The bacteriophage T7 DNA polymerase consists of a tight, 1:1 complex of T7 gp5, encoded by the phage, and thioredoxin, produced by the E. coli host. In the absence of thioredoxin, gp5 is capable of adding only a few nucleotides to the 3′ end of a primer before dissociating from the primer-template. But when complexed with thioredoxin, gp5 becomes highly processive, capable of polymerizing thousands of nucleotides complementary to the template strand. The mechanism by which thioredoxin acts as a processivity factor to gp5 is not fully understood. To understand the role of the thioredoxin in stabilizing polymerase-DNA interactions, we use a single-molecule imaging approach to observe individual, fluorescently labeled T7 DNA polymerase complexes diffusing along double-stranded DNA. Our results show that the average diffusion coefficient of T7 DNA polymerase complexes is insensitive to ionic strength and does not exceed the theoretical diffusion limit for a protein that tracks the helical pitch and rotates as it diffuses along the DNA helix. These results suggest that the T7 DNA polymerase slides along the DNA, remaining tightly bound to the DNA and tracking the helical pitch. However, the mean diffusion coefficients for fluorescently labeled T7 gp5 in the absence of thioredoxin increase with salt concentration, and exceed the theoretical limit for a protein tracking the DNA helix. Upon addition of unlabeled thioredoxin, the mean diffusion coefficient is restored to the value observed for the labeled T7 DNA polymerase, and becomes salt independent. These observations indicate that, in the absence of thioredoxin, T7 gp5 intermittently dissociates from the DNA as it diffuses, and that thioredoxin binding suppresses microscopic hopping on and off the DNA.