Transfection of nonmuscle beta- and gamma-actin genes into myoblasts elicits different feedback regulatory responses from endogenous actin genes

We have examined the role of feedback-regulation in the expression of the nonmuscle actin genes. C2 mouse myoblasts were transfected with the human beta- and gamma-actin genes. In gamma-actin transfectants we found that the total actin mRNA and protein pools remained unchanged. Increasing levels of human gamma-actin expression resulted in a progressive down-regulation of mouse beta- and gamma-actin mRNAs. Transfection of the beta-actin gene resulted in an increase in the total actin mRNA and protein pools and induced an increase in the levels of mouse beta-actin mRNA. In contrast, transfection of a beta-actin gene carrying a single-point mutation (beta sm) produced a feedback-regulatory response similar to that of the gamma-actin gene. Expression of a beta-actin gene encoding an unstable actin protein had no impact on the endogenous mouse actin genes. This suggests that the nature of the encoded actin protein determines the feedback-regulatory response of the mouse genes. The role of the actin cytoskeleton in mediating this feedback-regulation was evaluated by disruption of the actin network with Cytochalasin D. We found that treatment with Cytochalasin D abolished the down-regulation of mouse gamma-actin in both the gamma- and beta sm-actin transfectants. In contrast, a similar level of increase was observed for the mouse beta-actin mRNA in both control and transfected cells. These experiments suggest that the down-regulation of mouse gamma-actin mRNA is dependent on the organization of the actin cytoskeleton. In addition, the mechanism responsible for the down-regulation of beta-actin may be distinct from that governing gamma-actin. We conclude that actin feedback-regulation provides a biochemical assay for differences between the two nonmuscle actin genes.     

Preferential expression of actin genes during oogenesis of Drosophila

The expression of actin genes was examined during oogenesis of Drosophila. Accumulation of actin proteins was quantitated by a two-stage electrophoresis procedure. Egg chambers accumulate actins preferentially, resulting in a twofold enrichment over other nonyolk proteins. RNA gel blot hybridization experiments demonstrated a concomitant twofold selective increase of actin mRNA levels over that of other mRNAs, suggesting regulation of actin genes at the pretranslational level. Despite an abrupt arrest of actin protein accumulation near the end of oogenesis, the bulk of the actin mRNAs remains associated with polysomes of constant size. It appears that this shut-off of actin protein accumulation is due to an overall decrease in translational efficiency, rather than actin mRNA degradation or its dissociation from polysomes.     

Biochemical characterization and expression analysis of neural thrombospondin-1-like proteins NELL1 and NELL2.

Two closely related genes coding for NELL proteins (NELL1 and NELL2) have been cloned by the yeast two-hybrid screening of a rat brain cDNA library with the regulatory domain of protein kinase C betaI (PKCbetaI) as bait. The rat NELL proteins show about 55% identity with each other and contain several protein motifs assigned to a secretion signal peptide, an NH(2)-terminal thrombospondin-1 (TSP-1)-like module, five von Willebrand factor C domains, and six epidermal growth factor-like domains; the NELL proteins share many protein motifs with TSP-1. The NELL proteins expressed in COS-7 cells are homotrimeric glycoproteins and possess heparin-binding activity. Furthermore, while NELL1 and NELL2 show distinct subcellular localization in cytoplasm, they both are partially secreted into the culture medium of COS-7 cells. Although the NELL1 mRNA is faintly expressed in adult neural cells, the NELL2 mRNA is expressed abundantly, particularly in the pyramidal cells of rat hippocampus, showing neuronal high plasticity. During mouse embryogenesis, expression of the NELL2 mRNA is initiated 7-11 days postcoitum, simultaneously with neural plate formation. These results strongly suggest that the NELL2 protein, similar to but not identical with TSP-1, is involved in the growth and differentiation of neural cells. Additionally, the NELL1 and NELL2 mRNAs were found to be expressed abundantly in Burkitt's lymphoma Raji cells and colorectal adenocarcinoma SW480 cells, respectively. Thus, it is likely that the NELL proteins also participate in the growth, differentiation, and oncogenesis of cancer cell lines.     

