Sheila Timmons

Binding of fibrinogen to human platelets depends on the interaction of the gamma-chain carboxy-terminal segment with specific receptors exposed by different agonists such as ADP, epinephrine, and thrombin. The functions of a series of synthetic peptides encompassing the sequence of the 15 carboxy-terminal residues of the gamma chain were investigated in this study. Both pentadecapeptide (gamma 397-411) and dodecapeptide (gamma 400-411) inhibited binding of 125I-fibrinogen to ADP-treated platelets, with the concentration causing 50% inhibition (IC50) being 28 microM. In comparison, decapeptide (gamma 402-411) was almost 4 times less active (IC50 = 106 microM), thus suggesting that the two histidine residues (gamma 400-401) are required for a full inhibitory effect. A heptapeptide (gamma 405-411) had a similar effect (IC50 = 102 microM) whereas a pentapeptide (gamma 407-411) was even less inhibitory (IC50 = 190 microM), indicating that the lack of lysine (gamma 406) further diminishes the reactivity of the platelet recognition site on the gamma chain of human fibrinogen. The heptapeptide (gamma 400-406) containing two histidine residues and derived from the dodecapeptide by proteolytic degradation with trypsin had very low inhibitory activity. The synthetic peptides inhibited fibrinogen-supported platelet aggregation in the same order of decreasing reactivity: pentadecapeptide = dodecapeptide greater than decapeptide = heptapeptide greater than pentapeptide. Modified synthetic pentadecapeptides bearing tyrosine or cysteinyltyrosine at the amino terminal were prepared to provide a means for radiolabeling and for formation of molecules of higher valency.(ABSTRACT TRUNCATED AT 250 WORDS)

We have isolated overlapping cDNAs encoding the N-terminal non-triple-helical region of mouse alpha 1(XVIII) collagen and shown that three different variants of alpha 1(XVIII) collagen exist. Each of the three variants shows characteristic tissue-specific expression patterns. Immunohistochemical studies show positive staining for alpha 1(XVIII) collagen along the basement membrane zones of vessels in the intestinal villi, the choroid plexus, skin, liver, and kidney. Thus, we conclude that alpha 1(XVIII) collagen may interact (directly or indirectly) with components in basement membrane zones or on the basal surface of endothelial/epithelial cells.

We have isolated overlapping mouse cDNAs encoding a collagenous polypeptide that we have designated alpha 1(XVIII) collagen. Nucleotide sequence analysis shows that alpha 1(XVIII) collagen contains 10 triple-helical domains separated and flanked by non-triple-helical regions. Within the non-triple-helical regions, there are several Ser-Gly-containing sequences that conform to consensus sequences for glycosaminoglycan attachment sites in proteoglycan core proteins. Northern blots show that alpha 1(XVIII) transcripts are present in multiple organs, with the highest levels in liver, lung, and kidney. We have also isolated overlapping cDNAs encoding human alpha 1(XV) collagen, and their sequence extends a published partial alpha 1(XV) sequence to the 3' end. Comparison of the alpha 1(XV) and alpha 1(XVIII) sequences reveals a striking similarity in the lengths of the six most carboxyl-terminal triple-helical domains. In addition, within the carboxyl non-triple-helical domain NC1 of the two chains, a region of 177 amino acid residues shows about 60% identity at the amino acid level. We suggest, therefore, that alpha 1(XV) and alpha 1(XVIII) collagens are structurally related. Their structure is different from that of other known collagen types. We conclude that they belong to a subfamily of extracellular matrix proteins and we suggest the designation multiplexins (for protein with multiple triple-helix domains and interruptions) for members of this subfamily.

Fibrinogen, a clottable plasma protein, agglutinates both prokaryotic cells (e.g., staphylococci) and eukaryotic cell fragments (e.g., platelets) through interaction with specific receptors. To identify the region of the fibrinogen molecule responsible for its interaction with human platelets, we prepared polypeptide chain subunits (alpha, beta, and gamma) of human fibrinogen by reduction and carboxymethylation. A mixture of the chains induced aggregation (clumping) of human platelets separated from plasma proteins and treated with ADP. When individual chains of fibrinogen were tested, gamma-chain multimers caused platelet aggregation at a molar concentration comparable with that of intact human fibrinogen. The beta chain remained inactive, and the alpha chain was 1/4th to 1/5th as reactive as the gamma chain. Monospecific antibody fragments against the gamma chain inhibited binding of 125I-labeled fibrinogen to the human platelet receptor and blocked aggregation of platelets induced by ADP in the presence of fibrinogen or gamma-chain multimers. These results indicate that the gamma chain of human fibrinogen bears the main site for interaction with the platelet receptor.