Coordinate regulation of contractile protein synthesis during myoblast differentiation

The synthesis of contractile proteins has been studied during the differentiation of quail skeletal muscle myoblasts in culture. Myoblast differentiation was synchronized by transferring secondary cultures of rapidly dividing myoblasts into medium lacking cell division-promoting factors. Cultures at various stages of differentiation were then pulse-labeled with 35S-methionine, and cell extracts were resolved by electrophoresis on two-dimensional gels. Incorporation into specific proteins was quantitated by autoradiography and fluorography using a scanning densitometer. Contractile proteins synthesized by muscle cultures were identified by their co-electrophoresis on two-dimensional gels with contracile proteins purified from quail breast muscle. Our results show that the synthesis of myosin heavy chain, two myosin light chains, two subunits of troponin and two subunits of tropomyosin is first detected at the time of myoblast fusion and then rapidly increase at least 500 fold to maximum rates which remain constant in muscle fibers. Both the kinetics of activation and the molar rates of synthesis of these contractile proteins are virtually identical. Muscle-specific actin (alpha) synthesis also increases at the time of myoblast fusion, but this actin (alpha) is synthesized at 3 times the rate of other contractile proteins. The synthesis of 30 other muscle cell proteins was quantitated, and most of these are shown to follow different patterns of regulation. From these results, we conclude that the contractile proteins are regulated coordinately during myoblast differentiation.     

Formation and stability of cytoplasmic mRNAs during myoblast differentiation: Pulse-chase and density labeling analyses

Stabilities and rates of formation of cytoplasmic mRNAs have been measured quantitatively in cultures of embryonic quail breast myoblasts undergoing differentiation to form muscle fibers. Uridine pulse-chase studies show that dividing myoblasts and differentiated fibers form both short- and long-lived mRNAs. Short-lived mRNAs in myoblasts and fibers have similar half-lives of 2–4 hr, however, long-lived mRNAs have a half-life of 60–100 hr in myoblasts and only 20 hr in fibers. When myoblasts fuse, the formation of long-lived cytoplasmic mRNAs increases at least twofold, and this increased formation together with the cessation of myoblast cell division at fusion is sufficient to account for the four- to fivefold accumulation of long-lived mRNA observed in fibers. These long-lived mRNAs were identified by density labeling cultures with ¹⁵N, ¹³C-nucleotides, chasing with light nucleosides, and then translating the density labeled mRNAs in wheat germ extracts. These experiments show that the contractile protein mRNAs, as well as 60–70 other muscle mRNAs are actively synthesized by muscle fibers and that all of the specific mRNAs detected have half-lives clustering around 20 hr.     

Nonmuscle Myosin-Dependent Synthesis of Type I Collagen

Type I collagen, synthesized in all tissues as the heterotrimer of two α1(I) polypeptides and one α2(I) polypeptide, is the most abundant protein in the human body. Here we show that intact nonmuscle myosin filaments are required for the synthesis of heterotrimeric type I collagen. Conserved 5′ stem-loop in collagen α1(I) and α2(I) mRNAs binds the RNA-binding protein LARP6. LARP6 interacts with nonmuscle myosin through its C-terminal domain and associates collagen mRNAs with the filaments. Dissociation of nonmuscle myosin filaments results in secretion of collagen α1(I) homotrimer, diminished intracellular colocalization of collagen α1(I) and α2(I) polypeptides (required for folding of the heterotrimer), and their increased intracellular degradation. Inhibition of the motor function of myosin has similar collagen-specific effects, while disruption of actin filaments has a general effect on protein secretion. Nonmuscle myosin copurifies with polysomes, and there is a subset of polysomes involved in myosin-dependent translation of collagen mRNAs. These results indicate that association of collagen mRNAs with nonmuscle myosin filaments is necessary to coordinately synthesize collagen α1(I) and α2(I) polypeptides. We postulate that LARP6/myosin-dependent mechanism regulates the synthesis of heterotrimeric type I collagen by coordinating the translation of collagen mRNAs.     

