Hierarchies of regulatory genes may specify mammalian development

Rhabdomyosarcoma of the Long Bone in an Adult

Rhabdomyosarcoma is one of the most common sarcomas of childhood. It usually arises in the soft tissues but may involve bone by several different mechanisms, includ ing direct extension, metastatic spread, as a component of dedifferentiated chondrosar coma or malignant mesenchymoma, or as a primary tumor. Only nine cases of primary rhabdomyosarcoma of bone have been previously reported, many of them not well documented. The histologic, immunohistochemical, and ultrastructural findings of a primary rhabdomyosarcoma of the femur in a 68-year-old woman are presented. Also discussed are the different aspects of skeletal muscle differentiation in bone tumors and the possible explanation for the rarity of primary skeletal rhabdomyosarcoma. Int J Surg Pathol 1(4):253-260, 1994

Epigenetic mechanisms for primary differentiation in mammalian embryos

This review examines main developments related to the interface between primary mammalian cell differentiation and various aspects of chromosomal structure changes, such as heterochromatin dynamics, DNA methylation, mitotic recombination, and inter- and intrachromosomal differentiation. In particular, X chromosome difference, imprinting, chromosomal banding, methylation pattern, single-strand DNA breaks, sister chromatid exchanges (SCEs), and sister chromatid asymmetry are considered. A hypothesis is put forward which implies the existence of an epigenetic asymmetry versus mirror symmetry of sister chromatids for any DNA sequences. Such epigenetic asymmetry appears as a result of asymmetry of sister chromatid organization and of SCE and is a necessary (not sufficient) condition for creating cell diversity. The sister chromatid asymmetry arises as a result of consecutive rounds of active and passive demethylation which leads after chromatin assembly events to chromatid difference. Single-strand DNA breaks that emerge during demethylation trigger reparation machinery, provend as sister chromatid exchanges, which are not epigenetically neutral in this case. Taken together, chromatid asymmetry and SCE lead to cell diversity regarding their future fate. Such cells are considered pluripotent stem cells which after interplay between a set of chromosomal domains and certain substances localized within the cytoplasmic compartments (and possibly cell interactions) can cause sister cells to express different gene chains. A model is suggested that may be useful for stem cell technology and studies of carcinogenesis.

Cystic fibrosis revisited

Cystic fibrosis is a pleiotropic disease whose primary defect is thought to be abnormal chloride conductance. Despite intensive study, the role of the protein in the airway and the mechanism for its direct participation in the disease pathology remain unclear. This paper reviews CFTR's cell regulatory functions and data supporting the role of CFTR in secretory epithelial cell development. A hypothesis for CF pathophysiology based on secretory cell differentiation is proposed.

Modification of development by the CFTR gene in utero

The in utero infection of rats at 16-17 days gestation with a recombinant adenovirus carrying the human cystic fibrosis transmembrane conductance regulator (cftr) gene resulted in altered lung development and morphology. These structural alterations prompted an evaluation of concurrent functional changes in the cftr-treated lung. CFTR protein could be detected in treated lungs for up to 30 days postinfection, although it was not detected in the intestines at this time. Increased levels of secreted glycoconjugates and lipids were found in lungs treated in utero with human cftr and large vacuoles containing glycoconjugates were detected within cells of the intestines. The scope and durability of these changes suggested that in utero cftr treatment influenced the activity of secretory cells in the developing lung. Altered secretory products in the lungs of cystic fibrosis patients are thought to be associated with increased susceptibility to Pseudomonas aeruginosa infection. We challenged 3-month-old rats (treated in utero with the human cftr gene) with a lethal, intratrachial dose of this bacteria. Rats treated with cftr exhibited enhanced resistance to Pseudomonas infection when compared to controls. These animals displayed little or no associated inflammatory response. No evidence of the adenovirus transgene was detectable at the time of P. aeruginosa inoculation, indicating that continuous ectopic expression of hcftr was not required for enhanced protection. These data demonstrate that in utero, cftr expression influenced the development and function of cells involved in the primary host defense against bacterial infection in the lung.

