A model system for the analysis of intracellular events governing the modification of individual vitamin K-dependent (VKD) proteins by the carboxylase has been developed using recombinant VKD protein-transfected cell lines. When untransfected 293 cells were analyzed by in vitro carboxylation followed by SDS-PAGE, endogenous VKD proteins were not detected. With 293 cells stably-transfected with recombinant native factor IX, most (> 95%) of the carboxylase was in complex with the factor IX, as assayed by adsorption of carboxylase activity to immobilized anti-factor IX antibody. In contrast, with 293 cells stably-transfected with recombinant factor IX deleted in the propeptide sequence (amino acids -18 to -4, delta pro factor IX), no association of factor IX with the carboxylase was observed. This observation was used to specifically isolate and identify the human carboxylase, and carboxylase-associated protein. When the carboxylase was purified from solubilized microsomes from either native factor IX, or delta pro factor IX, stably-transfected 293 cells, a single 98 kDa band was specifically obtained from native factor IX microsomes, but not from delta pro factor IX microsomes. This band was subsequently shown by Western and microsequencing analysis to comprise both the carboxylase and carboxylase-associated protein. This isolation, which represents the first isolation to near homogeneity of both the human carboxylase and the carboxylase from cell lines, will be valuable in isolating enzymatically active recombinant carboxylase, which has been refractile to other purification attempts. This system was also used to show that the human carboxylase in 293 cells is capable of binding and modifying two different liver-derived proteins. Protein C-producing 293 cells were generated from the same 293 progenitor cell line used to created the factor IX-expressing cells. With both factor IX- and protein C-transfected 293 cells, the secreted proteins were almost completely carboxylated, and in microsomes from each cell line the carboxylase was found in near quantitative complex with the two different VKD proteins. Thus the carboxylase modifies both VKD proteins. The approach described here for the analysis of the carboxylase from recombinant VKD protein-transfected cell lines should provide an important new system for studying protein carboxylation and VKD protein-carboxylase interaction.
The microsomal y-carboxylase catalyzes modification of a limited set of glutamyl residues to y-carboxyglutamyl residues in a vitamin K-dependent reaction that also utilizes 02 and CO2. We report the purification to apparent homogeneity of the bovine liver microsomal carboxylase. Affinity chromatography exploiting the association of the carboxylase with prothrombin precursor and carboxylase binding to the propeptide sequence were combined with ion-exchange chromatography and fractionation using immobilized lectins. A 3.5 x 105-fold purification was obtained, which is the highest purification, by a factor of 35, yet reported for this enzyme. A single 98-kDa protein is obtained from this isolation. Carboxylase activity is associated with this protein by two different criteria. Antibodies prepared against the carboxylase detected the 98-kDa protein when used in Western analysis. In addition, the single 98-kDa protein was shown to comigrate with activity when electrophoresed in a nondenaturing gel system. The availability of purified preparations of carboxylase will facilitate an increased understanding of the complex biochemical reaction carried out by this protein.The liver microsomal carboxylase catalyzes the posttranslational modification of selected glutamyl residues to Y-carboxylated glutamyl (Gla) residues in a limited set of proteins in a reaction requiring vitamin K hydroquinone, 02, and CO2 (1-3). These vitamin K-dependent proteins contain multiple glutamyl residues clustered at the N terminus in what is referred to as the Gla domain. Carboxylation of glutamyl residues in the Gla domain enables the Ca2+-mediated interaction ofthese proteins with phospholipids and is required for their biological activity. Vitamin K-dependent carboxylase activity has been detected in almost all mammalian tissues assayed and has been observed in one invertebrate as well (4). Its apparent presence in a wide variety of cultured lines can also be inferred from the ability of these lines to secrete carboxylated vitamin K-dependent recombinant proteins (5-10). A major limitation in understanding the mechanism of carboxylation has been the lack of a purified preparation of this enzyme. Attempts pmade using selective detergent extraction, ammonium sulfate fractionation, and conventional chromatography have been successful only in a limited purification (11-13). More recently, the propeptide sequence unique to all vitamin K-dependent proteins has been used in attempts to purify the carboxylase (14-16). This sequence is similar among vitamin K-dependent proteins that share very little other homology, leading to the proposal that the propeptide sequence is important for carboxylase recognition (17). The observations that mutations in protein C (18) or factor IX (19) impair carboxylation supported this concept. Carboxylase purifications have been attempted by using the propeptide as a ligand in affinity chromatography (15,16). The enzyme has also been isolated by virtue of its known association with its vitamin K-dependent prote...
THP-1 is an acute monocytic leukemia cell line which acquires phenotypic and functional monocytoid-like features following incubation with mezerein. The current study concerned the modulation of these features by rIFN gamma. rIFN gamma induces the time-dependent enhancement of HLA-DR expression in the presence or absence of mezerein but has no effect on the expression of Leu-M1, Leu-M2, or Leu-M3 antigens. CSF-1 production following mezerein activation was reduced by incubation in the presence of 10(3) and 10(4) units/ml rIFN gamma. This was confirmed through both biological assays with mouse bone marrow cells and an indirect ELISA. In contrast, the concentration of growth inhibitory activity in conditioned medium was increased by rIFN gamma. A small but significant increase in IL-1 beta concentration in conditioned medium was detected using a sensitive double-antibody ELISA and a radioimmunoassay. The results infer that the functional characteristics of this leukemia cell line are modulated by rIFN gamma in a manner qualitatively similar to that reported for IFN gamma treated normal monocytes.
The human monocytic leukemia cell line, THP-1, acquires macrophage-like characteristics following exposure to mezerein. Serum-free medium conditioned by mezerein-activated cells was observed to contain colony-stimulating factor (CSF) activity in assays with murine bone marrow cultures. Isoelectrofocusing revealed that CSF activity displayed charge heterogeneity and migrated in a pl range of 4.4-5.3. Treatment with neuraminidase did not affect biological activity but did reduce charge heterogeneity. Reisofocusing of neuraminidase-treated CSF revealed a peak of activity at pl 4.9. The active component was shown to be an acidic sialoglycoprotein, resistant to proteolytic cleavage but completely inactivated by 2-mercaptoethanol. This CSF has been purified from THP-1-conditioned serum-free medium by preparative isoelectrofocusing, gel filtration through Sephacryl S-200, ion exchange chromatography on DEAE-Sephacel, neuraminidase treatment, and tris-glycinate polyacrylamide gel electrophoresis (PAGE). Elution from SDS-PAGE revealed a single peak of activity corresponding to an apparent molecular weight of 70,000 daltons. Preliminary characterization of the bone marrow cells in colonies showed that THP-1 cells produced macrophage-specific CSF.
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