The essential mitochondrial Hsp70 (mtHsp70) is required for the import of mitochondrial preproteins into the matrix compartment. The translocation-specific activity of mtHsp70 is coordinated by its interaction with specific partner proteins, forming the import motor complex that provides the energy for unfolding and complete translocation of precursor polypeptide chains. A major biochemical characteristic of Hsp70-type chaperones is their nucleotide-regulated affinity to polypeptide substrates. To study the role of this allosteric regulation in the course of preprotein translocation, we have generated specific mtHsp70 mutations located within or close to the interface between the nucleotide-binding and the substrate-binding domains. Mitochondria isolated from the mtHsp70 mutants displayed severely reduced import efficiencies in vitro. Two of the mutants exhibited strong growth defects in vivo and were significantly impaired in the generation of an inward-directed, ATP-dependent import force on precursor proteins in transit. The biochemical properties of these two mutant proteins were consistent with defects in the transfer of conformational signals to the substrate-binding domain, resulting in a prolonged and enhanced interaction with imported substrate proteins. Furthermore, interference with the allosteric mechanism resulted in defects of translocation-specific partner protein interaction. We conclude that even a partial disruption of the interdomain communication in the mtHsp70 chaperone results in an almost complete breakdown of its translocation-driving properties.