The complex formation between the single-strand DNA binding protein (ssB protein) from Escherichia coli and oligonucleotides and single-stranded DNA has been studied by using fluorescence titrations, ultracentrifugation measurements, and fast kinetic techniques. Determination of the stoichiometries of oligo(dT)--ssB complexes shows that each of the four subunits of the ssB protein represents a binding site for an oligonucleotide about eight residues long. Occupation of all four binding sites with oligo(dT) or poly(dT) leads to 80% quenching of the intrinsic protein fluorescence. The binding sites are nearly equivalent and independent. For d(pT)16, the intrinsic binding constant is 6 X 10(5) M-1, and for d(pT)30-40, which is long enough to extend continuously over the ssB tetramer, the binding constant is higher than 5 X 10(8) M-1. Oligoadenylates bind about 2 orders of magnitude weaker than the corresponding oligo(dT) species. The binding of oligo(dT) is very weakly dependent on ionic strength, in contrast to the oligo(dA)--ssB complex formation. For d(pT)8, d(pT)16, and d(pT)30-40, the complex formation can be described by a simple one-step reaction. The strength of the interaction is mainly expressed in the rate constant of dissociation. In the cooperative complexes with poly(dT) or poly(dA), all four binding sites on the ssB tetramer are also occupied. It is concluded that single-stranded DNA is coiled around the ssB molecule. Fluorescence melting experiments of the complexes show that the conformation of the single-stranded DNA has a strong influence on the stability of the complexes.