Identical distribution of fluorescently labeled brain and muscle actins in living cardiac fibroblasts and myocytes

We have investigated whether living muscle and nonmuscle cells can discriminate between microinjected muscle and nonmuscle actins. Muscle actin purified from rabbit back and leg muscles and labeled with fluorescein isothiocyanate, and nonmuscle actin purified from lamb brain and labeled with lissamine rhodamine B sulfonyl chloride, were co-injected into chick embryonic cardiac myocytes and fibroblasts. When fluorescence images of the two actins were compared using filter sets selective for either fluorescein isothiocyanate or lissamine rhodamine B sulfonyl chloride, essentially identical patterns of distribution were detected in both muscle and nonmuscle cells. In particular, we found no structure that, at this level of resolution, shows preferential binding of muscle or nonmuscle actin. In fibroblasts, both actins are associated primarily with stress fibers and ruffles. In myocytes, both actins are localized in sarcomeres. In addition, the distribution of structures containing microinjected actins is similar to that of structure containing endogenous F-actin, as revealed by staining with fluorescent phalloidin or phallacidin. Our results suggest that, at least under these experimental conditions, actin-binding sites in muscle and nonmuscle cells do not discriminate among different forms of actins.     

Correct NH2-terminal processing of cardiac muscle alpha-isoactin (class II) in a nonmuscle mouse cell

Both mammalian nonmuscle and muscle actins possess an AcAsp(Glu)NH2 terminus. The nonmuscle actin genes code for a polypeptide with a Met-Asp NH2 terminus (class I) whereas the muscle actin genes code for a polypeptide with a Met-Cys-Asp NH2 terminus (class II). Two amino acids must be removed for mature muscle actin synthesis, whereas only the Met must be removed for nonmuscle actin synthesis. We wished to know whether a nonmuscle cell which normally does not synthesize a class I actin can correctly process a muscle actin with its extra NH2-terminal amino acid in vivo. To answer this question we have used L/LK165 cells, a mouse L-cell transfected with a human cardiac muscle actin gene. When these cells were labeled overnight with [35S]Cys, an actin with an NH2-terminal tryptic peptide corresponding to that of mature cardiac muscle actin was detected. When the cells were pulse-labeled for 20 min, a new actin intermediate containing an AcCys-Asp amino terminus was observed which then disappeared with time. Furthermore, the muscle actin was processed as fast if not faster than the nonmuscle actin in these cells. This actin intermediate was also seen in chick myotube cultures. Our results show that the ability to correctly process muscle specific actins is not tissue specific. Furthermore, these results confirm a processing pathway for class II actins proposed by us earlier on the basis of experiments with a cell-free translation system.     

Expression of the genes coding for the skeletal muscle and cardiac actions in the heart

Several types of evidence indicate that the gene coding for the skeletal muscle actin is expressed in the rat heart: 1) A recombinant plasmid containing an insert with a nucleotide sequence identical to that of the homologous region of skeletal muscle actin gene was isolated from a cDNA library prepared on rat cardiac mRNA template. 2) Using specific probes it was found that the hearts of newborn rats contain a significant amount of skeletal muscle actin mRNA. The quantity of this mRNA in the heart decreases during development. 3) The skeletal muscle actin gene is DNAase I sensitive in nuclei from rat heart tissue. A plasmid containing a cDNA insert homologous to a part of the cardiac actin mRNA was isolated and sequenced. It was found that in spite of the great similarity between the amino acid sequence of the skeletal muscle and cardiac actins, the nucleotide sequences of the two mRNAs are considerably divergent. There is only limited sequence homology between the 3' untranslated regions of the two mRNAs. However, there is an extensive sequence homology between the 3' untranslated regions of the rat and human cardiac mRNAs, suggesting a functional role for this region of the gene or mRNA.     

Cellular localization of muscle and nonmuscle actin mRNAs in chicken primary myogenic cultures: the induction of alpha-skeletal actin mRNA is regulated independently of alpha-cardiac actin gene expression

Specific DNA fragments complementary to the 3' untranslated regions of the beta-, alpha-cardiac, and alpha-skeletal actin mRNAs were used as in situ hybridization probes to examine differential expression and distribution of these mRNAs in primary myogenic cultures. We demonstrated that prefusion bipolar-shaped cells derived from day 3 dissociated embryonic somites were equivalent to myoblasts derived from embryonic day 11-12 pectoral tissue with respect to the expression of the alpha-cardiac actin gene. Fibroblasts present in primary muscle cultures were not labeled by the alpha-cardiac actin gene probe. Since virtually all of the bipolar cells express alpha-cardiac actin mRNA before fusion, we suggest that the bipolar phenotype may distinguish a committed myogenic cell type. In contrast, alpha-skeletal actin mRNA accumulates only in multinucleated myotubes and appears to be regulated independently from the alpha-cardiac actin gene. Accumulation of alpha- skeletal but not alpha-cardiac actin mRNA can be blocked by growth in Ca2+-deficient medium which arrests myoblast fusion. Thus, the sequential appearance of alpha-cardiac and then alpha-skeletal actin mRNA may result from factors that arise during terminal differentiation. Finally, the beta-actin mRNA was located in both fibroblasts and myoblasts but diminished in content during myoblast fusion and was absent from differentiated myotubes. It appears that in primary myogenic cultures, an asynchronous stage-dependent induction of two different alpha-striated actin mRNA species occurs concomitant with the deinduction of the nonmuscle beta-actin gene.     

