Abstract
Human acid ceramidase ((AC) N-acylsphingosine amidohydrolase, EC 3.5. 1.23) hydrolyzes the sphingolipid ceramide into sphingosine and free fatty acid. Ceramide is an essential component of all sphingolipids and an important cell-signaling molecule. Moreover, an inherited deficiency of AC activity leads to the lysosomal storage disorder known as Farber disease. Human AC was purified from urine, and 117 amino acid residues were determined by microsequencing. Degenerative oligonucleotide probes were then constructed and used to screen for human fibroblast and pituitary cDNA libraries. Several partial cDNA clones were obtained, and two of these were combined to construct a full-length cDNA containing a 17-base pair (bp) 5'-untranslated sequence, a 1185-bp open reading frame encoding 395 amino acids, a 1110-bp 3'-untranslated sequence, and an 18-bp poly(A) tail. Transient expression of the full-length cDNA in COS-1 cells led to a 10-fold increase in AC activity. In addition, biosynthetic studies carried out in the transfected cells demonstrated that 13-kDa (alpha) and 40-kDa (beta) AC subunits were derived from a common 55-kDa precursor encoded by the full-length cDNA. This protein pattern was identical to that seen in normal human skin fibroblasts. A homoallelic point mutation (T222K) was also identified in the AC gene of a patient suffering from Farber disease, further confirming the authenticity of the full-length cDNA.
Highlights
Human acid ceramidase ((AC) N-acylsphingosine amidohydrolase, EC 3.5.1.23) hydrolyzes the sphingolipid ceramide into sphingosine and free fatty acid
DNA sequence analysis revealed that the predicted amino acid sequence of this cDNA was colinear with all of the AC amino acid residues determined by microsequencing and that the N-terminal amino acid codon of the -subunit corresponded to an internal region of the cDNA
Ceramide plays a critical role in normal cell function and disease pathogenesis
Summary
Jurgen Koch‡, Sabine Gartner‡§, Chi-Ming Li¶, Lothar E. Biosynthetic studies carried out in the transfected cells demonstrated that 13-kDa (␣) and 40-kDa () AC subunits were derived from a common 55-kDa precursor encoded by the full-length cDNA This protein pattern was identical to that seen in normal human skin fibroblasts. Metabolic labeling and immunoprecipitation analyses indicated that both subunits arose from a single precursor of ϳ55 kDa by proteolytic processing This manuscript reports the isolation and characterization of a full-length cDNA encoding human AC and the identification of the first molecular lesion causing FD. The availability of this cDNA should facilitate further molecular genetic analysis of FD patients and stimulate additional studies defining the role of AC in ceramide metabolism, cell differentiation, and mammalian development
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