Valerie Lupa-Kimball scite author profile

Valerie Lupa-Kimball

2Publications

62Citation Statements Received

77Citation Statements Given

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Affiliations

University of Illinois at Chicago

Publications

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The CACC Box and Myocyte Enhancer Factor-2 Sites within the Myosin Light Chain 2 Slow Promoter Cooperate in Regulating Nerve-specific Transcription in Skeletal Muscle

Esser

Nelson

Lupa-Kimball

et al. 1999

Journal of Biological Chemistry

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Previous experiments showed that activity of the ؊800-base pair MLC2slow promoter was 75-fold higher in the innervated soleus (SOL) compared with the noninnervated SOL muscles. Using in vivo DNA injection of MLC2slow promoter-luciferase constructs, the aim of this project was to identify regulatory sites and potential transcription factors important for slow nerve-dependent gene expression. Three sites within the proximal promoter (myocyte enhancer factor-2 (MEF2), E-box, and CACC box) were individually mutated, and the effect on luciferase expression was determined. There was no change in luciferase expression in the SOL and extensor digitorum longus (EDL) muscles when the E-box was mutated. In contrast, the MEF2 mutation resulted in a 30-fold decrease in expression in the innervated SOL muscles (10.3 versus 0.36 normalized relative light units (RLUs)). Transactivation of the MLC2slow promoter by overexpressing MEF2 was only seen in the innervated SOL (676,340 versus 2,225,957 RLUs; p < 0.01) with no effect in noninnervated SOL or EDL muscles. These findings suggest that the active MLC2slow promoter is sensitive to MEF2 levels, but MEF2 levels alone do not determine nerve-dependent expression. Mutation of the CACC box resulted in a significant up-regulation in the EDL muscles (0.23 versus 4.08 normalized RLUs). With the CACC box mutated, overexpression of MEF2 was sufficient to transactivate the MLC2slow promoter in noninnervated SOL muscles (27,536 versus 1,605,797 RLUs). Results from electrophoretic mobility shift and supershift assays confirm MEF2 protein binding to the MEF2 site and demonstrate specific binding to the CACC sequence. These results suggest a model for nerve-dependent regulation of the MLC2slow promoter in which derepression occurs through the CACC box followed by quantitative expression through enhanced MEF2 activation.

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Use of DNA injection for identification of slow nerve-dependent regions of the MLC2sgene

Lupa-Kimball

Esser

1998

American Journal of Physiology-Cell Physiology

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It has been well established that expression of slow contractile protein genes in skeletal muscle is regulated, in part, by activity from slow motoneurons. However, very little is understood about the mechanism by which neural activity regulates transcription of slow isoform genes. The purpose of this investigation was first to more fully define the in vivo DNA injection technique for use in both fast-twitch and slow-twitch muscles and second to use the injection technique for the identification of slow nerve-dependent regions of the myosin light chain 2 slow ( MLC2s) gene. Initial experiments determined that the same amount of plasmid DNA was taken up by both the slow-twitch soleus and fast-twitch extensor digitorum longus (EDL) muscles and that injection of from 0.5 to 10 μg DNA/muscle is ideal for analysis of promoter activity during regeneration. This technique was subsequently used to identify that the region from −800 to +12 base pairs of MLC2s gene directed ∼100 times higher activity in the innervated soleus than in innervated EDL, denervated soleus, or denervated EDL muscles. Placing the introns upstream of either the MLC2s or SV40 promoter increased expression 5- and 2.7-fold, respectively, in innervated soleus but not in innervated EDL, denervated soleus, or denervated EDL muscles. These results demonstrate that 1) in vivo DNA injection is a sensitive assay for promoter analysis in both fast-twitch and slow-twitch skeletal muscles and 2) both 5′ flanking and intronic regions of the MLC2s gene can independently and synergistically direct slow nerve-dependent transcription in vivo.

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