Abstract
Ganglioside GD1a-GalNAc was isolated from Tay-Sachs brain, tritium-labeled in its sphingosine moiety, and its enzymic degradation studied in vitro and in cultured fibroblasts. When offered as micelles, GD1a-GalNAc was almost not hydrolyzed by Hex A or Hex B, while after incorporation of the ganglioside into the outer leaflet of liposomes, the terminal GalNAc residue was rapidly split off by Hex a. In striking contrast to ganglioside GM2, the major glycolipid substrate of Hex A, the enzymic hydrolysis of GD1a-GalNAc was not promoted by the GM2 activator protein, although the activator protein did bind GD1a-GalNAc to form a water-soluble complex. Pathobiochemical studies corroborate these results. After incorporation of [3H]GD1a-GalNAc into cultured skin fibroblasts from healthy subjects and from patients with different variants of GM2 gangliosidosis, its degradation was found to be strongly attenuated in mutant cells with Hex A deficiencies such as variant B (Tay-Sachs disease), variant B1 and variant 0 (Sandhoff disease), while in cells with variant AB (GM2 activator deficiency), its catabolism was blocked only at the level of GM2. In line with these metabolic studies, a normal content of GD1a-GalNAc was found in brains of patients who had succumbed to variant AB of GM2 gangliosidosis whereas in brains from variants B, B1, and 0, its concentration was considerably elevated (up to 19-fold). Together with studies on the enzymic degradation of GM2 derivatives with modifications in the ceramide portion, these results indicate that mainly steric hindrance by adjacent lipid molecules impedes the access of Hex A to membrane-bound GM2 (whose degradation therefore depends on solubilization by the GM2 activator) and in addition that the interaction between the GM2. GM2 activator complex and the enzyme must be highly specific.
Highlights
Sachs brain, tritium-labeled iints sphingosine moiety, dases
In striking contrast to ganglioside GM2t,he major glycolipid substrate of Hex A, the enzymic hydrolysis ofGD1,GalNAc was not promoted by the GMz activator protein, the activatorprotein did bind GDl,GalNAc to form a addition requires the presence of a water-soluble, nonenzymatic protein, the G Ma~ctivator (Sandhoff et al, 1989).The human GMzactivator has been purified from kidney (Conzelmann and Sandhoff, 1979) and liver (Li et aL, 1981b)
B’ and variant 0 (Sandhoff disease),while in cells with and variant 0 (deficiency of P-chain, Sandhoff et al, 1968; variant AB(GMz activator deficiency), its catabolism Sandhoff et al, 1971).In addition, a variant allelic to a-chain was blocked only at the level of GM2. In line with these deficiency has been described that due to a point mutation metabolic studies, a normal content ofGD1.-GalNAc does no longer possess an active site on the P-hexosaminidase siwvferiaodasrmesoiranfanovbtutahlnryeAidaeBeninonltzefsybvBmraaGt,ieiMcnBddz(s’ue,ogpgafanrtnpaodgdal0at1iito,9eiison-tifntsdosocolwdosfi)nhGs.coweTMhnhoadtegrd~eareresttiiuahvosceancrtiinuvwwmbeairsbtsahecidwnosnstitot-uhd-aS1-9ocT8nh8hda;eeiTrnfm(aevnleadacrkehiataananelti.t,sma1lB9.,8o’1,5f9bLa9;cTi0t)aie.ontnaakola.f, 1981a; Kytzia et al, 1983; et al, 1988;Ohno and Suzuki, the GM, activator has been modifications in the ceramide portion, these results studied in some detail
Summary
GMZ, I13NeuAc-Ggose3Cer or 4Gal~1-3GalNAc@l-4Ga1(3-2aNeuAc)@l-4Glc~l-1Cer;G~~~-GalNAc, GalNAc~l-4Gal(3-2aNeuAc)@l-4Glcpl-lCeNr-;diazirinyl-lyso-GM2, IV4GalNAc, IVqNeuG1-GgOse4Cer, or GalNAc@1-4Ga1(3-2aNeuGI) 5~4[3(trifluoromethyl)diazirinyl]-phenyl)pentanoyl-N-lyso-GMf.~w;., @l-3GalNAc@l-4Galpl-4Glc@l-lCerH;ex A, @-hexosaminidaseA; fresh weight;GalNAc: N-acetyl-galactosamine;GA2, GgosesCer or Hex B, @-hexosaminidase B4; -MUGlcNAc, 4-methyl-umhellifery1-2GalNAcpl-4Gal~l-4Glc@l-1CeGrD;1,, IV3NeuAc, II”NeuAc-Ggose, acetamido-2-deoxy-~-~-glucopyranosi4d-Me;U-GlcNAc-6-sulfate, 4Cero,r NeuAcol2-3Gal~l-3GaINAc@l-4Ga1(3-2olNeuAc)@l-4Glcplm-ethylumbelliferyl-2-acetamido-2-deoxy-6-sulfo-@-~-glucopyrano-. In an attempt tosolve this problem, we have studied the degradation of the disialoganglioside GDl,-GalNAcby human 0hexosaminidases. This ganglioside contains in an identical configuration the same three terminal sugars a s G Mbu~t, two monosaccharideunits more remote fromthe ceramidepart of the molecule (Fig. 5A). Studies on the enzymic degradation of GDla-GalNAcin vitro and pathobiochemicalinvestigations should give an answer to thequestion whether G Ma~ctivator dependence of degradation is a general feature of membraneinserted glycolipidsubstrates of Hex A or is restricted to some lipid substrates (such as G M a~nd GA2) only. Studies on the interaction between GD1,-GalNAcG, Ma~ctivator, and Hex A should provide further insight into the substrate specificity,mechanism of action, and physiological relevance of the GM2 activator protein. A Determinations were performed in duplicates; deviations were less than 5%unless indicated
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