Cell type-specific differences in glycosaminoglycans modulate the biological activity of a heparin-binding peptide (RKRLQVQLSIRT) from the G domain of the laminin alpha1 chain.

AG73 (RKRLQVQLSIRT), a peptide from the G domain of the laminin alpha1 chain, has diverse biological activities with different cell types. The heparan sulfate side chains of syndecan-1 on human salivary gland cells were previously identified as the cell surface ligand for AG73. We used homologous peptides from the other laminin alpha-chains (A2G73-A5G73) to determine whether the bioactivity of the AG73 sequence is conserved. Human salivary gland cells and a mouse melanoma cell line (B16F10) both bind to the peptides, but cell attachment was inhibited by glycosaminoglycans, modified heparin, and sized heparin fragments in a cell type-specific manner. In other assays, AG73, but not the homologous peptides, inhibited branching morphogenesis of salivary glands and B16F10 network formation on Matrigel. We identified residues critical for AG73 bioactivity using peptides with amino acid substitutions and truncations. Fewer residues were critical for inhibiting branching morphogenesis (XKXLXVXXXIRT) than those required to inhibit B16F10 network formation on Matrigel (N-terminal XXRLQVQLSIRT). In addition, surface plasmon resonance analysis identified the C-terminal IRT of the sequence to be important for heparin binding. Structure-based sequence alignment predicts AG73 in a beta-sheet with the N-terminal K (Lys(2)) and the C-terminal R (Arg(10)) on the surface of the G domain. In conclusion, we have determined that differences in cell surface glycosaminoglycans and differences in the amino acids in AG73 recognized by cells modulate the biological activity of the peptide and provide a mechanism to explain its cell-specific activities.

Characterization of Trichomonas vaginalis AP33 adhesin and cell surface interactive domains.

Adherence to host target cells is a critical step in establishing infection with the sexually transmitted pathogen Trichomonas vaginalis. Four parasite surface proteins mediating attachment to vaginal epithelial cells have been identified. One surface protein, termed AP33, was characterized further to identify domains interactive with previously generated antibodies and with host surface sites. N- and C-terminal deletion subclones were generated and tested for reactivity with both mAb and rabbit antiserum against AP33, and were also examined for their ability to bind to host cells. Surprisingly, the rabbit antiserum known to inhibit cytoadherence recognized an epitope(s) contained within 72 residues in the N-terminal half of the protein. However, the mAb epitope was immunoreactive with a 28-amino-acid region near the C-terminus. Subsequent mapping of this region with overlapping peptides identified a nine-amino-acid sequence reactive with the mAb. Equally surprising, two domains interactive with host cell surfaces were identified at distinct parts of AP33: one in the N-terminal half of the protein, and the other within 24 residues in the C-terminal third. Further analysis of the C-terminal binding domain revealed that a peptide representing this area could inhibit T. vaginalis cytoadherence by 40%.

Three genes encode distinct AP33 proteins involved in Trichomonas vaginalis cytoadherence.

Adherence to host cells is essential for the initiation and maintenance of infection by mucosal pathogens. The protozoan Trichomonas vaginalis colonizes the human urogenital tract via four surface proteins (AP65, AP51, AP33 and AP23). To characterize AP33 further, six cDNA clones were examined. Restriction mapping indicated that the six clones represented three similar genes. Southern analysis confirmed the existence of three single-copy AP33 genes and suggested a semi-conservative genomic arrangement between T. vaginalis isolates. Analysis of full-length sequences determined that each contained a 930bp open reading frame encoding a protein of approximately 33,000 Da. Sequence comparisons revealed a high degree of identity at both the DNA and the protein levels. N-terminal protein sequencing established the presence of leader peptides. Each of the three full-length recombinant proteins had a predicted pI of approximately 10, which was verified experimentally for the T. vaginalis AP33 adhesin. A database search revealed that AP33 had significant identity to the succinyl-CoA synthetase alpha-subunit of several different organisms and virtually 100% identity to the reported T. vaginalis subunit. Unlike commercially purchased enzyme, the recombinant proteins retained adhesive properties equal to the natural T. vaginalis AP33. The characteristics of the AP33 protein are similar to those of the other adhesins and emphasize a complex host-parasite relationship.

Cloning and molecular characterization of two genes encoding adhesion proteins involved in Trichomonas vaginalis cytoadherence.

Cytoadherence to the vaginal epithelium is a critical step in infection by the eukaryotic flagellate Trichomonas vaginalis. Four trichomonad surface proteins (AP65, AP51, AP33 and AP23) mediate cytoadherence. The cDNA encoding the AP65 adhesin was isolated from a phagemid cDNA expression library by screening with antiserum and monoclonal antibody (mAb) raised against the purified trichomonad AP65 protein. Two clones, F11.2 and F11.5, coded for immuno-crossreactive recombinant proteins that possessed functional properties equal to the T. vaginalis AP65 adhesin. Analysis of full-length sequences corresponding to the F11.2 and F11.5 cDNAs revealed that both contained 1701-base open reading frames (ORFs) that encoded proteins of 63 281 daltons and 83 087 daltons, respectively. Comparison of the full-length sequences showed 87% identity at the nucleotide level and 91% identity at the protein level. Restriction-enzyme mapping and Southern analysis reaffirmed the distinctness of the F11.2 and F11.5 cDNAs, indicating that two different AP65 genes (now called ap65-1 and ap65-2) are present in the T. vaginalis genome in at least two copies each. Northern analysis detected high levels of transcript of approximately 1.8 kb for both ap65-1 and ap65-2 genes in trichomonads grown only in high-iron medium, confirming the transcriptional regulation of adhesin synthesis by iron. Homology searches revealed significant similarity (38% amino acid identity and 54% nucleotide identity) to malic enzymes. However, purified malic enzyme and mAb to AP65 crossreactive with malic enzyme neither inhibited cytoadherence of T. vaginalis to host cells nor prevented binding of the trichomonad AP65 to HeLa cells in a ligand assay.