Activity of a novel PDGF beta-receptor enhancer during the cell cycle and upon differentiation of neuroblastoma

PDGF acts as an autocrine and paracrine factor in certain tumors through upregulation of the PDGF beta-receptor expression. In order to elucidate the control mechanism for the receptor expression, we have isolated an enhancer from two P1 clones that together contain a 102 kb NotI region covering the entire human PDGFRB gene. They were partially digested with TspI and cloned into the PDGFRB enhancer trap vector to make a library for identification of enhancers. The digested DNA containing enhancer was identified by expression of GFP when transfected in PDGF beta-receptor expressing cells. One of the enhancer clones was further examined by making several deletion mutants in a luciferase vector. This enhancer was most active in neuroblastoma cells, IMR32 and BE2, but less active in hemangioma and in smooth muscle cell lines. Chip assay revealed that SP1, AP2, and GATA2 bound the enhancer in BE2 cells. Their interaction occurred dependently of the cell cycle and synchronously with their binding to the promoter. Transfection of GATA2 alone or with Ets, which binds adjacent to GATA, resulted in differentiation of BE2 cells in parallel with increased PDGF beta-receptor expression. Furthermore, over-expression of the PDGF beta-receptor in BE2 cells induced neurite extension.     

Phosphofructokinase isozyme expression during myoblast differentiation

Isozyme expression of phosphofructokinase (PFK), the key regulatory enzyme for glycolysis, was studied during differentiation of mouse C2 myoblasts to myotubes. The total PFK activity increased 20-fold during in vitro myogenesis. The rate of synthesis, relative to the rate of total protein synthesis, measured by pulse labeling and immunoprecipitation was lowest for muscle PFK (PFK-A), 0.008% in myoblasts, while those for liver (PFK-B) and brain (PFK-C) PFK were 0.017 and 0.014%, respectively. The relative rate of PFK-A synthesis increased sharply (5-fold) at an initial period of differentiation (8 h) and reached maximum of 10-fold at 48 h, to make PFK-A the major isoform synthesized in myotubes. The relative rates of synthesis for both PFK-B and PFK-C did not change drastically, decreasing slightly at 8 h, but were restored to 1.5-2-fold of myoblasts. cDNA sequences coding for mouse muscle PFK were cloned and used along with those for mouse liver PFK, which we have previously cloned, to measure by Northern blot analysis under highly stringent conditions the steady-state mRNA concentrations for muscle and liver PFK during C2 differentiation. The hybridizable mRNA level for PFK-A increased gradually, reaching 13-fold at 48 h when 80% of cells was fused to myotubes. The PFK-A mRNA level at 96 h was 90-fold of that for myoblasts. In contrast, the mRNA level for PFK-B increased slightly during differentiation, showing a maximum of 4-fold at 96 h. These results indicate isozyme-specific control of muscle PFK gene expression during C2 myoblast differentiation.     

Differential immunoreactivity for Z-DNA in rat myoblast nuclei during their terminal differentiation

L6 myoblasts in vitro accomplish the process of terminal differentiation from dividing mononucleated cells to quiescent plurinucleated myotubes, synthesizing muscle-specific proteins. They have been tested, using paraformaldehyde and acetic acid fixations and immunocytochemical techniques, for the presence of Z-DNA at different stages: namely after 3, 5 and 8-9 days of culture. The nuclei of the actively dividing 3-day myoblasts were strongly Z-DNA and B-DNA-positive. The inhibition of replication by araC did not diminish the reaction. In the myotubes, the nuclei became Z-DNA-negative but were still B-DNA-positive. In contrast, the nuclei of a non-fusing alpha-amanitin-resistant mutant (Ama102) stayed Z-DNA-positive. These results tend to show that during the process of terminal differentiation Z-DNA either becomes less accessible or is present in undetectable amounts. In circular DNAs, it has been shown that the presence of Z-DNA depends on their negative supercoiling. In addition, the presence of closed superhelical loops of nuclear DNA has been demonstrated in several mammalian cell types; moreover, the density of DNA topological turns in these loops varies during cellular differentiation and malignant transformation. The relationship between these results and ours is discussed.     

Post-transcriptional regulation of ribosome accumulation during myoblast differentiation

The synthesis, accumulation and stability of rRNA were examined in embryonic quail myoblasts differentiating in cell culture. Quail myoblasts initially divide rapidly in culture, and accumulate 28S and 18S rRNA and ribosomes at a rate which maintains a constant ribosome content during cell division. After these myoblasts fuse, cell division ceases and ribosomes accumulate in fibers, but at a reduced rate which is only one fourth that in dividing myoblasts. Measurements of rRNA stability by 3H-methyl-methionine pulse-chase analysis show that 28S and 18S rRNA formed by fibers turn over with half-lives of 45 hr, and rRNA formed by myoblasts remains stable until fusion and then also turns over in fibers. Turnover of rRNA in fibers accounts for only half the reduction in ribosome accumulation following myoblast fusion. Measurements of the incorporation of 3H-adenosine into rRNA and ATP pools show that the rates of synthesis of rRNA precursor do not decrease after myoblast fuse, but half the rRNA molecules synthesized by fibers are degraded during processing. Degradation of rRNA during processing reduces the rate of formation of 28S and 18S rRNA, and together with rRNA turnover quantitatively accounts for the reduced rate of ribosome accumulation in fibers.     

