Substrate reduction therapy for Krabbe disease and metachromatic leukodystrophy using a novel ceramide galactosyltransferase inhibitor.

Krabbe disease (KD) and metachromatic leukodystrophy (MLD) are caused by accumulation of the glycolipids galactosylceramide (GalCer) and sulfatide and their toxic metabolites psychosine and lysosulfatide, respectively. We discovered a potent and selective small molecule inhibitor (S202) of ceramide galactosyltransferase (CGT), the key enzyme for GalCer biosynthesis, and characterized its use as substrate reduction therapy (SRT). Treating a KD mouse model with S202 dose-dependently reduced GalCer and psychosine in the central (CNS) and peripheral (PNS) nervous systems and significantly increased lifespan. Similarly, treating an MLD mouse model decreased sulfatides and lysosulfatide levels. Interestingly, lower doses of S202 partially inhibited CGT and selectively reduced synthesis of non-hydroxylated forms of GalCer and sulfatide, which appear to be the primary source of psychosine and lysosulfatide. Higher doses of S202 more completely inhibited CGT and reduced the levels of both non-hydroxylated and hydroxylated forms of GalCer and sulfatide. Despite the significant benefits observed in murine models of KD and MLD, chronic CGT inhibition negatively impacted both the CNS and PNS of wild-type mice. Therefore, further studies are necessary to elucidate the full therapeutic potential of CGT inhibition.

Expression of sulfatide and sulfated lactosylceramide among histological types of human ovarian carcinomas.

Among negatively charged lipids, sulfoglycolipids are known to be expressed by specific cell populations and to be involved in their functions, including in adhesion with functional proteins, modification of ion channels and induction of cellular differentiation. Accordingly, we determined their amounts in several histologically defined types of ovarian carcinoma tissues. Sulfoglycolipids were determined by TLC-immunostaining with monoclonal anti-sulfatide antibodies and the gene expression of their synthetic enzymes was by RT-PCR. All types of ovarian carcinomas were revealed to exhibit potential to synthesize sulfoglycolipids, either sulfatide (I(3)SO3-GalCer) or sulfated lactosylceramides (II(3)SO3-LacCer), which were expressed at the following frequencies, 6 out of 6 mucinous cystadenocarcinomas, 4 out of 7 serous cystadenocarcinomas, 2 out of 3 endometrioid carcinomas, and 2 out of 3 clear cell adenocarcinomas. All mucinous cystadenocarcinoma tissues preferentially contained sulfatide in amounts of 0.61-1.13 µg per mg dry weight, the molecular species being similar with those of GalCer. Whereas the other carcinomas contained either sulfatide or sulfated LacCer, the latter being detected in 4 out of 6 specimens with sulfoglycolipids. The expression of sulfatide and sulfated LacCer was found to be positively correlated with the amounts of GalCer and LacCer as substrates for sulfotransferase and expression of the genes for GalCer sulfotransferase and ceramide galactosyltransferase. Sulfoglycolipids in ovarian carcinoma tissues were revealed to be expressed in morphologically defined type-characteristic manners, in contrast to the ubiquitous distribution of GM3.

The lifetime of UDP-galactose:ceramide galactosyltransferase is controlled by a distinct endoplasmic reticulum-associated degradation (ERAD) regulated by sigma-1 receptor chaperones.

The glycosphingolipid biosynthesis is initiated by monoglycosylation of ceramides, the action of which is catalyzed either by UDP-glucose:ceramide glucosyltransferase or by UDP-galactose:ceramide galactosyltransferase (CGalT). CGalT is expressed predominantly at the endoplasmic reticulum (ER) of oligodendrocytes and is responsible for synthesizing galactosylceramides (GalCer) that play an important role in regulation of axon conductance. However, despite the importance of ceramide monoglycosylation enzymes in a spectrum of cellular functions, the mechanism that fine tunes activities of those enzymes is largely unknown. In the present study, we demonstrated that the sigma-1 receptor (Sig-1R) chaperone, the mammalian homologue of a yeast C8-C7 sterol isomerase, controls the protein level and activity of the CGalT enzyme via a distinct ER-associated degradation system involving Insig. The Sig-1R forms a complex with Insig via its transmembrane domain partly in a sterol-dependent manner and associates with CGalT at the ER. The knockdown of Sig-1Rs dramatically prolonged the lifetime of CGalT without affecting the trimming of N-linked oligosaccharides at CGalT. The increased lifetime leads to the up-regulation of CGalT protein as well as elevated enzymatic activity in CHO cells stably expressing CGalT. Knockdown of Sig-1Rs also decreased CGalT degradation endogenously expressed in D6P2T-schwannoma cells. Our data suggest that Sig-1Rs negatively regulate the activity of GalCer synthesis under physiological conditions by enhancing the degradation of CGalT through regulation of the dynamics of Insig in the lipid-activated ER-associated degradation system. The GalCer synthesis may thus be influenced by sterols at the ER.

Quantification of seminolipid by LC-ESI-MS/MS-multiple reaction monitoring: compensatory levels in Cgt(+/⁻) mice.

