Human antibodies targeting the C-type lectin-like domain of the tumor endothelial cell marker clec14a regulate angiogenic properties in vitro.

It has been suggested that clec14a may be involved in tumor angiogenesis. However, a molecular mechanism has not been clearly identified. In this study, we show for the first time that C-type lectin-like domain (CTLD) of clec14a may be important for regulating cell migration and filopodia formation. Using phage display technology, recombinant human antibodies specific to the CTLDs of human and mouse clec14a (clec14a-CTLD (immunoglobulin G) IgG) were selected. Functional assays using the antibodies showed that clec14a-CTLD IgGs specifically blocked endothelial cell migration and tube formation without affecting cell viability or activation. Further, clec14a-CTLD IgGs inhibited clec14a-mediated cell-cell contact by blocking interaction between CTLDs. Finally, clec14a cross-linking by the clec14a-CTLD IgGs significantly downregulated clec14a expression on the surface of endothelial cells. These results strongly suggest that the clec14a-CTLD may be a key domain in angiogenesis, and that clec14a-CTLD IgGs specifically inhibit angiogenesis by modulating CTLD-mediated cell interactions and clec14a expression on the surface of endothelial cells.

Characterization of active-site residues of the NIa protease from tobacco vein mottling virus.

Nuclear inclusion a (NIa) protease of tobacco vein mottling virus is responsible for the processing of the viral polyprotein into functional proteins. In order to identify the active-site residues of the TVMV NIa protease, the putative active-site residues, His-46, Asp-81 and Cys-151, were mutated individually to generate H46R, H46A, D81E, D81N, C151S, and C151A, and their mutational effects on the proteolytic activities were examined. Proteolytic activity was completely abolished by the mutations of H46R, H46A, D81N, and C151A, suggesting that the three residues are crucial for catalysis. The mutation of D81E decreased kcat marginally by about 4.7-fold and increased Km by about 8-fold, suggesting that the aspartic acid at position 81 is important for substrate binding but can be substituted by glutamate without any significant decrease in catalysis. The replacement of Cys-151 by Ser to mimic the catalytic triad of chymotrypsin-like serine protease resulted in the drastic decrease in kcat by about 1,260-fold. This result might be due to the difference of the active-site geometry between the NIa protease and chymotrypsin. The protease exhibited a bell-shaped pH-dependent profile with a maximum activity approximately at pH 8.3 and with the abrupt changes at the respective pKa values of approximately 6.6 and 9.2, implying the involvement of a histidine residue in catalysis. Taken together, these results demonstrate that the three residues, His-46, Asp-81, and Cys-151, play a crucial role in catalysis of the TVMV NIa protease.

Molecular cloning, expression, and purification of nuclear inclusion A protease from tobacco vein mottling virus.

The gene encoding the C-terminal protease domain of the nuclear inclusion protein a (NIa) of tobacco vein mottling virus (TVMV) was cloned from an isolated virus particle and expressed as a fusion protein with glutathione S-transferase in Escherichia coli XL1-blue. The 27-kDa protease was purified from the fusion protein by glutathione affinity chromatography and Mono S chromatography. The purified protease exhibited the specific proteolytic activity towards the nonapeptide substrates, Ac-Glu-Asn-Asn-Val-Arg-Phe-Gln-Ser-Leu-amide and Ac-Arg-Glu-Thr-Val-Arg-Phe-Gln-Ser-Asp-amide, containing the junction sequences between P3 protein and cylindrical inclusion protein and between nuclear inclusion protein b and capsid protein, respectively. The Km and k(cat) values were about 0.2 mM and 0.071 s(-1), respectively, which were approximately five-fold lower than those obtained for the NIa protease of turnip mosaic potyvirus (TuMV), suggesting that the TVMV NIa protease is different in the binding affinity as well as in the catalytic power from the TuMV NIa protease. In contrast to the NIa proteases from TuMV and tobacco etch virus, the TVMV NIa protease was not autocatalytically cleaved into smaller proteins, indicating that the C-terminal truncation is not a common phenomenon occurring in all potyviral NIa proteases. These results suggest that the TVMV NIa protease has a unique biochemical property distinct from those of other potyviral proteases.

Proteolytic processing of oligopeptides containing the target sequences by the recombinant tobacco vein mottling virus NIa proteinase.

