Your search keyword '"Muscle proteins -- Health aspects"' showing total 3 results

1. Extensive mononuclear infiltration and myogenesis characterize recovery of dysferlin-null skeletal muscle from contraction-induced injuries

Author

Roche, Joseph A., Lovering, Richard M., Roche, Renuka, Ru, Lisa W., Reed, Patrick W., and Bloch, Robert J.

Subjects

Dextran -- Health aspects, Dextran -- Research, Myosin -- Health aspects, Muscle proteins -- Health aspects, Myogenesis -- Analysis, Biological sciences

Abstract

We studied the response of dysferlin-null and control skeletal muscle to large- and small-strain injuries to the ankle dorsiflexors in mice. We measured contractile torque and counted fibers retaining 10-kDa fluorescein dextran, necrotic fibers, macrophages, and fibers with central nuclei and expressing developmental myosin heavy chain to assess contractile function, membrane resealing, necrosis, inflammation, and myogenesis. We also studied recovery after blunting myogenesis with X-irradiation. We report that dysferlin-null myofibers retain 10-kDa dextran for 3 days after large-strain injury but are lost thereafter, following necrosis and inflammation. Recovery of dysferlin-null muscle requires myogenesis, which delays the return of contractile function compared with controls, which recover from large-strain injury by repairing damaged myofibers without significant inflammation, necrosis, or myogenesis. Recovery of control and dysferlin-null muscles from small-strain injury involved inflammation and necrosis followed by myogenesis, all of which were more pronounced in the dysferlin-null muscles, which recovered more slowly. Both control and dysferlin-null muscles also retained 10-kDa dextran for 3 days after small-strain injury. We conclude that dysferlin-null myofibers can survive contraction-induced injury for at least 3 days but are subsequently eliminated by necrosis and inflammation. Myogenesis to replace lost fibers does not appear to be significantly compromised in dysferlin-null mice. inflammation; limb-girdle muscular dystrophy type 2B; Miyoshi myopathy; muscle injury doi: 10.1152/ajpcell.00122.2009

Published

2010

2. Nuclear localization of the titin Z1Z2Zr domain and role in regulating cell proliferation

Author

Qi, Jie, Chi, Liqun, Labeit, Siegfried, and Banes, Albert J.

Subjects

Muscle proteins -- Health aspects, Muscle proteins -- Properties, Cell proliferation -- Physiological aspects, Biological sciences

Abstract

Titin (also called connectin) is a major protein in sarcomere assembly as well as providing elastic return of the sarcomere postcontraction in cardiac and striated skeletal muscle tissues. In addition, it has been speculated that titin is associated with nuclear functions, including chromosome and spindle formation, and regulation of muscle gene expression. In the present study, a short isoform of titin was detected in a human osteoblastic cell line, MG-63 cells, by both immunostaining and Western blot analysis. Confocal images of titin staining showed both cytoplasmic and nuclear localization in a punctate pattern. Therefore, we hypothesized that human titin may contain a nuclear localization signal (NLS). A functional NLS, 200-PAKKTKT-206, located in a low-complexity, titin-specific region between Z2 and Z repeats, was found by sequentially deleting segments of the N[H.sub.2]-terminal sequence in conjunction with an enhanced green fluorescent protein reporter system and confirmed by site-directed mutagenesis. Overexpression of titin's amino terminal fragment (Z1Z2Zr) in human osteoblasts (MG-63) increased cell proliferation by activating the Wnt/[beta]-catenin pathway. RT-PCR screens of tissue panels demonstrated that residues 1-206 were ubiquitously expressed at low levels in all tissues and cell types analyzed. Our data implicate a dual role for titin's amino terminal region, i.e., a novel nuclear function promoting cell division in addition to its known structural role in Z-line assembly. Wnt; catenin; osteoblast

Published

2008

3. Acute responses of muscle protein metabolism to reduced blood flow reflect metabolic priorities for homeostasis

Author

Zhang, Xiao-jun, Irtun, Oivind, Chinkes, David L., and Wolfe, Robert R.

Subjects

Homeostasis -- Research, Muscle proteins -- Health aspects, Blood flow -- Health aspects, Biological sciences

Abstract

The present experiment was designed to measure the synthetic and breakdown rates of muscle protein in the hindlimb of rabbits with or without clamping the femoral artery. L-[[ring-.sup.13][C.sub.6]]phenylalanine was infused as a tracer for measurement of muscle protein kinetics by means of an arteriovenous model, tracer incorporation, and tracee release methods. The ultrasonic flowmeter, dye dilution, and microsphere methods were used to determine the flow rates in the femoral artery, in the leg, and in muscle capillary, respectively. The femoral artery flow accounted for 65% of leg flow. A 50% reduction in the femoral artery flow reduced leg flow by 28% and nutritive flow by 26%, which did not change protein synthetic or breakdown rate in leg muscle. Full clamp of the femoral artery reduced leg flow by 42% and nutritive flow by 59%, which decreased (P < 0.05) both the fractional synthetic rate from 0.19 [+ or -] 0.05 to 0.14 [+ or -] 0.03%/day and fractional breakdown rate from 0.28 [+ or -] 0.07 to 0.23 [+ or -] 0.09%/day of muscle protein. Neither the partial nor full clamp reduced (P = 0.27-0.39) the intracellular phenylalanine concentration or net protein balance in leg muscle. We conclude that the flow threshold to cause a fall of protein turnover rate in leg muscle was a reduction of 30-40% of the leg flow. The acute responses of muscle protein kinetics to the reductions in blood flow reflected the metabolic priorities to maintain muscle homeostasis. These findings cannot be extrapolated to more chronic conditions without experimental validation. stable isotope; gas chromatograph-mass spectrometer; arteriovenous balance; fractional synthetic rate; fractional breakdown rate

Published

2008