Cardiac actin is the major actin gene product in skeletal muscle cell differentiation in vitro.

We examined the expression of alpha-skeletal, alpha-cardiac, and beta- and gamma-cytoskeletal actin genes in a mouse skeletal muscle cell line (C2C12) during differentiation in vitro. Using isotype-specific cDNA probes, we showed that the alpha-skeletal actin mRNA pool reached only 15% of the level reached in adult skeletal muscle and required several days to attain this peak, which was then stably maintained. However, these cells accumulated a pool of alpha-cardiac actin six times higher than the alpha-skeletal actin mRNA peak within 24 h of the initiation of differentiation. After cells had been cultured for an additional 3 days, this pool declined to 10% of its peak level. In contrast, over 95% of the actin mRNA in adult skeletal muscle coded for alpha-actin. This suggests that C2C12 cells express a pattern of sarcomeric actin genes typical of either muscle development or regeneration and distinct from that seen in mature, adult tissue. Concurrently in the course of differentiation the beta- and gamma-cytoskeletal actin mRNA pools decreased to less than 10% of their levels in proliferating cells. The decreases in beta- and gamma-cytoskeletal actin mRNAs are apparently not coordinately regulated.     

Temporal resolution and sequential expression of muscle-specific genes revealed by in situ hybridization

The expression of muscle-specific mRNAs was analyzed directly within individual cells by in situ hybridization to chicken skeletal myoblasts undergoing differentiation in vitro. The probes detected mRNAs for sarcomeric myosin heavy chain (MHC) or the skeletal, cardiac, and beta isoforms of actin. Precise information as to the expression of these genes in individual cells was obtained and correlated directly with analyses of cell morphology and interactions, cell cycle stage, and immunofluorescence detection of the corresponding proteins. Results demonstrate that mRNAs for the two major muscle-specific proteins, myosin and actin, are not synchronously activated at the time of cell fusion. The mRNA for alpha-cardiac actin (CAct), known to be the predominant embryonic actin isoform in muscle, is expressed prior to cell fusion and prior to the expression of any isoform of muscle MHC mRNA. MHC mRNA accumulates rapidly immediately after fusion, whereas skeletal actin mRNA is expressed only in larger myofibers. Single cells expressing CAct mRNA have a characteristic short bipolar morphology, are in terminal G1, and do not contain detectable levels of the corresponding protein. In a pattern of expression reciprocal to that of CAct mRNA, beta-actin mRNA diminishes to low or undetectable levels in myofibers and in cells of the morphotype which expresses CAct mRNA. Finally, the intracellular distribution of mRNAs for different actin isoforms was compared using nonisotopic detection of isoform-specific oligonucleotide probes. This work illustrates a generally valuable approach to the analysis of cell differentiation and gene expression which directly integrates molecular, morphological, biochemical, and cell cycle information on individual cells.     

Expression of actin mRNAs in denervated chicken skeletal muscle

The expression of actin genes in chicken pectoralis muscle denervated 1 week after hatching was examined 1-8 weeks after the operation by RNA blot hybridization using a generic actin cDNA probe and DNA probes specific for alpha-skeletal and alpha-cardiac actin genes. Total and alpha-skeletal actin mRNAs/microgram total RNA decreased to about half of the levels found in contralateral control muscle, while the expression of alpha-cardiac actin mRNA was up-regulated. Consequently, alpha-cardiac actin mRNA formed about 15% of the total actin mRNA as compared to less than 1% found in control muscle. The expression of actin genes in the denervated muscle was similar to that in the late embryonic muscle. These results suggest that innervation is required to show the expression pattern of striated muscle actin genes found in mature muscle.     