Regulation of muscle gene expression: The accumulation of messenger RNAs coding for muscle-specific proteins during myogenesis in a mouse cell line

The expression of RNA sequences coding for myofibrillar proteins has been followed during terminal differentiation in a mouse skeletal muscle cell line. Cloned complementary DNA probes hybridizing with the actins, skeletal muscle α-actin, myosin heavy chain and the myosin alkali light chains were employed in Northern blotting experiments with total cellular poly (A)-containing RNA extracted from the cultures at different times after plating. At the same times, parallel cultures were pulse-labelled with [³⁵S]methionine and the pattern of newly synthesized proteins was analysed by two-dimensional gel electrophoresis. Synthesis of skeletal muscle α-actin and of the myosin alkali light chains (LC_lemb, LC₁, LC₃) was not detectable in dividing myoblast cultures. From the onset of cell fusion, the synthesis of myosin heavy chain, LC_lemb and α-actin increases with similar kinetics. Synthesis of LC₃ (and trace amounts of LC_1F) is detectable and subsequently increases at later stages of myotube formation. The corresponding messenger RNAs coding for myosin heavy chain and skeletal muscle α-actin are first detectable immediately before the initiation of myofibrillar protein synthesis. mRNAs coding for the non-muscle actins are accumulated in myoblasts and diminish after cell fusion. Comparisons between muscle mRNAs depend on the relative sensitivities of the different probes, reflecting mainly their homology with the isoform of the actin or myosin multigene family expressed. Quantitative analysis of Northern blots gives an estimated increase in skeletal muscle α-actin mRNA, with an homologous probe, of at least 130-fold with a minimum level of detection of 40 to 80 molecules per cell. Accumulation of this species and of the myosin heavy chain mRNA follows similar kinetics. mRNA coding for LC₃, the principal myosin light chain detected with the probe, appears to accumulate to a lesser extent initially, paralleling synthesis of the corresponding protein. These results using cloned probes demonstrate a close temporal correlation between muscle mRNA accumulation and protein synthesis during terminal myogenesis in this muscle line.     

Activation of myosin synthesis in fusing and mononucleated myoblasts

The synthesis of the heavy chain subunit of myosin has been studied in breast muscle myoblasts from embryos of the Japanese quail, Coturnix coturnix japonica, during differentiation of these cells in culture. Specifically, these experiments were done to examine the roles of myoblast fusion and the regulation of myoblast cell division in the control of myosin heavy chain synthesis.The rates of myosin heavy chain synthesis have been quantitated in cultures of fusing myoblasts by measurement of the incorporation of radioactive leucine and valine precursors into myosin heavy chain, and simultaneous determination of the intracellular specific activities of these radioactive amino acids. These measurements demonstrate that, prior to fusion, dividing myoblasts synthesize little, if any, myosin heavy chain, but that during the period of myoblast fusion, myosin heavy chain synthesis becomes activated at least 50 to 100-fold. Myosin heavy chain synthesis was also measured in mononucleated myoblasts inhibited from fusing by the presence of EGTA in the culture medium. These experiments demonstrate that myosin synthesis can be activated in mononucleated myoblasts to reach rates similar to those attained in fused myoblasts. This activation occurs under conditions in which EGTA-inhibited myoblasts were induced to withdraw from the cell division cycle by reducing the concentrations of the serum and embryo extract components of the culture medium or by prior “conditioning” of standard growth medium.These experiments, therefore, establish that the activation of myosin synthesis in breast muscle myoblasts does not require fusion, but indicate that activation is co-ordinated with the withdrawal of myoblasts from the cell division cycle.     

