Abstract
Analysis of a series of human beta-myosin heavy chain (MHC) constructs with progressive deletions in the 5'-flanking region has localized a strong positive element at positions -298/277 with a repressor region located immediately upstream at -332/-300 (Flink, I. L., Edwards, J. G., Bahl, J. J., Liew, C.-C., Sole, M., and Morkin, E. (1992) J. Biol. Chem. 267, 9917-9924). A 49-base pair restriction fragment containing the suppressor element was used to screen a cardiac expression library. The 0.65-kilobase pair cDNA identified by this procedure was similar in sequence, except for the absence of a 21-base pair region encoding seven amino acids, to cellular nucleic acid-binding protein (CNBP), a 19-kDa zinc finger DNA-binding protein isolated earlier from liver, which may be involved in negative regulation of cholesterol biosynthesis (Rajavashisth, T. B., Taylor, A. K., Andalibi, A., Svenson, K. L., and Lusis, A. J. (1989) Science 245, 640-643). An additional clone identical to the one originally found in liver, referred to as CNBP alpha, was isolated from the cardiac library by hybridization screening. Gel mobility shift analysis indicated that CNBP alpha and CNBP beta isoforms preferentially interact with single-stranded DNA corresponding to the proximal and distal regions of the suppressor. When cotransfected with a beta-MHC reporter construct, CNBP alpha repressed activity in a dosage-dependent manner, whereas repression was not observed with the shorter construct (CNBP beta). Cotransfection of a combination of CNBP alpha and CNBP beta repressed reporter activity to an extent similar to cotransfection with CNBP alpha alone, suggesting that CNBP beta is not translationally active under these conditions. The results of RNase protection assays and genomic sequencing indicated that the alpha and beta isoforms are formed by alternative use of 5' donor sites within a single exon. These results suggest that CNBP isoforms may modulate the activity of the beta-MHC gene by interaction with a repressor region.
Highlights
National Institutes of Health, a grant from the Gustavus and Louise Pfeiffer Research Foundation, Grants G-2-03-90 and G-2-02-92 from the American Heart Association, Arizona Affiliate, and Grant 9411 from the Arizona Disease Control Research Commission
In earlier studies of the human {3-myosin heavy chain (MHC) promoter, a region was identified by DNase I footprinting between positions -278/ -296 that coincided with sequences between positions -274/ -300 that were required for high level expression in primary fetal rat heart cell cultures (Flink et al, 1992)
The clone initially characterized was similar in sequence to the message corresponding to cellular nucleic acid-binding protein (CNBP) (Rajavashisth et al, 1989), except for the absence of 21 nucleotides encoding seven amino acids near the 5' end of the cDNA
Summary
Vol 270, No 12, Issue of March 24, pp. 6959-6965, 1995 Printed in U.S.A. Alternatively Processed Isoforms of Cellular Nucleic Acid-binding Protein Interact with a Suppressor Region of the Human I3-Myosin Heavy Chain Gene*. The results of RNase protection assays and genomic sequencing indicated that the a and fl isoforms are formed by alternative use of 5' donor sites within a single exon These results suggest that CNBP isoforms may modulate the activity of the fl-MHC gene by interaction with a repressor region. In transient assays using primary heart cell cultures, CNBPa inhibited expression of a {3-MHC reporter plasmid containing the negative domain in a dosage-dependent manner, whereas the shorter isoform (CNBP{3) did not repress transcription. These results suggest that isoforms of CNBP in cardiac muscle may differentially regulate the transcriptional activity of the {3-MHC gene by competing for a suppressor element. The ex and f3 isoforms ofCNBP are present in liver and other non-muscle tissues where they may playa role in modulating the transcriptional activity of non-contractile protein genes
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