In postmeiotic male germ cells poly (A) shortening accompanies translation of mRNA encoding γ enteric actin but not cytoplasmic β and γ actin mRNAs

In the mammalian testis the cytoplasmic β and γ actins are expressed in all stages of germ-cell differentiation, whereas γ enteric actin is expressed in germ cells solely in postmeiotic stages. Northern blot analysis of mouse testicular RNAs reveals actin mRNAs of about 2.1, 1.5, and 1.4 kB. The 2.1-kB mRNAs encode the cytoplasmic β and γ actins, whereas the two faster-migrating actin mRNAs encode γ enteric actin. When post-mitochondrial mouse testis extracts are fractionated by sucrose gradient centrifugation, the 1.5-kB γ enteric actin mRNA is primarily found in the nonpolysomal fraction, whereas the 1.4-kB γ enteric actin is polysomal. When the poly (A) tails are removed, the nonpolysomal and polysomal γ enteric actin mRNAs both migrate at 1.3 kB, indicating that the difference in electrophoretic mobilities of the two γ enteric actin mRNAs is caused by poly (A) length differences. The nonpolysomal and polysomal forms of the cytoplasmic β and γ actins show similar electrophoretic mobilities before and after deadenylation. Sequence comparison of the 3′ untranslated region of the mouse γ enteric actin to the 3′ untranslated regions of other testicular mRNAs that undergo partial deadenylation reveals three highly-conserved sequence elements. These data demonstrate that the poly (A) shortening of polysomal mRNAs previously seen only with testis-specific mRNAs that are stored as mRNPs also occurs with mRNAs of widely-expressed genes that are expressed in postmeiotic male germ cells. The mRNAs all contain specific conserved sequence elements in their 3′ untranslated regions. © 1996 Wiley-Liss, Inc.     

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.     

Retracted: Smad4 gene silencing enhances the chemosensitivity of human lymphoma cells to adriamycin via inhibition of the activation of transforming growth factor β signaling pathway

There are diverse investigations focused on the therapies of lymphoma. Our research was taken to identify the effects of lentiviral-mediated Smad4 gene silencing on chemosensitivity of human lymphoma cells to adriamycin (ADM) via transforming growth factor β (TGFβ) signaling pathway. Raji/ADM cells were cultured and infected with lentiviral particles Smad4-short hairpin (shRNA) and control-shRNA. Then, the messenger RNA (mRNA) and protein levels of TGFβ signaling pathway–related factors (Smad4, Smad3, cyclinE, cyclinD1, and p21) in Raji/ADM cells were determined. The effect of Smad4-shRNA on cell viability, invasion and migration, and apoptosis were also detected. Compared with the Raji group, increased mRNA and protein levels of Smad4, Smad3, cyclinE, cyclinD1, enhanced cell proliferation, migration and invasion as well as decreased mRNA, and protein levels of p21 and cell apoptosis rate were found in the Raji/ADM and control-shRNA groups. However, Smad4 gene silencing resulted in decreased mRNA and protein levels of Smad4, Smad3, cyclinE, and cyclinD1 along with inhibited cell proliferation, migration and invasion but increased expression of p21 together with cell apoptosis. Collectively, Smad4 gene silencing can inhibit the activation of TGFβ signaling pathway, thereby enhancing the chemosensitivity of human lymphoma cells to ADM.     

Simultaneous expression of early and late histone messenger RNAs in individual cells during development of the sea urchin embryo

The transition from early (E) to late (L) histone gene expression in developing sea urchin (Strongylocentrotus purpuratus) embryos was examined for H2B, H3, and H4 mRNAs by in situ hybridization of class-specific probes. Hybridization patterns indicate that the shift from E to L mRNAs occurs gradually and simultaneously in all blastomeres. Thus, during the transition the ratio of L to E mRNAs is similar in most cells. This suggests that no sudden changes in histone composition occur in individual cells which might be related to alterations in gene expression associated with differentiation of cell lineages. Around the midpoint of the transition, clusters of cells progressively appear which contain little, if any, E or L histone mRNA. This modulation of expression is coordinated for the three late genes examined because most individual cells contain either high or low levels of all three mRNAs. At blastula stage these clusters of unlabeled cells appear to be randomly distributed throughout the embryo. Subsequently the unlabeled regions expand and are found predominantly in aboral ectoderm as these cells cease to divide. Thus, the L/E histone mRNA ratio is not differentially regulated in diverse cell lineages, and the major differences in total histone mRNA content among individual cells may be related to cell cycle and/or the cessation of division.