Functional and structural consequences of aromatic residue substitutions within the kringle-2 domain of tissue-type plasminogen activator.

Aromatic amino acid residues within kringle domains play important roles in the structural stability and ligand-binding properties of these protein modules. In previous investigations, it has been demonstrated that the rigidly conserved Trp25 is primarily involved in stabilizing the conformation of the kringle-2 domain of tissue-type plasminogen activator (K2tpA), whereas Trp63, Trp74, and Tyr76 function in omega-amino acid ligand binding, and, to varying extents, in stabilizing the native folding of this kringle module. In the current study, the remaining aromatic residues of K2tPA, viz., Tyr2, Phe3, Tyr9, Tyr35, Tyr52, have been subjected to structure-function analysis via site-directed mutagenesis studies. Ligand binding was not significantly influenced by conservative amino acid mutations at these residues, but a radical mutation at Tyr35 destabilized the interaction of the ligand with the variant kringle. In addition, as reflected in the values of the melting temperatures, changes at Tyr9 and Tyr52 generally destabilized the native structure of K2tPA to a greater extent than changes at Tyr2, Phe3, and Tyr35. Taken together, results to date show that, in concert with predictions from the crystal structure of K2tpA, ligand binding appears to rely most on the integrity of Trp63 and Trp74, and aromaticity at Tyr76. With regard to aromatic amino acids, kringle folding is most dependent on Tyr9, Trp25, Tyr52, Trp63, and Tyr76. As yet, no obvious major roles have been uncovered for Tyr2, Phe3, or Tyr35 in K2tpA.

Enhancement through mutagenesis of the binding of the isolated kringle 2 domain of human plasminogen to omega-amino acid ligands and to an internal sequence of a Streptococcal surface protein.

In the background of the recombinant K2 module of human plasminogen (K2(Pg)), a triple mutant, K2(Pg)[C4G/E56D/L72Y], was generated and expressed in Pichia pastoris cells in yields exceeding 100 mg/liter. The binding affinities of a series of lysine analogs, viz. 4-aminobutyric acid, 5-aminopentanoic acid, epsilon-aminocaproic acid, 7-aminoheptanoic acid, and t-4-aminomethylcyclohexane-1-carboxylic acid, to this mutant were measured and showed up to a 15-fold tighter interaction, as compared with wild-type K2(Pg) (K2(Pg)[C4G]). The variant, K2(Pg)[C4G/E56D], afforded up to a 4-fold increase in the binding affinity to these same ligands, whereas the K2(Pg)[C4G/L72Y] mutant decreased the same affinities up to 5-fold, as compared with K2(Pg)[C4G]. The thermal stability of K2(Pg)[C4G/E56D/L72Y] was increased by approximately 13 degrees C, as compared with K2(Pg)[C4G]. The functional consequence of up-regulating the lysine binding property of K2(Pg) was explored, as reflected by its ability to interact with an internal sequence of a plasminogen-binding protein (PAM) on the surface of group A streptococci. A 30-mer peptide of PAM, containing its K2(Pg)-specific binding region, was synthesized, and its binding to each mutant of K2(Pg) was assessed. Only a slight enhancement in peptide binding was observed for K2(Pg)[C4G/E56D], compared with K2(Pg)[C4G] (K(d) = 460 nM). A 5-fold decrease in binding affinity was observed for K2(Pg)[C4G/L72Y] (K(d) = 2200 nM). However, a 12-fold enhancement in binding to this peptide was observed for K2(Pg)[C4G/E56D/L72Y] (K(d) = 37 nM). Results of these PAM peptide binding studies parallel results of omega-amino acid binding to these K2(Pg) mutants, indicating that the high affinity PAM binding by plasminogen, mediated exclusively through K2(Pg), occurs through its lysine-binding site. This conclusion is supported by the 100-fold decrease in PAM peptide binding to K2(Pg)[C4G/E56D/L72Y] in the presence of 50 mM 6-aminohexanoic acid. Finally, a thermodynamic analysis of PAM peptide binding to each of these mutants reveals that the positions Asp(56) and Tyr(72) in the K2(Pg)[C4G/E56D/L72Y] mutant are synergistically coupled in terms of their contribution to the enhancement of PAM peptide binding.

