Initial recognition of DNA damage is the crucial but poorly understood first step in DNA repair by the human nucleotide excision repair(NER) and mismatch repair (MMR) systems. Failure by NER or MMR to recognize DNA damage threatens the genetic integrity of the organism and may play a role in carcinogenesis. Both NER and MMR recognize and repair a wide variety of structurally dissimilar lesions against the background of normal DNA. Previous studies have suggested that detection of thermodynamic destabilization of DNA caused by covalent damage and base mismatches is a potential mechanism by which repair pathways with broad specificity such as NER and MMR recognize their substrates. However, both NER and MMR respectively, repair a wide variety of stabilizing and destabilizing covalent DNA lesions and base pair mismatches. A common feature of lesions that are both thermodynamically stabilizing and destabilizing is the alteration of the local DNA flexibility (dynamics). In this review we describe the experimental evidence for altered dynamics from NMR and thermodynamic studies on normal and damaged DNA molecules with respect to recognition by NER and MMR. Based on these data, we propose a model for initial detection of lesions by both NER and MMR that occurs through an indirect readout mechanism of alternative DNA conformations induced by covalent damage and base mismatches.