Abstract
Cytoplasmic actins are abundant, ubiquitous proteins in nucleated cells. However, actin expression is regulated in a tissue- and development-specific manner. We identified a novel cytoplasmic-γ-actin (Actg1) transcript that includes a previously unidentified exon (3a). Inclusion of this exon introduces an in-frame termination codon. We hypothesized this alternatively-spliced transcript down-regulates γ-actin production by targeting these transcripts for nonsense-mediated decay (NMD). To address this, we investigated conservation between mammals, tissue-specificity in mice, and developmental regulation using C2C12 cell culture. Exon 3a is 80% similar among mammals and varies in length from 41 nucleotides in humans to 45 in mice. Though the predicted amino acid sequences are not similar between all species, inclusion of exon 3a consistently results in the in the introduction of a premature termination codon within the alternative Actg1 transcript. Of twelve tissues examined, exon 3a is predominantly expressed in skeletal muscle, cardiac muscle, and diaphragm. Splicing to include exon 3a is concomitant with previously described down-regulation of Actg1 in differentiating C2C12 cells. Treatment of differentiated C2C12 cells with an inhibitor of NMD results in a 7-fold increase in exon 3a-containing transcripts. Therefore, splicing to generate exon 3a-containing transcripts may be one component of Actg1 regulation. We propose that this post-transcriptional regulation occurs via NMD, in a process previously described as “regulated unproductive splicing and translation” (RUST).
Highlights
All mammals express six isoforms of actin: a-cardiac (Actc1, NM_009608), a-skeletal (Acta1, NM_009606), a-aortic (Acta2, NM_007392), c-enteric (Actg2, NM_009610), b-cytoplasmic (Actb, NM_007393), and c-cytoplasmic (Actg1, NM_009609)
Cytoplasmic actins are considered to be ubiquitously expressed in most tissues of the body with the exception of developing skeletal muscle, where muscle specific actins are up-regulated and c-actin is repressed
We identify an alternatively spliced transcript in muscle that allowed us to elucidate how the c-actin is downregulated during the important transition from myoblast to differentiated muscle cells
Summary
All mammals express six isoforms of actin: a-cardiac (Actc, NM_009608), a-skeletal (Acta, NM_009606), a-aortic (Acta, NM_007392), c-enteric (Actg, NM_009610), b-cytoplasmic (Actb, NM_007393), and c-cytoplasmic (Actg, NM_009609). Each actin is encoded on a separate chromosome but the coding sequence of the actins are 71% identical and there is 92% amino acid sequence identity between actin proteins. This degree of conservation is indicative of intolerance of these proteins to changes in amino acid composition, presumably because of the large number of proteins that interact directly with actin. The coding sequences are similar between actin isoforms, the genomic architecture of actin isoforms differs between the cytoplasmic (six exons), smooth muscle (nine exons), and cardiac and skeletal isoforms (seven exons). Mature skeletal and cardiac muscle derive from myoblasts, which express high levels of b- and c-actin in their undifferentiated form. Actg1-null mice demonstrate that c-actin is crucial for the normal function of mature skeletal muscle, as its complete absence results in a progressive myopathy in adult mice [5,6]
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