Tobacco vein mottling virus (TVMV) belongs to the potyviridae that consists of about 200 plant viruses. Potyviruses have RNA genomes of approximately 10,000 bases from which a single polyprotein is expressed from each virus upon infection. The NIa proteinase is known to process the polyprotein at seven distinct junctions between proteins. Kinetic constants were determined for the reactions of the recombinant TVMV NIa protease (27 kDa) with synthetic oligopeptides containing the sequences for the cleavage sites. For optimum activity, the substrate needs to have six amino acids (P6-P1) in the amino region and four (P1'-P4') in the carboxy region, including four conserved amino acids (V-R-F-Q) in P4-P1 positions. Mutation of any of four conserved amino acids to Gly made the substrate inert to the enzyme. Among the substrates, the oligopeptides containing the sequences for junctions, P3-6K1, NIa (VPg-Pro), and NIa-NIb were not processed by the NIa protease. Those junctions have Glu at P3, Glu at P1, and Thr at P2. The implications of high substrate specificity and size dependence in polyprotein processing and viral replication are discussed.

Fluorometric assay of turnip mosaic virus NIa protease.

Turnip mosaic virus (TuMV) NIa protease cleaves the viral polyprotein at seven distinct junctions out of nine. The amino acid sequences of the seven cleavage sites have three conserved amino acids, V, H, Q in positions P4, P2, P1, respectively. Small molecules as well as conjugated peptides were tested for proteolytic activity of the enzyme. None of small molecules tested, such as methylumbelliferyl-p-guanidinobenzoate, p-nitrophenyl-p'-guanidinobenzoate, p-nitrophenyl acetate, and methylumbelliferyl-N-acetylglutamate, were hydrolyzed. Ac-V-Y-H-Q-Mca was also not hydrolyzed. Intramolecularly quenched fluorogenic substrates Dns-P-V-Y-H-Q-A-W-NH(2) and Dns-P-V-Y-H-Q-W-NH(2) emitted fluorescence after addition of TuMV NIa protease. The proteolysis rate of Dns-P-V-Y-H-Q-A-W-NH(2) was comparable to that of the tetradecapeptide with an optimum sequence, but Dns-P-V-Y-H-Q-W-NH(2) was hydrolyzed at a slower rate, which was confirmed independently by HPLC analysis. These results suggest that intramolecularly quenched fluorogenic substrates can be used for the continuous assay of TuMV NIa protease.

Effects of mutations in the C-terminal region of NIa protease on cis-cleavage between NIa and NIb.

Mutational analyses were carried out to investigate whether the nuclear inclusion protein a (NIa) C-terminal amino acids of turnip mosaic potyvirus play any roles in the cis-cleavage between NIa and NIb. The processing rate of the NIa-NIb junction sequence was decreased significantly by either V240D or Q243A mutation while little affected by F226D, V228E, K230E, I232D, or L235D mutation. The mutation of W212S, G213S, or I217D abolishing the cleavage at the NIb-CP or 6K1-cylindrical inclusion protein junction sequence decreased the processing rate to half the level of that of the wild type. Deletion of the C-terminal one (K230), two (S229 and K230), three (S229 to L231), or six amino acids (S229 to D234) as well as the insertion of five glycines between S229 and K230 or between S220 and Q221 did not affect significantly the cleavage while the deletion of 20 amino acids (Q218 to S237) decreased the processing rate to 73% of that of the wild type. These results rule out the possibility that the C-terminal region plays a role as a spacer in right placement of the NIa-NIb junction sequence and demonstrate that the C-terminal 20 amino acids from Q218 to S237 are not crucial for the cis-cleavage of the NIa-NIb junction sequence.

Effects of internal cleavages and mutations in the C-terminal region of NIa protease of turnip mosaic potyvirus on the catalytic activity.

The nuclear inclusion protein a (NIa) of turnip mosaic potyvirus is a protease processing the viral polyprotein into functional proteins. It has been shown that the NIa C-terminal 27-kDa protease cleaves itself between Ser-223 and Gly-224 to generate a 25-kDa protein lacking the C-terminal 20 amino acids. We have found a second internal cleavage near the C-terminus resulting in the degradation of the 25-kDa protein into a 24-kDa protein. Substitution of the active site Asp-81 or Cys-151 with Asn or Ser, respectively, prevented the second cleavage, suggesting that the internal cleavage is also due to the proteolytic activity of the NIa protease. This second internal cleavage was found to occur between Thr-207 and Ser-208, eliminating the C-terminal 36 amino acids from the 27-kDa protease. The proteolytic activity of the 24-kDa protein was not detected at all when it was measured using a nonapeptide containing the cleavage site between 6K1 and Cl as a substrate, suggesting that the C-terminal region between residues 208 and 223 contains essential amino acids for the processing of 6K1-Cl polyprotein. The deletion analyses of the C-terminal region revealed that at least 217 amino acids from the N-terminus are required for the catalytic activity of the NIa protease. The point mutation of Trp-212 to Ser, Gly-213 to Ser, or Ile-217 to Asp drastically abolished the catalytic activity, demonstrating that Trp-212, Gly-213, and Ile-217 are important for the processing of 6K1-Cl polyprotein.