Cardiac myosin binding protein C regulates postnatal myocyte cytokinesis.

Homozygous cardiac myosin binding protein C-deficient (Mybpc(t/t)) mice develop dramatic cardiac dilation shortly after birth; heart size increases almost twofold. We have investigated the mechanism of cardiac enlargement in these hearts. Throughout embryogenesis myocytes undergo cell division while maintaining the capacity to pump blood by rapidly disassembling and reforming myofibrillar components of the sarcomere throughout cell cycle progression. Shortly after birth, myocyte cell division ceases. Cardiac MYBPC is a thick filament protein that regulates sarcomere organization and rigidity. We demonstrate that many Mybpc(t/t) myocytes undergo an additional round of cell division within 10 d postbirth compared with their wild-type counterparts, leading to increased numbers of mononuclear myocytes. Short-hairpin RNA knockdown of Mybpc3 mRNA in wild-type mice similarly extended the postnatal window of myocyte proliferation. However, adult Mybpc(t/t) myocytes are unable to fully regenerate the myocardium after injury. MYBPC has unexpected inhibitory functions during postnatal myocyte cytokinesis and cell cycle progression. We suggest that human patients with homozygous MYBPC3-null mutations develop dilated cardiomyopathy, coupled with myocyte hyperplasia (increased cell number), as observed in Mybpc(t/t) mice. Human patients, with heterozygous truncating MYBPC3 mutations, like mice with similar mutations, have hypertrophic cardiomyopathy. However, the mechanism leading to hypertrophic cardiomyopathy in heterozygous MYBPC3(+/-) individuals is myocyte hypertrophy (increased cell size), whereas the mechanism leading to cardiac dilation in homozygous Mybpc3(-/-) mice is primarily myocyte hyperplasia.

Efficacy and mechanisms of vacuum-assisted closure (VAC) therapy in promoting wound healing: a rodent model.

BACKGROUND: The vacuum-assisted closure device (VAC) has revolutionised wound care, although molecular mechanisms are not well understood. We hypothesise that the VAC device induces production of pro-angiogenic factors and promotes formation of granulation tissue and healing. METHODS: A novel rodent model of VAC wound healing was established. Excisional wounds were created on rat dorsa. Wounds were dressed with Tegaderm (control group), VAC Granulofoam and Tegaderm (special control group), or VAC Granulofoam, T.R.A.C. PAD((R)) with 125 mm Hg continuous negative pressure (VAC group). Wound closure rates were calculated as a percentage of initial wound sizes. Rats were sacrificed on postoperative days 3, 5 and 7; harvested tissues were processed for histology [haematoxylin & eosin (H&E), Masson's trichrome, picrosirius red] and Western blot analysis (CD31, vascular endothelial growth factor, basic fibroblast growth factor). RESULTS: Statistically significant wound closure rates were achieved in the experimental group at all measured time points: day 3, 28.1% (VAC) vs 8.2% (control) and 8.8% (special control) (ANOVA, P<0.0001); day 5, 45.3% (VAC) vs 23.7% (control) and 22.5% (special control) (ANOVA, P=0.0003); day 7, 54.4% (VAC) vs 43.0% (control) and 31.5% (special control) (ANOVA; P<0.0001). Morphological evaluation by Masson's trichrome stain showed increased collagen organisation and wound maturation in the VAC group. These wounds also showed increased expression of vascular endothelial growth factor and fibroblast growth factor-2 on day 5 by Western blot analysis. CONCLUSION: A small animal VAC wound model was established. Wounds treated with a VAC device showed accelerated wound closure rates, increased pro-angiogenic growth factor production and improved collagen deposition. Further application of this model may elucidate other mechanisms.