Specific molecular interactions mediated by the N-terminus of fibrinogen's Bbeta chain were revealed using laser tweezers-based force spectroscopy. We examined interactions between fibrinogen fragments representing the center of the molecule, NDSK, desA-NDSK, and desAB-NDSK, and two recombinant fibrinogens, gammaD364H and gammaD364A, which have nonfunctional gamma-chain polymerization sites to prevent the dominant knob-hole binding. Interactions between desA-NDSK, where the N-terminus of the Bbeta chain is present, and the fibrinogen variants showed a complex spectrum of rupture forces which disappeared with desAB-NDSK, lacking both FpA and FpB. The interactions between desA-NDSK and gammaD364H or gammaD364A were inhibited by addition of soluble FpB, but not FpA or the polymerization inhibitor peptides GPRP and GHRP. When gammaD364H fibrinogen was replaced with its X-fragment lacking alphaC- domains or with fragment D, the strongest component of the rupture force spectrum disappeared, suggesting interactions between the uncleaved FpB and the alphaC-domain. Electron microscopy confirmed the binding of desA-NDSK to either D or E regions of fibrinogen as well as to alphaC-domains. The data demonstrate the existence of weak transient interactions within and between fibrin molecules mediated by the N-terminus of the fibrinogen Bbeta chain.