It is unknown whether ascorbate alone (vitamin C), its oxidized metabolite dehydroascorbic acid alone, or both species are transported into human cells. This problem was addressed using specific assays for each compound, freshly synthesized pure dehydroascorbic acid, the specially synthesized analog 6-chloroascorbate, and a new assay for 6-chloroascorbate. Ascorbate and dehydroascorbic acid were transported and accumulated distinctly; neither competed with the other. Ascorbate was accumulated as ascorbate by sodium-dependent carrier-mediated active transport. Dehydroascorbic acid transport and accumulation as ascorbate was at least 10-fold faster than ascorbate transport and was sodium-independent. Once transported, dehydroascorbic acid was immediately reduced intracellularly to ascorbate. The analog 6-chloroascorbate had no effect on dehydroascorbic acid transport but was a competitive inhibitor of ascorbate transport. The Ki for 6-chloroascorbate (2.9-4.4 microM) was similar to the Km for ascorbate transport (9.8-12.6 microM). 6-Chloroascorbate was itself transported and accumulated in fibroblasts by a sodium-dependent transporter. These data provide new information that ascorbate and dehydroascorbic acid are transported into human neutrophils and fibroblasts by two distinct mechanisms and that the compound available for intracellular utilization is ascorbate.
De-N-acetylation of N-acetylglucosaminyl-phosphatidylinositol (GlcNAc-PI) is the second step of glycosylphosphatidylinositol (GPI) membrane anchor biosynthesis in eukaryotes. This step is a prerequisite for the subsequent mannosylation of glucosaminyl-phosphatidylinositol (GlcN-PI) which leads to mature GPI membrane anchor precursors, which are transferred to certain proteins in the endoplasmic reticulum. The substrate specificities of the GlcNAc-PI de-N-acetylase activities of African trypanosomes and human (HeLa) cells were studied with respect to the N-acyl groups (R) that could be removed from a series of GlcNR-PI substrates, where R = acetyl (Ac), propionyl (Pr), butyryl (Bu), isobutyryl (iBu), pentanoyl (Pen) or hexanoyl (Hex). The data show that the trypanosomal and HeLa enzymes had similar specificities and that the turnover of GlcNR-PIs by the trypanosomal enzyme was in the order GlcNAc-PI > GlcNPr-PI GlcNBu - PI ≈ GlcNiBu - PI ≈ GlcNPen - PI GlcNHex - PI. The trypanosome and HeLa de-N-acetylases were unable to de-N-acetylate mannosylated GlcNAc-PI intermediates, which explains why de-N-acetylation must precede mannosylation in the GPI biosynthetic pathway.
The substrate speci®cities of Trypanosoma brucei and human (HeLa) GlcNAc-PI de-N-acetylases were determined using 24 substrate analogues. The results show the following. (i) The de-N-acetylases show little speci®city for the lipid moiety of GlcNAc-PI. (ii) The 3¢-OH group of the GlcNAc residue is essential for substrate recognition whereas the 6¢-OH group is dispensable and the 4¢-OH, while not required for recognition, cannot be epimerized or substituted. (iii) The parasite enzyme can act on analogues containing bGlcNAc or aromatic N-acyl groups, whereas the human enzyme cannot. (iv) Three GlcNR-PI analogues are de-N-acetylase inhibitors, one of which is a suicide inhibitor. (v) The suicide inhibitor most likely forms a carbamate or thiocarbamate ester to an active site hydroxy-amino acid or Cys or residue such that inhibition is reversed by certain nucleophiles. These and previous results were used to design two potent (IC 50 = 8 nM) parasite-speci®c suicide substrate inhibitors. These are potential lead compounds for the development of anti-protozoan parasite drugs.
It has been suggested that compounds affecting glycosylphosphatidylinositol (GPI) biosynthesis in bloodstream form Trypanosoma brucei should be trypanocidal. We describe cell-permeable analogues of a GPI intermediate that are toxic to this parasite but not to human cells. These analogues are metabolized by the T. brucei GPI pathway, but not by the human pathway. Closely related nonmetabolizable analogues have no trypanocidal activity. This represents the first direct chemical validation of the GPI biosynthetic pathway as a drug target against African human sleeping sickness. The results should stimulate further inhibitor design and synthesis and encourage the search for inhibitors in natural product and synthetic compound libraries.
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