Trypanosoma cruzi: reversal of inhibition of host muscle differentiation after exposure to elevated temperatures

The L6E9 myoblast cell line can be grown as individual cells in "growth medium," or can be induced to fuse and differentiate to form multinucleated myotubes either at 37 C or at 40.5 C in "differentiation medium." It has previously been shown that myoblasts with infected Trypanosoma cruzi (Brazil strain) cannot differentiate to form myotubes. Moreover, the mRNAs for contractile proteins are not induced in these infected cells. Infected myoblasts grown in "differentiation medium" at 37C were unable to differentiate by 7 days. The infection was maintained at 100%, and the number of trypomastigotes in the supernatant increased with time (peak greater than 10(6)/ml). At 40.5C, however, infected myoblasts gradually eliminated their infection. The percentage of parasitized cells was reduced to less than 1% by the 7th day of observation. There was also a decrease in the number of trypomastigotes in the supernatant. Moreover, significant fusion was observed in these cultures by morphological criteria. Using 32P-labeled recombinant DNA probes, it was shown that, at 37C, there was an inhibition of mRNAs for muscle-specific contractile proteins (myosin heavy chain and alpha-actin), whereas nonspecific mRNAs were not inhibited. Furthermore, infected myoblasts exposed to 40.5C exhibited no inhibition of mRNAs for myosin heavy chain and alpha-actin. Myoblasts cleared of their infection could readily be reinfected. This study demonstrates that the inhibition of muscle differentiation induced by T. cruzi is reversible when cultures are exposed to elevated temperatures.     

Cloning and characterization of cDNA sequences corresponding to myosin light chains 1, 2, and 3, troponin-C, troponin-T, alpha-tropomyosin, and alpha-actin

A library of cDNA clones was constructed from adult rat skeletal muscle mRNA, from which a set of contractile protein clones was selected. These clones were identified by sequencing the cDNA inserts and comparing the derived amino acid sequences with published sequences of rabbit contractile proteins. In this manner, clones corresponding to myosin light chains 1, 2, and 3, troponin-C, troponin-T, alpha-tropomyosin, and alpha-actin were identified. A high degree of amino acid sequence conservation was found upon comparison of the rat and rabbit proteins. Using the cDNA clone panel, we analyzed the expression of abundant rat muscle mRNAs. We show that abundant rat muscle mRNAs can be classified into four developmentally regulated groups, based upon their expression at different stages of myogenesis. One class of mRNAs is expressed during all stages of muscle development. Since these mRNAs are also present in nonmuscle tissues, we conclude that they code for housekeeping proteins. The second class of mRNAs is present in both embryonic and adult muscle, while a third class of mRNAs is expressed only in adult muscle. A small number of mRNAs, which are present at greater levels in undifferentiated myoblasts than in adult muscle, comprise a fourth class. These results suggest the existence of at least four modes of gene control during myogenesis.     

Role of LARP6 and Nonmuscle Myosin in Partitioning of Collagen mRNAs to the ER Membrane

Type I collagen is extracellular matrix protein composed of two α1(I) and one α2(I) polypeptides that fold into triple helix. Collagen polypeptides are translated in coordination to synchronize the rate of triple helix folding to the rate of posttranslational modifications of individual polypeptides. This is especially important in conditions of high collagen production, like fibrosis. It has been assumed that collagen mRNAs are targeted to the membrane of the endoplasmic reticulum (ER) after translation of the signal peptide and by signal peptide recognition particle (SRP). Here we show that collagen mRNAs associate with the ER membrane even when translation is inhibited. Knock down of LARP6, an RNA binding protein which binds 5′ stem-loop of collagen mRNAs, releases a small amount of collagen mRNAs from the membrane. Depolimerization of nonmuscle myosin filaments has a similar, but stronger effect. In the absence of LARP6 or nonmuscle myosin filaments collagen polypeptides become hypermodified, are poorly secreted and accumulate in the cytosol. This indicates lack of coordination of their synthesis and retro-translocation due to hypermodifications and misfolding. Depolimerization of nonmuscle myosin does not alter the secretory pathway through ER and Golgi, suggesting that the role of nonmuscle myosin is primarily to partition collagen mRNAs to the ER membrane. We postulate that collagen mRNAs directly partition to the ER membrane prior to synthesis of the signal peptide and that LARP6 and nonmuscle myosin filaments mediate this process. This allows coordinated initiation of translation on the membrane bound collagen α1(I) and α2(I) mRNAs, a necessary step for proper synthesis of type I collagen.     

