Your search keyword '"Lee, Jen Y."' showing total 3 results

1. Using laser capture microdissection to study fiber specific signaling in locomotor muscle in COPD: A pilot study.

Author

Mohan, Divya, Lewis, Amy, Patel, Mehul S., Curtis, Katrina J., Lee, Jen Y., Hopkinson, Nicholas S., Wilkinson, Ian B., Kemp, Paul R., and Polkey, Michael I.

Subjects

MUSCLE protein metabolism, ENZYME metabolism, COLLECTION & preservation of biological specimens, CELLULAR signal transduction, ENZYMES, GENES, OBSTRUCTIVE lung diseases, MUSCLE proteins, NONPARAMETRIC statistics, RESEARCH funding, TRANSFERASES, PILOT projects, CASE-control method, SKELETAL muscle, SIGNAL peptides

Abstract

Introduction: Quadriceps dysfunction is important in chronic obstructive pulmonary disease (COPD), with an associated increased proportion of type II fibers. Investigation of protein synthesis and degradation has yielded conflicting results, possibly due to study of whole biopsy samples, whereas signaling may be fiber-specific. Our objective was to develop a method for fiber-specific gene expression analysis.Methods: 12 COPD and 6 healthy subjects underwent quadriceps biopsy. Cryosections were immunostained for type II fibers, which were separated using laser capture microdissection (LCM). Whole muscle and different fiber populations were subject to quantitative polymerase chain reaction.Results: Levels of muscle-RING-finger-protein-1 and Atrogin-1 were lower in type II fibers of COPD versus healthy subjects (P = 0.02 and P = 0.03, respectively), but differences were not apparent in whole muscle or type I fibers.Conclusions: We describe a novel method for studying fiber-specific gene expression in optimum cutting temperature compound-embedded muscle specimens. LCM offers a more sensitive way to identify molecular changes in COPD muscle. Muscle Nerve 55: 902-912, 2017. [ABSTRACT FROM AUTHOR]

Published

2017

2. Increased expression of H19/miR-675 is associated with a low fat-free mass index in patients with COPD.

Author

Lewis, Amy, Lee, Jen Y., Donaldson, Anna V., Natanek, S. Amanda, Vaidyanathan, Srividya, Man, William D.‐C., Hopkinson, Nicholas S., Sayer, Avan A., Patel, Harnish P., Cooper, Cyrus, Syddall, Holly, Polkey, Michael I., and Kemp, Paul R.

Subjects

ADIPOSE tissues, MEDICAL care, LUNG diseases, MUSCLE mass, SARCOPENIA

Abstract

Background Loss of muscle mass and strength is a significant comorbidity in patients with chronic obstructive pulmonary disease (COPD) that limits their quality of life and has prognostic implications but does not affect everyone equally. To identify mechanisms that may contribute to the susceptibility to a low muscle mass, we investigated microRNA (miRNA) expression, methylation status, and regeneration in quadriceps muscle from COPD patients and the effect of miRNAs on myoblast proliferation in vitro. The relationships of miRNA expression with muscle mass and strength was also determined in a group of healthy older men. Methods We identified miRNAs associated with a low fat-free mass (FFM) phenotype in a small group of patients with COPD using a PCR screen of 750 miRNAs. The expression of two differentially expressed miRNAs (miR-675 and miR-519a) was determined in an expanded group of COPD patients and their associations with FFM and strength identified. The association of these miRNAs with FFM and strength was also explored in a group of healthy community-dwelling older men. As the expression of the miRNAs associated with FFM could be regulated by methylation, the relative methylation of the H19 ICR was determined. Furthermore, the proportion of myofibres with centralized nuclei, as a marker of muscle regeneration, in the muscle of COPD patients was identified by immunofluorescence. Results Imprinted miRNAs (miR-675 and from a cluster, C19MC which includes miR-519a) were differentially expressed in the quadriceps of patients with a low fat-free mass index (FFMI) compared to those with a normal FFMI. In larger cohorts, miR-675 and its host gene (H19) were higher in patients with a low FFMI and strength. The association of miR-519a expression with FFMI was present in male patients with severe COPD. Similar associations of miR expression with lean mass and strength were not observed in healthy community dwelling older men participating in the Hertfordshire Sarcopenia Study. Relative methylation of the H19 ICR was reduced in COPD patients with muscle weakness but was not associated with FFM. In vitro, miR-675 inhibited myoblast proliferation and patients with a low FFMI had fewer centralized nuclei suggesting miR-675 represses regeneration. Conclusions The data suggest that increased expression of miR-675/H19 and altered methylation of the H19 imprinting control region are associated with a low FFMI in patients with COPD but not in healthy community dwelling older men suggesting that epigenetic control of this loci may contribute to a susceptibility to a low FFMI. [ABSTRACT FROM AUTHOR]

Published

2016

3. Myostatin induces autophagy in skeletal muscle in vitro

Author

Lee, Jen Y., Hopkinson, Nicholas S., and Kemp, Paul R.

Subjects

*SKELETAL muscle, *GENE expression, *PHAGOSOMES, *CHRONIC diseases, *TRANSFORMING growth factors, *MESSENGER RNA

Abstract

Abstract: Myostatin is an important regulator of muscle mass that contributes to the loss of muscle mass in a number of chronic diseases. Myostatin is known to activate the expression of components of the ubiquitin-proteosomal pathway but its effect on the autophagic pathway is not known. We therefore analysed the effect of myostatin and TGF-β on autophagy in C2C12 cells by determining the effect of these proteins on LC3 processing, autophagosome formation and autophagy gene expression. Both myostatin and TGF-β increased LC3II expression and turnover as well as autophagosome formation (marked by the formation of puncta in LC3-GFP transfected cells). Myostatin also significantly increased the expression of ATG-4B and ULK-2 mRNA while TGF-β caused a trend towards an increase in these genes. We conclude that myostatin and TGF-β increase autophagy in skeletal muscle cells. [Copyright &y& Elsevier]

Published

2011