Molecular pathophysiology of cystic fibrosis based on the rescued knockout mouse model

Cystic fibrosis transmembrane conductance regulator (cftr) gene mutations are thought to result in cystic fibrosis due to an absence of the protein's chloride channel. Recently, the lethal intestinal blockage in the cftr knockout mouse was reversed by a single in utero dose of a recombinant adenovirus containing the human cftr gene. The rescue of these animals did not require continuous expression of the gene and the cAMP-dependent chloride channel was not permanently restored. These data suggested that cftr was required for normal development of the intestine but not for normal function of the adult organ. Phenotypic changes in the intestines and lungs of in utero cftr-treated knockout and heterozygous mice revealed that altered development was induced. The intestines of the untreated knockout mice were shown to be deficient in both intracellular calcium and UTP receptors. Both of these deficiencies were partially corrected in the rescued knockout mice, whereas treatment of heterozygous animals disrupted the normal pattern of these markers. Examination of the lungs of knockout cftr (-/-) mice with lectins showed an increase in secreted glycoconjugates containing alpha(2,6)-sialic acid and fucose as compared with control heterozygotes. The in utero-treated knockouts showed an increase in this material as well, but it was contained in intracellular vesicles. Electron microscopy of these tissues confirmed the developmental alteration of secretory cell differentiation in the lungs. These data show that cftr is required in both the lung and intestines for normal differentiation of a secretory cell population and that in its absence these cells fail to develop properly.

mex-1 and the general partitioning of cell fate in the early C. elegans embryo

It is thought that at least some of the initial specification of the five somatic founder cells of the C. elegans embryo occurs cell-autonomously through the segregation of factors during cell divisions. It has been suggested that in embryos from mothers homozygous for mutations in the maternal-effect gene mex-1, four blastomeres of the 8-cell embryo adopt the fate of the MS blastomere. It was proposed that mex-1 functions to localise or regulate factors that determine the fate of this blastomere. Here, a detailed cell lineage analysis of 9 mex-1 mutants reveals that the fates of all somatic founder cells are affected by mutations in this gene. We propose that mex-1, like the par genes, is involved in establishing the initial polarity of the embryo.

Expression and differential regulation of Id1, a dominant negative regulator of basic helix-loop-helix transcription factors, in glomerular mesangial cells

Id is a family of dominant negative helix-loop-helix (HLH) proteins that block cell-specific transcription mediated by basic HLH (bHLH) transcription mediated by basic HLH (bHLH) transcription factors. We have analyzed Id1 expression in mesangial cells as a first step towards understanding the putative role of bHLH transcription factors in cell type-specific gene expression in the kidney. Glomerular mesangial cells expressed an abundant 1.1 kb mRNA transcript for Id1, but in contrast to other cell types Id1 mRNA was expressed in both randomly cycling cells and in serum-deprived, quiescent cultures. When quiescent mesangial cells were treated with serum to re-enter G1, Id1 mRNA levels were rapidly (2-4 h) and transiently down-regulated. Down-regulation of Id1 mRNA following addition of serum to mesangial cells was cell type-specific and contrasted with induction of Id1 by serum in BHK-21 and 3T3 fibroblasts. Down-regulation of Id1 mRNA correlated with mitogenesis and occurred when quiescent cells were treated with growth factors that activate G protein-coupled receptors and receptor protein tyrosine kinases but not with a non-mitogenic cAMP analog. Down-regulation of Id1 by growth factors required de novo protein synthesis, suggesting that a labile protein was involved. Appearance of E-box DNA binding activity in mesangial cell extracts followed down-regulation of Id1 message. Steady state Id1 mRNA levels and E-box DNA binding activity were not tightly correlated, suggesting complex regulation of Id1 activity. mRNA transcripts for E2A gene products were also expressed in mesangial cells, but these cells failed to express mRNAs for MyoA/MyoD-related genes. Collectively, these data demonstrate that Id1 is expressed in renal mesangial cells and suggest that bHLH complexes might be important for transcriptional regulation in the kidney. In addition, the observation that Id1 mRNA is transiently down-regulated by serum in mesangial cells suggests that Id1 gene expression is more complicated than previously appreciated and is tightly regulated in a cell-specific manner.

Degeneration of skeletal and cardiac muscles in c-myb transgenic mice

In order to reveal cellular processes sensitive to abnormal c-myb expression in vivo, transgenic mice were produced by introducing the c-myb nuclear proto-oncogene under the ubiquitous transcriptional regulatory unit of the cytoplasmic beta-actin gene. Expression of c-myb in thymus did not cause apparent abnormality, but the mice unexpectedly developed degenerative abnormalities in skeletal and cardiac muscles; this occurred predominantly in males. Expression of c-myb in skeletal muscle was correlated with an inflammation of muscle and was accompanied by vacuolar degeneration of muscle fibres, their regeneration, and lymphocyte infiltration. The identical pathological progression in cardiac muscle was associated with cardiomegaly.

