The conformation of coenzyme A bound to chloramphenicol acetyltransferase has been studied in solution by NMR methods. Transferred nuclear Overhauser enhancement (NOE) and rotating frame NOE (ROE) experiments were used to determine the conformation of the bound coenzyme. Experiments were carried out at five mixing times and two temperatures, and with normal and perdeuterated enzyme, to ensure (1) that the fast exchange condition was satisfied and (2) that the results were not complicated by spin diffusion involving enzyme protons. The data were analysed using a general approach involving combined exchange and relaxation matrices. For the binary complex of coenzyme A (CoA) and enzyme, the conformation of CoA was calculated by using distance constraints derived from the intensities of 71 NOE and 33 ROE cross-peaks between coenzyme protons. The conformation of the adenosine moiety of CoA in the structure deduced by NMR is very close to that seen in the crystal structure of this complex, while the pantetheine moiety is clearly less extended. Essentially the same conformation was obtained whether or not the calculations included the protein (with appropriate intermolecular energy terms). The difference between the NMR and X-ray structures is interpreted in terms of the existence of two conformations of the CoA-enzyme complex. Support for this model comes from measurements of the coenzyme dissociation rate constant; NMR (lineshape analysis and transferred NOE experiments) gives estimates of koff approximately 3700 s-1 at 298 K and approximately 500 s-1 at 280 K, both significantly greater than estimates by fluorescence stopped-flow measurements. For the ternary complex of CoA, chloramphenicol and enzyme, 71 NOE cross peaks between protons of coenzyme A and a further ten cross-peaks between protons of coenzyme A and chloramphenicol were measured. Starting with a model derived from the crystal structures of the two binary complexes (in the absence of crystallographic data for the ternary complex) the conformations and relative positions of the two ligands were refined using the distance constraints derived from these NOEs. The conformation of the adenosine part of CoA is the same as in the binary complex, while the pantetheine arm is more extended and approaches close to the bound chloramphenicol molecule. The model of the ternary complex is discussed in terms of the information available on the mechanism of the enzyme.