Seminolipid, also known as sulfogalactosylglycerolipid (SGG), plays important roles in male reproduction. Therefore, an accurate and sensitive method for SGG quantification in testes and sperm is needed. Here we compare SGG quantitation by the traditional colorimetric Azure A assay with LC-ESI-MS/MS using multiple reaction monitoring (MRM). Inclusion of deuterated SGG as the internal standard endowed accuracy to the MRM method. The results showed reasonable agreement between the two procedures for purified samples, but for crude lipid extracts, the colorimetric assay significantly overestimated the SGG content. Using ESI-MS/MS MRM, C16:0-alkyl/C16:0-acyl SGG of Cgt(+/⁻) mice was quantified to be 406.06 ± 23.63 µg/g testis and 0.13 ± 0.02 µg/million sperm, corresponding to 78% and 87% of the wild-type values, respectively. CGT (ceramide galactosyltransferase) is a critical enzyme in the SGG biosynthesis pathway. Cgt⁻/⁻ males depleted of SGG are infertile due to spermatogenesis arrest. However, Cgt(+/⁻) males sire offspring. The higher than 50% expression level of SGG in Cgt(+/⁻) animals, compared with the wild-type expression, might be partly due to compensatory translation of the active CGT enzyme. The results also indicated that 78% of SGG levels in Cgt(+/⁻) mice were sufficient for normal spermatogenesis.

Modification of sphingoglycolipids and sulfolipids in kidney cell lines under heat stress: activation of monohexosylceramide synthesis as a ceramide scavenger.

Heat stress on Madin-Darby canine kidney cells increased ceramide content to 187% at 40 degrees C for 24 h, and the de novo synthesis from serine increased to 146%. Glucosylceramide (GlcCer) and galactosylceramide (GalCer) synthesis from ceramide, the first glycosylation step of sphingolipid metabolism in kidney cells, increased to 290% (GalCer) and 143% (GlcCer) after metabolic labeling with (14)C-glucose at 42 degrees C for 20 h. The more complex glycolipid lactosylceramide also increased to 151%, whereas sulfatide and ganglioside GM3 decreased to 21% and 43%, respectively. Sulfatide (SM4s) showed optimal sulfation at 37 degrees C, whereas cholesterol sulfate was optimally sulfated at 40 degrees C. The gene expression of ceramide glucosyltransferase (GluT), ceramide galactosyltransferase, and GalCer sulfotransferase (GST) after 24 h culture at 42 degrees C significantly increased to 714%, 221%, and 174%, respectively. Another kidney cell line, COS7, showed less activation of these transferases by heat stress. Although GST gene expression was higher under heat stress, SM4s synthesis decreased, which may have been due to increased GST sensitivity to a temperature higher than 37 degrees C. When we introduced the HSP70 gene into the expression vector and transfected the plasmid (pCDM-dHSP70) into kidney cells, GlcCer synthesis increased significantly. From these results, we speculated that HSP70 may play a role in GluT gene expression to increase GlcCer and decrease intracellular ceramide level.

Genetic dissection of the biosynthetic route to gentamicin A2 by heterologous expression of its minimal gene set.

Since the first use of streptomycin as an effective antibiotic drug in the treatment of tuberculosis, aminoglycoside antibiotics have been widely used against a variety of bacterial infections for over six decades. However, the pathways for aminoglycoside biosynthesis still remain unclear, mainly because of difficulty in genetic manipulation of actinomycetes producing this class of antibiotics. Gentamicin belongs to the group of 4,6-disubstituted aminoglycosides containing a characteristic core aminocyclitol moiety, 2-deoxystreptamine (2-DOS), and the recent discovery of its biosynthetic gene cluster in Micromonospora echinospora has enabled us to decipher its biosynthetic pathway. To determine the minimal set of genes and their functions for the generation of gentamicin A(2), the first pseudotrisaccharide intermediate in the biosynthetic pathway for the gentamicin complex, various sets of candidate genes from M. echinospora and other related aminoglycoside-producing strains were introduced into a nonaminoglycoside producing strain of Streptomyces venezuelae. Heterologous expression of different combinations of putative 2-DOS biosynthetic genes revealed that a subset, gtmB-gtmA-gacH, is responsible for the biosynthesis of this core aminocyclitol moiety of gentamicin. Expression of gtmG together with gtmB-gtmA-gacH led to production of 2'-N-acetylparomamine, demonstrating that GtmG acts as a glycosyltransferase that adds N-acetyl-d-glucosamine (GLcNA) to 2-DOS. Expression of gtmM in a 2'-N-acetylparomamine-producing recombinant S. venezuelae strain generated paromamine. Expression of gtmE in an engineered paromamine-producing strain of S. venezuelae successfully generated gentamicin A(2), indicating that GtmE is another glycosyltransferase that attaches d-xylose to paromamine. These results represent in vivo evidence elucidating the complete biosynthetic pathway of the pseudotrisaccharide aminoglycoside.

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.

Disruption of axo-glial junctions causes cytoskeletal disorganization and degeneration of Purkinje neuron axons.

Axo-glial junctions (AGJs) play a critical role in the organization and maintenance of molecular domains in myelinated axons. Neurexin IV/Caspr1/paranodin (NCP1) is an important player in the formation of AGJs because it recruits a paranodal complex implicated in the tethering of glial proteins to the axonal membrane and cytoskeleton. Mice deficient in either the axonal protein NCP1 or the glial ceramide galactosyltransferase (CGT) display disruptions in AGJs and severe ataxia. In this article, we correlate these two phenotypes and show that both NCP1 and CGT mutants develop large swellings accompanied by cytoskeletal disorganization and degeneration in the axons of cerebellar Purkinje neurons. We also show that alphaII spectrin is part of the paranodal complex and that, although not properly targeted, this complex is still formed in CGT mutants. Together, these findings establish a physiologically relevant link between AGJs and axonal cytoskeleton and raise the possibility that some neurodegenerative disorders arise from disruption of the AGJs.