Trans-activation of the murine dystrophin gene in human-mouse hybrid myotubes

Myotube cultures of the myogenic cell line, C2, produce significantly lower levels of dystrophin than primary mouse cultures. We demonstrate that expression of the C2 dystrophin gene increases 10-fold in hybrid myotubes formed by fusion of C2 and dystrophin-deficient human myoblasts from a Duchenne muscular dystrophy patient. These results indicate that C2 cells are deficient in endogenous gene regulatory factors which enhance dystrophin expression, and that the C2 cell line may therefore be used to identify putative trans-acting factors involved in the regulation of dystrophin gene expression.

Techniques for cloning cDNAs encoding interactive transcriptional regulatory proteins

Several approaches aimed at detecting and cloning interactive transcriptional regulatory proteins have been presented. All of the techniques can effectively identify specific interactions between two transcription proteins. However, interaction cloning and the two hybrid system have the added advantage of yielding a cDNA expression clone directly. The other methods, EMSA-mediated cloning, co-immunoprecipitation, oligonucleotide/PCR-facilitated cloning, Southwestern, and Farwestern, require additional manipulations to obtain a cDNA clone. Clearly, the interactive cloning system of choice will depend on the proteins under investigation.

Stable hybrid myotubes: a new model for studying re-expression of enzymatic activities in vitro

Heterokaryons represent a stable and reproducible model system for the study of biochemical and molecular aspects responsible for muscle gene activation. Previous experiments have used this fusion system to demonstrate human gene activation in hybrids formed between human and non-human cells. The aim of this research was to apply this experimental model to the correction of a cytoplasmic activity, namely glucose-6-phosphate dehydrogenase (G6PD), in vitro, in hybrid myotubes formed between G6PD-negative and positive myoblasts. Different identification methods were used (Hoechst stain and Fluorescent Latex Microspheres, FLMs) to identify hybrid myotubes formed. We demonstrated the restoration of G6PD activity in all hybrid myotubes formed; we then tried to elucidate the mechanisms underlying the restoration of this specific activity and apply the results obtained to the understanding of more complex mechanisms involved in muscle gene activation.

Basement membrane and interstitial matrix components form separate matrices in heterokaryons of PYS-2 cells and fibroblasts

In order to gain further understanding of the spatial organization of interstitial and basement membrane matrices, we studied the expression of the interstitial matrix protein, fibronectin, and the basement membrane protein, laminin, in heterokaryons formed by the fusion of normal fibroblasts and teratocarcinoma-derived epithelial PYS-2 cells. These heterokaryons showed various distributions of the matrix proteins depending on the proportions of the different parental cell nuclei within the cytoplasm of the cell. Heterokaryons containing equal numbers of fibroblast and PYS-2 cell nuclei showed an abundant laminin matrix subcellularly and only minor amounts of fibronectin matrix at the periphery of the cells. Similar results were obtained in heterokaryons containing an excess of epithelial cell nuclei. In heterokaryons containing an excess of fibroblast nuclei, on the other hand, laminin matrix was reduced and a fibrillar fibronectin matrix was seen also on top of the cell body. The results suggest a gene dosage-type of effect on the expression of these proteins. Furthermore, extracellular laminin and fibronectin matrices did not codistribute around the heterokaryons but the two proteins were assembled into separate structures. The lack of codistribution of fibronectin and laminin matrices in heterokaryons suggests that the molecular interactions, which determine the assembly of basement membrane and interstitial matrices in these cells are highly type-specific. Similar mechanisms may also operate in the assembly of extracellular matrices in vivo.

cis-4-Hydroxy-L-proline and ethyl-3,4-dihydroxybenzoate prevent myogenesis of C2C12 muscle cells and block MyoD1 and myogenin expression

cis-4-Hydroxy-L-proline (cis-OH-Pro) and ethyl-3,4-dihydroxybenzoate (EDHB), two distinct inhibitors of collagen synthesis, prevented myogenesis in C2C12 mouse skeletal muscle cells. Both inhibitors blocked myotube formation and the expression of sarcomeric myosin heavy chain. Northern blot analysis showed that cis-OH-Pro- and EDHB-treated C2C12 muscle cells did not express the myogenic regulatory genes, MyoD1 and myogenin, but continued to express non-muscle isoforms of actin (beta and gamma) and alpha-tropomyosin. 10TFL2-3B cells, a C3H10T1/2 cell line permanently transfected with myogenin cDNA, constitutively expressed exogenous myogenin in the presence of cis-OH-Pro but failed to activate endogenous myogenin and to undergo myogenesis. These results demonstrate that commitment to terminal differentiation and activation of myogenic regulatory genes requires active synthesis of the extracellular matrix component collagen.