Expression of chimeric human beta- and delta-globin genes during erythroid differentiation

To determine whether sequences contained within the small intervening sequence (IVS 1) or large intervening sequence (IVS 2) are involved in the regulated expression of the human beta-globin gene, chimeric genes containing portions of the human beta- and delta-globin genes were stably transfected into mouse erythroleukemia (MEL) cells. Since MEL cells can be induced to differentiate in culture, the expression of the chimeric genes was compared to the expression of beta and delta both before and after the induction of erythroid differentiation. The expression of beta delta 1, a beta-globin gene containing delta IVS 1 in place of beta IVS 1, was comparable to the expression of a beta-globin gene both before and after erythroid differentiation. However, the base-line expression of human beta-globin genes containing delta IVS 2 in place of beta IVS 2 was dramatically decreased. Furthermore, the substitution of delta IVS 2 for beta IVS 2 prevented the regulated increase in expression of the beta-globin gene upon induction. The results also indicate that sequences present in beta IVS 2 are not sufficient for this induced increase in expression since the substitution of beta IVS 2 for delta IVS 2 in a delta gene does not increase the regulated expression of delta during differentiation. These experiments suggest that either the presence of delta IVS 2 in a beta gene interrupts sequences required for the induced expression of beta-globin or that sequences in beta IVS 2 act in concert with other beta globin sequences not present in the delta-globin gene to permit optimal expression.     

Chromatin protein kinases and phosphoproteins during myoblast growth and differentiation

A photolabile derivative of α-bungarotoxin which binds specifically to $\text{Torpedo}\text{californica}$ acetylcholine receptor has been used to investigate the topography of the membrane associated protein. It is shown that the toxin can be crosslinked to a polypeptide of 40,000 daltons, to which it is known to bind, and in addition to another polypeptide of 65,000 daltons which is a major constituent of the membrane. The results substantiate the notion that this nicotinic acetylcholine receptor is composed of different polypeptides and that some of these interact with each other or are in close proximity on the exterior surface of the post-synaptic membrane.     

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.     

Effect of receptor kinase inactivation on the rate of internalization and degradation of PDGF and the PDGF beta-receptor

The complementary DNAs for wildtype and tyrosine kinase-inactivated (K634A) forms of the PDGF beta-receptor were expressed in porcine aortic endothelial cells. We examined the internalization and degradation of ligands and receptors after exposure of receptor expressing cells to PDGF-BB, which binds to the beta-receptor with high affinity, and PDGF-AB, which binds with lower affinity. Cells expressing wildtype beta-receptors were able to internalize and degrade the receptor, as well as the ligand, after exposure to PDGF-BB or -AB. Cells expressing the kinase-inactivated mutant receptor also internalized and degraded both receptor and ligand, but with lower efficiency compared with the wildtype receptor cells. The degradation of either form of receptor was inhibited by treatment of the cells with the lysosomotropic drug chloroquine. Exposure of wildtype and K634A receptor expressing cells to PDGF-AB resulted in a twofold slower rate of internalization of this ligand as compared with PDGF-BB, whereas the relative rate of degradation was similar for the two ligands. Our data indicate that tyrosine kinase activity promotes, but is not a prerequisite for, ligand-induced internalization and degradation of the ligand-receptor complex.     

Expression profiles for six zebrafish genes during gonadal sex differentiation

Background  

The mechanism of sex determination in zebrafish is largely unknown and neither sex chromosomes nor a sex-determining gene have been identified. This indicates that sex determination in zebrafish is mediated by genetic signals from autosomal genes. The aim of this study was to determine the precise timing of expression of six genes previously suggested to be associated with sex differentiation in zebrafish. The current study investigates the expression of all six genes in the same individual fish with extensive sampling dates during sex determination and -differentiation.     

Coordinate accumulation of contractile protein mRNAs during myoblast differentiation.

The synthesis of contractile protein mRNAs has been studied during the differentiation of quail skeletal muscle myoblasts in culture. Eight contractile protein mRNAs were identified by translation of total cellular RNA isolated from differentiated myofibers in wheat germ and reticulocyte lysates. Products of the translation systems were fractionated by two-dimensional gel electrophoresis, and incorporation of [³⁵S]methionine into individual contractile proteins was quantitated by computerized densitometry of autoradiograms. These translation assay systems were used to quantitate levels of contractile protein mRNAs in cultures of myoblasts undergoing highly synchronous differentiation. Our results show that dividing myoblasts contain very little, if any, translatable contractile protein mRNA. The mRNAs coding for myosin heavy chain, the musclespecific actin, three myosin light chains, two tropomyosin subunits, and one troponin subunit begin to coordinately accumulate at fusion, when contractile protein synthesis is activated. Their levels increase 50- to 200-fold during the next 30 hr, paralleling increases in the rates of contractile protein synthesis. These results indicate that the contractile protein mRNAs accumulate coordinately during myoblast differentiation and that contractile protein synthesis is regulated by changes in the levels of these mRNAs.