Abstract
In this study, the substrate specificity of a newly identified rat brain ceramidase (CDase) was investigated. To this end, the major functional groups and stereochemistry of ceramide (Cer) were evaluated for their influence on the hydrolysis of substrate by this CDase. The results showed that, of the four possible stereoisomers of Cer, only the natural d-e-C(18)-Cer isomer was used as substrate (K(m) of 1.1 mol% and V(max) of 5 micromol/min/mg). Removal of the 4-5 trans double bond to generate dihydroceramide decreased the affinity of the enzyme toward its substrate by around 90%, whereas changing the configuration of the double bond from the natural trans configuration into cis or introduction of a hydroxyl group (phytoceramide) resulted in loss of hydrolysis. Shortening the chain length of the sphingosine backbone resulted in decreased affinity. Methylation of either the primary or the secondary hydroxyl groups resulted in loss of activity. Results also indicated that Cer species that harbor long saturated or monounsaturated fatty acyl chains are preferred substrates of the enzyme. alpha-Hydroxylated Cer demonstrated considerably higher affinity, indicating a preference of the enzyme to those Cer molecular species. These results disclose a very high specificity of nonlysosomal CDase for its substrate, Cer.
Highlights
In this study, the substrate specificity of a newly identified rat brain ceramidase (CDase) was investigated
The results indicated that all three isomers inhibited the hydrolysis of the substrate by 50% at a concentration of 2.5 mol% (Fig. 2A)
The results indicated that phytoceramide was not a substrate for the CDase (Table 1)
Summary
Merck-Lipha/INSERM U352, Diabetic Microangiopathy Research Unit, INSA-Lyon, 69621 Villeurbanne, France. The results showed that of the four stereoisomers of Cer, only the d-erythro isomer was used as a substrate They indicated that the preferred substrates of the enzyme are species that harbor a long sphingoid base (C18:1) with a trans double bond, and a long saturated or monounsaturated (C16:0-C18:0) or a very long monounsaturated (C24:1) fatty acyl chain. The results indicated a strict requirement for i) the d-erythro isomer, ii) the secondary amide group, iii) the 4-5 trans double bond, and iv) free hydroxyl groups at the C1 and C3 positions. The implications of these results are discussed with respect to the catalytic mechanism and possible physiologic significance
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