Isoprenoids and astroglial cell cycling: diminished mevalonate availability and inhibition of dolichol-linked glycoprotein synthesis arrest cycling through distinct mechanisms

Primary astroglial cultures were used to compare the relationships to cell cycling of dolichol-linked glycoprotein synthesis, and of availability of mevalonate, the precursor of dolichol and other isoprenoid lipids. With shift-up to 10% serum (time 0) after 48 h of serum depletion, the proportion of cells in S phase (bromodeoxyuridine immunofluorescence) remained under 15% for 12 h, then increased by 20 h to 72 +/- 10%; DNA synthetic rates (thymidine incorporation) increased 5-fold. S phase transition was prevented by addition at 10-12 h of tunicamycin, an inhibitor of transfer of saccharide moieties to dolichol. Mevinolin, an inhibitor of mevalonate biosynthesis, also blocked cycle progression when added at this time. However, mevinolin markedly inhibited the isoprenoid pathway, as reflected by over 90% reduction of sterol synthesis, without inhibiting net glycoprotein synthesis. Removal of mevinolin after a 24 h exposure delayed S phase until 48 h, following recovery of sterol synthesis, even though kinetics of glycoprotein synthesis were unaffected. Tunicamycin removal after 24 h spared sterol synthesis, but caused delay of S phase until 72 h, following recovery of glycoprotein synthesis. In mevinolin-treated cultures, S phase transition was restored by 1 h of exposure to mevalonate at 10 h, although cycling was thereby rendered sensitive to inhibition by cycloheximide and by tunicamycin. Cell cycle progression following hydroxyurea exposure and release was unaffected by mevinolin, tunicamycin, or cycloheximide. Thus, in these developing astroglia, mevalonate and its isoprenoid derivatives have at least two cell cycle-specific roles: dolichol-linked glycoprotein synthesis is required at or before the G1/S transition, while a distinct mevalonate requirement is apparent also in late G1.

From growth arrest to growth suppression

Since the introduction of the cell cycle concept two approaches to study growth regulation of cells have been proposed. One claims that cells are naturally quiescent, requiring a stimulatory encouter with growth factors for induction of cell division. The other considers cellular multiplication as the natural steady-state; cessation of multiplication is thus a restriction imposed on the system. In the latter case emphasis is mainly on the signals involved in arrest of multiplication. This Prospect focuses on specific events occurring in mammalian cells at growth arrest, senescence, and terminal differentiation, specifically emphasizing the growth inhibitory factors, tumor suppressor genes, and other signals for growth suppression.

Heterodimers of myogenic helix-loop-helix regulatory factors and E12 bind a complex element governing myogenic induction of the avian cardiac alpha-actin promoter

Recent studies have shown that two genes regulating myogenesis (MyoD and myogenin) are coexpressed with cardiac alpha-actin during early stages of skeletal muscle development. Myogenin and MyoD are members of a family of regulatory proteins which share a helix-loop-helix (HLH) motif required for dimerization and DNA binding. Myogenin and MyoD form heterodimers with the ubiquitous HLH protein E12 which bind cis-acting DNA elements that have an E box (CANNTG) at their core. E boxes are present in the control regions of numerous muscle-specific genes, although their functional importance in regulating many of these genes has not yet been evaluated. In this report we examine the possibility that myogenin (or MyoD) directly transactivates the cardiac alpha-actin promoter. Heterodimers of myogenin and E12 (or MyoD and E12) specifically bound a restriction fragment extending from -200 to -103 relative to the start of cardiac alpha-actin transcription. Methylation interference footprints pinpointed the site of interaction to an E box immediately adjacent to a previously identified CArG box (CArG3). Site-directed mutations to the DNA-binding site revealed that either an intact E box or an intact CArG3 is required for induction of the cardiac alpha-actin promoter in myoblasts and for transactivation by myogenin in cotransfected fibroblasts. However, deletion and substitution experiments indicate that the complex E box/CArG3 element alone does not confer muscle-specific expression to a minimal promoter. These results suggest that direct and indirect pathways involving multiple cis-acting elements mediate the induction of the cardiac alpha-actin promoter by myogenin and MyoD.