Control mechanisms regulating gene expression during normal differentiation of myeloid leukemic cells: Differentiation defective mutants blocked in mRNA production and mRNA translation

Regulation of gene expression during myeloid cell differentiation has been analyzed using clones of myeloid leukemic cells that differ in their competence to be induced to differentiate by the normal macrophage- and granulocyte-inducing protein MGI. Changes in the relative rate of synthesis for specific proteins were compared to changes in the relative amounts of corresponding translatable poly(A)⁺ mRNAs, assayed in the reticulocyte cell-free translation system, using two-dimensional gel electrophoresis. Of the 217 proteins which changed during MGI-induced differentiation of normally differentiating MGI⁺D⁺ leukemic cells, 136 could be identified as products of cell-free translation. Eighty-four percent of the 70 decreases in synthesis, most of which occurred early during differentiation, were not accompanied by a parallel decrease in the amount of translatable mRNA, but were accompanied by a parallel shift of the corresponding mRNAs from the polysomal to the monosomal and free mRNA fractions. These results indicate that most of the early decreases in the synthesis of proteins were translationally regulated. In contrast, 81% of the proteins which increased in synthesis and 71% of the proteins that were induced de novo were regulated at the level of mRNA production. Experiments with differentiation defective mutants have shown that they were blocked both at the level of mRNA production and mRNA translation. The data with these mutants have suggested that there were different subsets of translationally regulated proteins which were separately regulated. The translational blocks for several proteins in these mutant clones have also made it possible to identify additional translational sites of regulation for protein changes that were controlled at the level of mRNA production during normal differentiation. The results indicate that translational regulation may predominantly have a different function in cell differentiation than regulation by mRNA production, and that differentiation-defective mutants can be blocked at either level.     

Evidence on the participation of protein kinase C alpha in the proliferation of cultured myoblasts.

There is evidence involving protein kinase C (PKC) in the signal transduction pathways that regulate the differentiation of myoblasts into mature multinucleated muscle cells (myotubes). In order to obtain information on the possible role of individual PKC isozymes in myogenesis, in the present work we investigated the differential expression of PKC isoforms alpha, beta, delta, epsilon, and zeta during muscle cell development in vitro. Chick embryo myoblasts cultured from 1 to 6 days were used as experimental model. Morphological characterization and measurement of specific biochemical parameters in cultures, e.g., DNA synthesis, creatine kinase activity, and myosin levels, revealed a typical muscle cell developmental pattern consisting of an initial proliferation of myoblasts followed by their differentiation into myotubes. PKC activity was high at the proliferation stage, decreased as myoblasts elongated and fused, and increased again in differentiated myotubes. In proliferating myoblasts, the PKC inhibitors calphostin C and bisindolylmaleimide I decreased DNA synthesis whereas in myoblasts undergoing differentiation they exerted the opposite effect, suggesting that PKC plays a role at both stages of myogenesis. Western blot analysis of changes in the expression of PKC isoforms during muscle cell development showed high levels of PKC alpha in the proliferating phase which markedly decreased as myoblasts differentiated. Treatment with TPA of proliferative myoblasts inhibited DNA synthesis and selectively down-regulated PKC alpha, suggesting that this isozyme may have an important role in maintaining myoblast proliferation. On the other hand, an increase in the expression of PKC beta, delta, and epsilon was detected during myogenesis, suggesting that one or more of these isoforms may participate in the differentiation process of myoblasts.     

Polysomes from cultured muscle cells: The cell-free synthesis of myosin

The results reported here have shown that there are significant differences between polysome patterns obtained from cultured cells and from freshly isolated muscle tissue. Polysomes from embryonic homogenates show different patterns with different levels of myosin synthesis, but this does not appear to be the case with cultured cells. Experiments utilizing cell-free protein synthesizing systems indicate that the polysomes isolated from myoblast cultures can synthesize myosin at levels similar to those obtained from myotube cultures, suggesting that the myoblasts contain significant amounts of the messenger RNA for myosin. In contrast, the polysomes isolated from BrdUrd-inhibited cultures synthesize a comparatively low level of myosin. These findings illustrate a significant difference between myoblasts and BrdUrd-inhibited cells.