Login / Signup

The Uptake of Heparanase into Mast Cells Is Regulated by Its Enzymatic Activity to Degrade Heparan Sulfate.

Jia ShiYoshiki OnukiFumiya KawanamiNaoko MiyagawaFumika IwasakiHaruna TsudaKatsuhiko TakahashiTeruaki OkuMasato SuzukiKyohei HigashiHayamitsu AdachiYoshio NishimuraMotowo NakajimaTatsuro IrimuraNobuaki Higashi
Published in: International journal of molecular sciences (2024)
Mast cells take up extracellular latent heparanase and store it in secretory granules. The present study examined whether the enzymatic activity of heparanase regulates its uptake efficiency. Recombinant mouse heparanase mimicking both the latent and mature forms (L-Hpse and M-Hpse, respectively) was internalized into mastocytoma MST cells, peritoneal cell-derived mast cells, and bone marrow-derived mast cells. The internalized amount of L-Hpse was significantly higher than that of M-Hpse. In MST cells, L-Hpse was continuously internalized for up to 8 h, while the uptake of M-Hpse was saturated after 2 h of incubation. L-Hpse and M-Hpse are similarly bound to the MST cell surface. The expression level of cell surface heparan sulfate was reduced in MST cells incubated with M-Hpse. The internalized amount of M-Hpse into mast cells was significantly increased in the presence of heparastatin (SF4), a small molecule heparanase inhibitor that does not affect the binding of heparanase to immobilized heparin. Enzymatically quiescent M-Hpse was prepared with a point mutation at Glu335. The internalized amount of mutated M-Hpse was significantly higher than that of wild-type M-Hpse but similar to that of wild-type and mutated L-Hpse. These results suggest that the enzymatic activity of heparanase negatively regulates the mast cell-mediated uptake of heparanase, possibly via the downregulation of cell surface heparan sulfate expression.
Keyphrases
  • cell surface
  • wild type
  • induced apoptosis
  • small molecule
  • poor prognosis
  • cell cycle arrest
  • hydrogen peroxide
  • signaling pathway
  • nitric oxide
  • mesenchymal stem cells
  • endoplasmic reticulum stress