The complete amino acid sequence of actins from bovine aorta, bovine heart, bovine fast skeletal muscle, and rabbit slow skeletal muscle. A protein-chemical analysis of muscle actin differentiation.

Complete amino acid sequences for four mammalian muscle actins are reported: bovine skeletal muscle actin, bovine cardiac actin, the major component of bovine aorta actin, and rabbit slow skeletal muscle actin. The number of different actins in a higher mammal for which full amino acid sequences are now available is therefore increased from two to five. Screening of different smooth muscle tissues revealed in addition to the aorta type actin a second smooth muscle actin, which appears very similar if not identical to chicken gizzard actin. Since the sequence of chicken gizzard actin is known, six different actins are presently characterized in a higher mammal. The two smooth muscle actins--bovine aorta actin and chicken gizzard actin--differ by only three amino acid substitutions, all located in the amino-terminal end. In the rest of their sequences both smooth muscle actins share the same four amino acid substitutions, which distinguish them from skeletal muscle actin. Cardiac muscle actin differs from skeletal muscle actin by only four amino acid exchanges. No amino acid substitutions were found when actins from rabbit fast and slow skeletal muscle were compared. In addition we summarize the amino acid substitution patterns of the six different mammalian actins and discuss their tissue specificity. The results show a very close relationship between the four muscle actins in comparison to the nonmuscle actins. The amino substitution patterns indicate that skeletal muscle actin is the highest differentiated actin form, whereas smooth muscle actins show a noticeably cloer relation to nonmuscle actins. By these criteria cardiac muscle actin lies between skeletal muscle actin and smooth muscle actins.     

Skeletal muscle actin mRNA. Characterization of the 3' untranslated region.

Plasmids p749, p106, and p150 contain cDNA inserts complementary to rat skeletal muscle actin mRNA. Nucleotide sequence analysis indicates the following sequence relationships: p749 specifies codons 171 to 360; p150 specifies codons 357 to 374 together with 120 nucleotides of the 3'-non-translated region; p106 specifies the last actin amino acid codon, the termination codon and the entire 3' non-translated region. Plasmid p749 hybridized with RNA extracted from rat skeletal muscle, cardiac muscle, smooth (stomach) muscle, and from brain. It also hybridizes well with RNA extracted from skeletal muscle and brain of dog and chick. Plasmid p106 hybridized specifically with rat striated muscles (skeletal and cardiac muscle) mRNA but not with mRNA from rat stomach and from rat brain. It also hybridized to RNA extracted from skeletal muscle of rabbit and dog but not from chick. Thermal stability of the hybrids and sensitivity to S1 digestion also indicated substantial divergence between the 3' untranslated end of rat and dog skeletal muscle actins. The investigation shows that the coding regions of actin genes are highly conserved, whereas the 3' non-coding regions diverged considerably during evolution. Probes constructed from the 3' non-coding regions of actin mRNAs can be used to identify the various actin mRNA and actin genes.     

Immunolocalization of muscle and nonmuscle isoforms of actin in myogenic cells and adult skeletal muscle

In vertebrate skeletal muscle, the proliferating myoblasts synthesize nonmuscle isoforms of actin, and the cells begin to express muscle-specific actin isoforms during their myogenic differentiation. To study the distributions of the actin isoforms in myogenic cells and fully differentiated skeletal muscle, we prepared a peptide antibody specific for the skeletal alpha isoform of actin and used this antibody along with an antibody specifically reactive with nonmuscle gamma actin to stain cultured myotubes and adult skeletal myofibrils by double-indirect immunofluorescence. At this level of resolution, no differences in isoform localization were seen: Both muscle and nonmuscle actins were detected in the myotubes and in the striations of mature myofibrils. Myotubes were also double-stained using immunogold electron microscopy, and the isoform distributions were determined quantitatively by counting the two sizes of gold particles that corresponded to labeling with each antibody. A quantitative analysis of immunoreactivity revealed that, although both forms were present in all actin-containing structures, nonmuscle actin was relatively more prevalent along the edges (cortical microfilaments) of the myotubes, whereas the muscle isoform predominated in the interior regions (containing forming myofibrils). Thus, we have found evidence of a heterogeneous distribution of muscle and nonmuscle actin isoforms in differentiating myogenic cells, and we have demonstrated that a nonmuscle actin isoform is a component of the muscle contractile apparatus.