promoters for the human beta-hexosaminidase genes, HEXA and HEXB.

Human lysosomal beta-hexosaminidases are encoded by two genes, HEXA and HEXB, specifying an alpha- and a beta-subunit, respectively. The subunits dimerize to form beta-hexosaminidase A (alpha beta), beta-hexosaminidase B (beta beta), and beta-hexosaminidase S (alpha alpha). This enzyme system has the capacity to degrade a variety of cellular substrates: oligosaccharides, glycosaminoglycans, and glycolipids containing beta-linked N-acetylglucosaminyl or N-galactosaminyl residues. Mutations in either the HEXA gene or HEXB gene lead to an accumulation of GM2 ganglioside in neurons, resulting in the severe neurodegenerative disorders termed the GM2 gangliosidoses. To identify the DNA elements responsible for hexosaminidase expression, we ligated the 5'-flanking sequences of both the human and mouse hexosaminidase genes to a chloramphenicol acetyltransferase (CAT) gene. The resulting plasmids were transfected into NIH-3T3 cells and CAT activity was determined as a measure of promoter strength. By 5' deletion analysis, it was found that essential sequences for HEXA expression resided within a 40-bp region between 100 bp and 60 bp upstream of the ATG initiation codon. This area contained two potential estrogen response element half-sites as well as potential binding sites for transcription factors NF-E1 and AP-2. Similarly, important HEXB promoter sequences were localized to a 60-bp region between 150 bp and 90 bp upstream of the ATG codon. By performing scanning mutagenesis on a 60-bp region within the 150-bp HEXB construct, we defined an essential promoter element of 12 bp that contained two potential AP-1 sites. The mouse Hexa and Hexb 5'-flanking sequences were found to contain regions similar in sequence, location, and activity to the essential promoter elements defined in the cognate human genes. No sequence similarity was found, however, between 5'-flanking regions of the HEXA and HEXB genes. These essential promoter elements represent potential sites for HEXA and HEXB mutations that could alter enzyme expression in Tay-Sachs and Sandhoff diseases, respectively.

Regulation of synaptic strength by sphingosine 1-phosphate in the hippocampus.

Although the hippocampus is a brain region involved in short-term memory, the molecular mechanisms underlying memory formation are not completely understood. Here we show that sphingosine 1-phosphate (S1P) plays a pivotal role in the formation of memory. Addition of S1P to rat hippocampal slices increased the rate of AMPA receptor-mediated miniature excitatory postsynaptic currents (mEPSCs) recorded from the CA3 region of the hippocampus. In addition long-term potentiation (LTP) observed in the CA3 region was potently inhibited by a sphingosine kinase (SphK) inhibitor and this inhibition was fully reversed by S1P. LTP was impaired in hippocampal slices specifically in the CA3 region obtained from SphK1-knockout mice, which correlates well with the poor performance of these animals in the Morris water maze test. These results strongly suggest that SphK/S1P receptor signaling plays an important role in excitatory synaptic transmission in the CA3 region of hippocampus and has profound effects on hippocampal function such as spatial learning.

Gene encoding the human beta-hexosaminidase beta chain: extensive homology of intron placement in the alpha- and beta-chain genes.

Lysosomal beta-hexosaminidase (EC 3.2.1.52) is composed of two structurally similar chains, alpha and beta, that are the products of different genes. Mutations in either gene causing beta-hexosaminidase deficiency result in the lysosomal storage disease GM2-gangliosidosis. To enable the investigation of the molecular lesions in this disorder and to study the evolutionary relationship between the alpha and beta chains, the beta-chain gene was isolated, and its organization was characterized. The beta-chain coding region is divided into 14 exons distributed over approximately 40 kilobases of DNA. Comparison with the alpha-chain gene revealed that 12 of the 13 introns interrupt the coding regions at homologous positions. This extensive sharing of intron placement demonstrates that the alpha and beta chains evolved by way of the duplication of a common ancestor.

Stemming the tide: glycosphingolipid synthesis inhibitors as therapy for storage diseases.

Glycosphingolipids (GSLs) are plasma membrane components of every eukaryotic cell. They are composed of a hydrophobic ceramide moiety linked to a glycan chain of variable length and structure. Once thought to be relatively inert, GSLs have now been implicated in a variety of biological processes. Recent studies of animals rendered genetically deficient in various classes of GSLs have demonstrated that these molecules are important for embryonic differentiation and development as well as central nervous system function. A family of extremely severe diseases is caused by inherited defects in the lysosomal degradation pathway of GSLs. In many of these disorders GSLs accumulate in cells, particularly neurons, causing neurodegeneration and a shortened life span. No effective treatment exists for most of these diseases and little is understood about the mechanisms of pathogenesis. This review will discuss the development of a new approach to the treatment of GSL storage disorders that targets the major synthesis pathway of GSLs to stem their cellular accumulation.

The molecular basis of HEXA mRNA deficiency caused by the most common Tay-Sachs disease mutation.

Tay-Sachs disease (TSD) is a catastrophic neurodegenerative disorder caused by mutations in the HEXA gene. The most common TSD allele worldwide contains a 4-bp insertion in exon 11 that produces a downstream premature termination codon. Despite normal transcription of this allele, HEXA mRNA is severely reduced, indicating that the HEXA transcript must be unstable. Minigenes of HEXA were constructed and expressed in mouse L cells, to investigate the relationship between the 4-bp insertion and mRNA deficiency. We conclude that the mRNA instability is caused by the premature termination codon and not by a cryptic mutation or by the 4-bp insertion directly and that degradation occurs coincident with or after splicing.