Bone and eggshell quality throughout an extended laying cycle in three strains of layers spanning 50 years of selection.

Decades of intensive genetic selection in commercial layers has resulted in earlier maturation, while sustaining high production rates to 100 wks of age (woa). To support eggshell formation while maintaining a healthy skeletal frame, substantial adaptations of calcium metabolism in the hen are necessary. Thus, skeletal growth, bone density, and egg quality were compared in 3 strains of layers, with the Lohmann LSL-lite as the current commercial strain, the heritage Shaver white leghorn as the mid-2000s strain, and the white-leghorn derived Smoky Joes as the non-selected 1960s strain.

Changes in the Control of the Hypothalamic-Pituitary Gonadal Axis Across Three Differentially Selected Strains of Laying Hens ().

Genetic selection for earlier sexual maturation and extended production cycles in laying hens has significantly improved reproductive efficiency. While limited emphasis has been placed on the underlying physiological changes, we hypothesize that modifications in the control of the hypothalamic-pituitary gonadal (HPG) axis have occurred. Thus, three strains of White leghorn derivatives were followed from hatch to 100 weeks of age (woa), including Lohmann LSL-lite ( = 120) as current commercial hens, heritage Shaver White leghorns ( = 100) as 2000s commercial equivalents, and Smoky Joe hens ( = 68) as 1960s commercial equivalents.

Overexpression of osteoactivin protects skeletal muscle from severe degeneration caused by long-term denervation in mice.

We have previously shown that osteoactivin, a type I membrane glycoprotein expressed in myofibers, upregulated expression of matrix metalloprotease (MMP)-3 and MMP-9 in fibroblasts infiltrated denervated skeletal muscle in mice. To address whether osteoactivin-mediated increase in MMPs in skeletal muscle is useful for regeneration of denervated skeletal muscle, we subjected osteoactivin-transgenic mice to long-term denervation for 70 or 90 days. Long-term denervation caused severe degeneration of myofibers and fibrosis in skeletal muscle of wild-type mice.