Inefficient processing of human protein C in the mouse mammary gland.

Vitamin K-dependent plasma protein, human Protein C (HPC) has been expressed in transgenic mice, using a 4.2 kb mouse whey acidic protein (WAP) promoter, 9.0 kb HPC gene and 0.4 kb 3' flanking sequences. Expression was mammary gland-specific and the recombinant human Protein C (rHPC) was detected in milk at concentrations of 0.1 to 0.7 mg ml-1. SDS-PAGE revealed that the single, heavy and light chains of rHPC migrated with increased electrophoretic mobility, as compared to HPC. Enzymatic deglycosylation showed that these molecular weight disparities are in part due to differential glycosylation. The substantial increase observed in the amount of single chain protein, as well as the presence of the propeptide attached to 20-30% of rHPC, suggest that mouse mammary epithelial cells are not capable of efficient proteolytic processing of rHPC. The Km of purified rHPC for the S-2366 synthetic substrate was similar to that of plasma-derived HPC, while the specific activity was about 42-77%. Amino acid sequence analyses and low anticoagulant activity of purified rHPC suggest that gamma-carboxylation of rHPC is insufficient. These results show that proteolytic processing and gamma-carboxylation can be limiting events in the overexpression of fully biologically active rHPC in the mouse mammary gland.

Construction and characterization of a single-chain catalytic antibody.

The antigen-binding (Fab) fragment of the catalytic monoclonal antibody NPN43C9 has recently been cloned by using bacteriophage lambda. By inserting the variable regions of this Fab coding sequence into a (NH2)-VL-linker-VH-(COOH) construct (where VL and VH represent the heavy and light chain variable regions), we have assembled a recombinant gene encoding a catalytic single-chain antigen-binding protein. This protein has been expressed in Escherichia coli and exhibits the same catalytic parameters as the parent monoclonal antibody NPN43C9. Single-chain forms of catalytic antibodies may prove valuable for structural and site-directed mutagenesis studies as well as for large-scale applications of catalytic antibodies.

L-asparaginase from Erwinia carotovora. An improved recovery and purification process using affinity chromatography.

A large-scale process was developed to purify L-asparaginase from submerged cultures of Erwinia carotovora. Cells from 880 L of fermentation broth were harvested and washed using a plate and frame type filter press. A cellular acetone powder was prepared from the washed cells by suspending the cells twice in acetone and the residual acetone was removed by washing the acetone powder in the filter press with 10 mM phosphate buffer (pH 7.0). The cellular acetone powder was extracted with 10 mM borate buffer at pH 9.5. The enzyme-rich borate extract was recovered by filtration and clarified by an in-line bag filter. The filtrate was adjusted to pH 7.5 and filtered through a 1-micron bag filter precoated with Celite and then through a 0.22-micron cartridge filter. The cell-free extract, containing 21 x 10(6) IU of enzyme and 448 g of total protein, was applied to an L-asparagine Sepharose 6 Fast Flow affinity column (9 L) using a bag filter loaded with Cell Debris Remover as an in-line prefilter. The affinity gel was prepared by coupling L-Asn at pH 9.0 to epoxy-activated Sepharose 6 Fast Flow beads. A total of 14 x 10(6) IU of enzyme (35 g protein) was eluted at pH 9.0 in 10.5 L. The eluted enzyme was determined to be greater than 90% pure using sodium dodecyl sulfate polyacrylamide gel electrophoresis. The total process time from whole broth to affinity column elution was 68 h and the enzyme yield was 38%. This improved process for the 880 L fermentation broth produced a cell-free extract of high specific activity, shortened the process time, increased the column capacity, and yielded a product with high purity.

Large-scale recovery and purification of L-asparaginase from Erwinia carotovora.

A large-scale process was developed to purify gram quantities of a therapeutic enzyme, L-asparaginase, from submerged cultures of Erwinia carotovora. Cells were harvested from 150 L of fermentation broth and washed. A cellular acetone powder was prepared and extracted with pH 9.5 borate buffer. After continuous centrifugation and filtration to remove cell debris, the acetone powder extract was adjusted to pH 7.7 and adsorbed onto a 16-L CM-Sepharose Fast Flow column, with a precolumn packed with Cell Debris Remover. The enzyme was desorbed from the catin-exchange column at pH 9.0 and further purified with an affinity column of L-asparagine Sepharose CL-4B. After dialysis-concentration to remove buffer salt, the enzyme was depyrogenated, formulated, sterile filled, and lyophilized as a single-dose final product. The final-product evaluation included analysis of the content of protein, sodium chloride, glycine, sodium, glucose hydrate, phosphate, and endotoxin, as well as reconstitution, potency, pH, specific activity, uniformity of fill, and sterility. The product was further subjected to visual examination, sodium dodecyl sulfate polyacrylamide gel electrophoresis, native gel electrophoresis, isoelectric focusing, amino acid analysis, N-terminal sequencing, peptide mapping, and immunological comparison.