Kathleen O’Connell scite author profile

Sarcopenia is the drastic loss of skeletal muscle mass and strength during ageing. In order to better understand the molecular pathogenesis of age-related muscle wasting, we have performed a DIGE analysis of young adult versus old rat skeletal muscle. Proteomic profiling revealed that out of 2493 separated 2-D spots, 69 proteins exhibited a drastically changed expression. Age-dependent alterations in protein abundance indicated dramatic changes in metabolism, contractile activity, myofibrillar remodelling and stress response. In contrast to decreased levels of pyruvate kinase (PK), enolase and phosphofructokinase, the mitochondrial ATP synthase, succinate dehydrogenase, malate dehydrogenase, isocitrate dehydrogenase and adenylate kinase (AK) were increased in senescent fibres. Higher expression levels of myoglobin and fatty acid binding-protein indicated a shift to more aerobic-oxidative metabolism in a slower-twitching aged fibre population. The drastic increase in aB-crystallin and myotilin demonstrated substantial filament remodelling during ageing. An immunoblotting survey of selected muscle proteins confirmed the pathobiochemical transition process in aged muscle metabolism. The proteomic analysis of aged muscle has identified a large cohort of new biomarkers of sarcopenia including opposite changes in PK and AK, which might be useful for the design of improved diagnostic procedures and/or therapeutic strategies to counteract ageing-induced muscle degeneration.

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In vitro Effects of the BH3 Mimetic, (−)-Gossypol, on Head and Neck Squamous Cell Carcinoma Cells

Oliver

et al. 2004

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Purpose: Bcl-x L overexpression is common in head and neck squamous cell carcinomas (HNSCC) and correlates with resistance to chemotherapy. Thus, a nonpeptidic, cellpermeable small molecule that mimics the BH3 domain of proapoptotic proteins may inhibit Bcl-x L function and have therapeutic potential for HNSCC by overcoming drug-resistance. (؊)-Gossypol, the levorotatory isomer of a natural product isolated from cottonseeds and roots, was recently discovered to bind to the BH3 binding groove of Bcl-x L and Bcl-2.Experimental Design: We investigated the in vitro effects of (؊)-gossypol on HNSCC cell lines as well as on fibroblast and keratinocyte cultures by using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) cell survival assays and assessed the results with respect to Bcl-2 family protein expression.Results: We observed dose-dependent growth inhibition of 10 HNSCC cell lines at biologically achievable doses (2.5-10 mol/L). (؊)-Gossypol doses required to inhibit the growth of human fibroblast cell lines by 50% were 2-to 10-fold higher than for HNSCC cell lines. To inhibit human oral keratinocyte growth by 50%, (؊)-gossypol concentrations were 2-to 3-fold higher than for HNSCC cell lines.Conclusions: There is a direct correlation between Bclx L -to-Bcl-x S ratios and sensitivity to (؊)-gossypol. This agent induced apoptosis in a much higher proportion of cells with wild-type p53. Importantly, cell lines resistant to cisplatin were very sensitive to (؊)-gossypol. These results demonstrate that (؊)-gossypol has potent antitumor activity in HNSCC in vitro. This agent may be developed as a novel therapeutic agent for HNSCC, either alone or in combination with existing chemotherapeutic agents.

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Proteomics of skeletal muscle aging

et al. 2009

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Extended human longevity has resulted in increasing numbers of elderly persons in the general population. However, old age is also associated with a variety of serious physical disorders. Frailty among sedentary elderly patients is related to the impaired structure and function of contractile fibers. Biochemical research into cellular mechanisms that underlie sarcopenia promises to acquire the scientific basis of evidence to aid the development of new diagnostic and therapeutic strategies. The recent application of MS-based proteomic methodology has identified a large cohort of disease-specific markers of sarcopenia. This review critically examines the biomedical implications of the results obtained from the proteomic screening of both aged human muscle and established animal models of sarcopenia. Substantial alterations in proteins involved in key metabolic pathways, regulatory and contractile elements of the actomyosin apparatus, myofibrillar remodeling and the cellular stress response are discussed. A multi-factorial etiology appears to be the basis for a slower-twitching aged fiber population, which exhibits a shift to more aerobic-oxidative metabolism. It is hoped that the detailed biomedical characterization of the newly identified biomarkers of sarcopenia will translate into better treatment options for reversing age-dependent muscle degeneration, which could improve the standard of living for a large portion of society.

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Proteomic DIGE analysis of the mitochondria‐enriched fraction from aged rat skeletal muscle

O’Connell

Ohlendieck

2009

Proteomics

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Skeletal muscle aging is associated with a loss in tissue mass and contractile strength, as well as fiber type shifting and bioenergetic adaptation processes. Since mitochondria represent the primary site for energy generation via oxidative phosphorylation, we investigated potential changes in the expression pattern of the mitochondrial proteome using the highly sensitive DIGE approach. The comparative analysis of the mitochondria-enriched fraction from young adult versus aged muscle revealed an age-related change in abundance for 39 protein species. MS technology identified the majority of altered proteins as constituents of muscle mitochondria. An age-dependent increase was observed for NADH dehydrogenase, the mitochondrial inner membrane protein mitofilin, peroxiredoxin isoform PRX-III, ATPase synthase, succinate dehydrogenase, mitochondrial fission protein Fis1, succinate-coenzyme A ligase, acyl-coenzyme A dehydrogenase, porin isoform VDAC2, ubiquinol-cytochrome c reductase core I protein and prohibitin. Immunoblotting, enzyme testing and confocal microscopy were used to validate proteomic findings. The DIGE-identified increase in key mitochondrial elements during aging agrees with the concept that sarcopenia is associated with a shift to a slower contractile phenotype and more pronounced aerobic-oxidative metabolism. This suggests that mitochondrial markers are reliable candidates that should be included in the future establishment of a biomarker signature of skeletal muscle aging.

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Aging skeletal muscle shows a drastic increase in the small heat shock proteins αB-crystallin/HspB5 and cvHsp/HspB7

Doran

Gannon

O’Connell

et al. 2007

European Journal of Cell Biology

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Most heat shock proteins operate as molecular chaperones and play a central role in the maintenance of normal cellular function. In skeletal muscle, members of the a-crystallin domain-containing family of small heat shock proteins are believed to form a cohort of essential stress proteins. Since aB-crystallin (aBC/HspB5) and the cardiovascular heat shock protein (cvHsp/HspB7) are both implicated in the molecular response to fibre transformation and muscle wasting, it was of interest to investigate the fate of these stress proteins in young adult versus aged muscle. The agerelated loss of skeletal muscle mass and strength, now generally referred to as sarcopenia, is one of the most striking features of the senescent organism. In order to better understand the molecular pathogenesis of age-related muscle wasting, we have performed a two-dimensional gel electrophoretic analysis, immunoblotting and confocal microscopy study of aged rat gastrocnemius muscle. Fluorescent labelling of the electrophoretically separated soluble muscle proteome revealed an overall relatively comparable protein expression pattern of young adult versus aged fibres, but clearly an up-regulation of aBC and cvHsp. This was confirmed by immunofluorescence microscopy and immunoblot analysis, which showed a dramatic age-induced increase in these small heat shock proteins. Immunodecoration of other major stress proteins showed that they were not affected or less drastically changed in their expression in aged muscle. These findings indicate that the increase in muscle-specific small heat shock proteins constitutes an essential cellular response to fibre aging and might therefore be a novel therapeutic option to treat sarcopenia of old age.

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