Expression of human plasminogen in Drosophila Schneider S2 cells.

The cDNA that encodes full-length human plasminogen (Glu1-hPg) has been expressed in Drosophila Schneider S2 cells under the influence of the Drosophila BiP protein signal sequence, which allowed the protein to be secreted into the medium. A procedure was devised for clonal selection of high-expressing cells, which were then used for large-scale expression of 10-15 mg/liter of the protein in the culture medium. The protein produced using this system was extensively characterized and contained full-length recombinant (r) Glu1-hPg plasminogen. As with human plasma Glu1-hPg, the S2-expressed protein underwent the Cl--induced transition to the tight conformation, which resulted in a weakly activatable zymogen. The addition of the ligand, epsilon-amino caproic acid, induced the relaxed conformation of r-Glu1-hPg, which was highly activatable, again in agreement with similar data for human plasma Glu1-hPg. The thermal stability of the S2-expressed r-Glu1-hPg also correlated well with that of human plasma hPg. These studies show that intact r-Glu1-hPg can be produced in high yield in Drosophila Schneider S2 cells, which possesses similar properties to its human plasma counterpart.

Glycosylation properties of the Pichia pastoris-expressed recombinant kringle 2 domain of tissue-type plasminogen activator.

The oligosaccharide structures present on Asn5 of the Pichia pastoris-expressed recombinant kringle 2 domain of tissue-type plasminogen activator [(r)-[K2tPA]] have been determined by a combination of techniques, including HPLC, FPLC, gel filtration, endoglycosidase digestions and mass spectrometry. The major oligosaccharides identified after their liberation by either hydrazinolysis or by the enzyme peptide:N4-(N-acetyl-beta-glucosaminyl)asparaginyl amidase, were in the oligomer range of (mannose)8(N-acetylglucosamine)2 (Man8GN2) to Man18GN2. The preponderance of these glycans spanned Man9GN2 to Man12GN2, and the major overall product was Man10GN2. An additional (less than 5%) amount of the polypeptide was hyperglycosylated. In contrast with glycoproteins produced in Saccharomyces cerevisiae, our results with specific mannosidase digestions were consistent with previous studies showing that (alpha 1,3)-linked mannose residues were not present in extensions of the core Man8GN2 unit. The results show that the N-linked glycosylation pathways in P. pastoris are substantially different from those found in S. cerevisiae, with shorter Man(alpha 1,6) extensions to the core Man8GN2 and the apparent lack of significant Man(alpha 1,3) additions representing the major processing modality of N-linked glycans in P. pastoris.

High-level secretion in Pichia pastoris and biochemical characterization of the recombinant kringle 2 domain of tissue-type plasminogen activator.

The kringle 2 (K2) domain of tissue-type plasminogen activator (tPA) has been expressed in Pichia pastoris cell lines GSI 15 and KM71. This construct contained a hexahistidine sequence at the C-terminus of the kringle to aid in purification by immobilized metalion-affinity chromatography. The exact amino acid sequence of the isolated kringle was EAEAYV-[K2tPA]SR(H)6, where [K2tPA] represents amino acid sequence residues C1-C82 of the kringle domain (residues 180-261 of tPA). The clones of the yeast transformants provided large amounts of the recombinant (r)-[K2tPA]-containing polypeptide at levels that allowed ready purification of several hundred mg from shake flasks and near-gram levels from a high-biomass fermenter. Purification of the kringle domain directly from cell-conditioned media was accomplished in a single step by either immobilized Ni(+)-affinity chromatography or lysine-Sepharose affinity chromatography. N-linked glycans were present on approx. 30% of this yeast-expressed material, at N5 of the kringle (corresponds to N11 of the particular construct, N184 of full-length tPA). The expressed recombinant kringle recognized a conformation-specific monoclonal antibody generated against tPA that is directed to the K2 domain of the protein, interacted properly with various omega-amino acid ligands, and showed signature conformational properties when studied by differential scanning calorimetry and high-resolution 1H-NMR. The results demonstrate that the P. pastoris system can be employed to obtain large amounts of secreted and properly folded kringle domains.