High-molecular-weight alkaline phosphatase in serum has properties similar to the enzyme in plasma membranes of the liver.

Partially purified high-molecular-weight alkaline phosphatase from serum was compared with two other forms of the enzyme from the human liver, enzyme in native plasma membranes and purified alkaline phosphatase as a hydrophilic dimer. In a high-molecular-weight form from serum and plasma membranes, and when treated with 1% (v/v) Triton X-100, alkaline phosphatase showed a major band on gradient gel electrophoresis with a mobility equivalent to 400 kD. Nondetergent-treated material from both sources did not enter the gel and was in the voided volume of a gel permeation column. Stimulation of catalytic activity by four different phospholipids and by albumin yielded similar results for high-molecular-weight alkaline phosphatase and for the enzyme in plasma membranes, but these were different from the hydrophilic form. Inhibitors of alkaline phosphatase had similar effects on all forms. Of the three forms of the enzyme, only the hydrophilic dimer did not become incorporated into liposomes or adsorb to octyl-Sepharose after solubilization with Triton X-100 and removal of the detergent. Km (substrate concentration to give half maximal velocity) values with p-nitrophenylphosphate and heat and sodium dodecyl sulfate stabilities were similar for all forms. In the high-molecular-weight form from serum and in plasma membranes, alkaline phosphatase and 5'-nucleotidase showed similar rates of release by phosphatidylinositol phospholipase C. Three preparations of phospholipase D failed to release alkaline phosphatase from either the high-molecular-weight form or from plasma membranes. Based on these similarities, it is probable that the complex of high-molecular-weight alkaline phosphatase in serum most often originates from fragments of hepatic plasma membranes.

Properties of amphiphilic and hydrophilic forms of alkaline phosphatase from human liver.

Amphiphilic and hydrophilic forms of alkaline phosphatase differed in electrophoretic mobility, sensitivity to heat, activation by phospholipids and albumin, and affinity of monoclonal antibodies, but were similar in substrate Km and inhibitor Ki values, sensitivity to sodium dodecyl sulfate, and electrophoretic behavior on desialylation. Chemical cross-linking experiments failed to conclusively demonstrate an aggregated state of amphiphilic alkaline phosphatase in Triton X-100. Further, attempts to identify a polymeric hybrid between amphiphilic forms of human liver and placental alkaline phosphatase were unsuccessful. We conclude that the covalent attachment of the hydrophobic phosphatidyl-inositol membrane anchor causes the amphiphilic form to behave anomalously on electrophoresis and to affect certain of the enzyme's catalytic and physical properties.

Incorporation of human liver and placental alkaline phosphatases into liposomes and membranes is via phosphatidylinositol.

As assessed by incorporation into liposomes and by adsorption to octyl-Sepharose, the integrity of the membrane anchor for the purified tetrameric forms of alkaline phosphatase from human liver and placenta was intact. Any treatment that resulted in a dimeric enzyme precluded incorporation and adsorption. An intact anchor also allowed incorporation into red cell ghosts. The addition of hydrophobic proteins inhibited incorporation into liposomes to varying degrees. Alkaline phosphatase was 100% releasable from liposomes and red cell ghosts by a phospholipase C specific for phosphatidylinositol. There was no appreciable difference in the rates of release of placental and liver alkaline phosphatases, although both were approximately 250 x slower in liposomes and 100 x slower in red cell ghosts than the enzyme's release from a suspension of cultured osteosarcoma cells. Both enzymes were released by phosphatidylinositol phospholipase C as dimers and would not reincorporate or adsorb to octyl-Sepharose. However, the enzyme incorporated, resolubilized by Triton X-100, and cleansed of the detergent by butanol treatment was tetrameric by gradient gel electrophoresis, was hydrophobic, and could reincorporate into fresh liposomes. A monoclonal antibody to liver alkaline phosphatase inhibited the enzyme's incorporation into liposomes, and abolished its release from liposomes and its conversion to dimers by phosphatidylinositol phospholipase C.