A complex rearrangement mutation in the mouse titin gene leads to an 83 amino acid deletion in the titin myofilament. Autosomal recessive inheritance of the mutation (Ttn^mdm/mdm) leads to a severe early-onset muscular dystrophy and premature death. We hypothesized that the N2A deletion would have a deleterious impact on the force-generating capacity and altered passive mechanical properties of the mdm diaphragm. Two and six week mdm and age-matched control mice were studied. We measured in vitro active isometric contractile and passive length-tension properties to assess muscle function. Micro-computed tomography, myosin heavy chain western, and histology were used to support findings. Our data revealed marked chest wall distortions progressing from 2 to 5 weeks of age. The percent of myofibers with centrally located nuclei in mdm diaphragms was 4% increased at 2 weeks and 17% increased at 6 weeks, compared with age-matched controls. At 6 weeks twitch stress was reduced by 71%, time-to-peak twitch was reduced by 52%, and 1/2 relaxation time was reduced by 57% in mdm diaphragms. Isometric tetanic stress was depressed in both 2 and 6 week-old mdm diaphragms by as much as 64%. Length-tension relationships of the mdm diaphragm from both age groups showed decreased extensibility and increased stiffness. Slow myosin heavy chain expression was aberrantly favored in the mdm diaphragm at 6 weeks of age. Our data strongly support early contractile and passive mechanical aberrations of the respiratory pump resulting from a subtle mutation in the titin N2A region.