Heterodimers of myogenic helix-loop-helix regulatory factors and E12 bind a complex element governing myogenic induction of the avian cardiac alpha-actin promoter

Recent studies have shown that two genes regulating myogenesis (MyoD and myogenin) are coexpressed with cardiac alpha-actin during early stages of skeletal muscle development. Myogenin and MyoD are members of a family of regulatory proteins which share a helix-loop-helix (HLH) motif required for dimerization and DNA binding. Myogenin and MyoD form heterodimers with the ubiquitous HLH protein E12 which bind cis-acting DNA elements that have an E box (CANNTG) at their core. E boxes are present in the control regions of numerous muscle-specific genes, although their functional importance in regulating many of these genes has not yet been evaluated. In this report we examine the possibility that myogenin (or MyoD) directly transactivates the cardiac alpha-actin promoter. Heterodimers of myogenin and E12 (or MyoD and E12) specifically bound a restriction fragment extending from -200 to -103 relative to the start of cardiac alpha-actin transcription. Methylation interference footprints pinpointed the site of interaction to an E box immediately adjacent to a previously identified CArG box (CArG3). Site-directed mutations to the DNA-binding site revealed that either an intact E box or an intact CArG3 is required for induction of the cardiac alpha-actin promoter in myoblasts and for transactivation by myogenin in cotransfected fibroblasts. However, deletion and substitution experiments indicate that the complex E box/CArG3 element alone does not confer muscle-specific expression to a minimal promoter. These results suggest that direct and indirect pathways involving multiple cis-acting elements mediate the induction of the cardiac alpha-actin promoter by myogenin and MyoD.

Identification of cis and trans-elements involved in the timed control of a Caulobacter flagellar gene

The genes encoding the structural components of the Caulobacter crescentus flagellum are temporally controlled and their order of expression reflects the sequence of assembly. Transcription of the operon containing the structural gene for the flagellar hook protein occurs at a defined time in the cell cycle, and information necessary for transcription is contained within a region between -81 and -120 base-pairs from the transcription start site. To identify the sequence elements that contribute to the temporal control of hook operon transcription, we constructed deletions and base changes in the 5' region and fused the mutagenized regulatory region to transcription reporter genes. We demonstrate that sequences 3' to the transcription start site do not contribute to temporal control. We confirm that upstream sequences between -81 and -120 base-pairs are necessary for temporal activation, and that transcription also requires sequences at -26 to -46 base-pairs. A specific binding activity for the region between -81 and -122 base-pairs was shown to be temporally controlled, appearing prior to the activation of hook operon transcription. This binding activity was missing from strains containing mutations in flaO and flaW, two genes near the top of the flagellar hierarchy known to be required for hook operon transcription. Thus, the hook operon upstream region contains a sequence element that responds to a temporally controlled trans-acting factor(s), and in concert with a second sequence element causes the timed activation of transcription.

Progressive inactivation of the expression of an erythroid transcriptional factor in GM- and G-CSF-dependent myeloid cell lines

The transcriptional binding protein NFE-1 (also called GF-1 and Ery-f1) is thought to play a necessary, but not sufficient, role in the regulation of differentiation-related gene expression in a subset of hematopoietic lineages (erythroid, megakaryocytic, and basophil-mast cell). In order to clarify the mechanism which underlies the lineage-specificity of the NFE-1 expression, as well as the relationship between the expression of this factor and growth factor responsiveness, we have evaluated the capacity of erythropoietin (Epo)-, granulomonocytic (GM)-colony stimulating factor (CSF)-, and granulocyte (G)-CSF-dependent subclones derived from the interleukin 3 (IL-3)-dependent cell line 32D, to express 1) NFE-1 mRNA, 2) NFE-1-related nuclear proteins, and 3) chloramphenicol acetyl transferase (CAT) activity when transfected with a CAT gene under the control of NFE-1 cognate sequences. NFE-1 mRNA was found to be expressed not only in cells with mast cell (IL-3-dependent 32D) and erythroid (Epo-dependent 32D Epo1) phenotypes, but also in cells with predominantly granulocyte/macrophage properties, such as the GM-CSF- (early myelomonocytic) and G-CSF- (myelocytic) dependent subclones of 32D. However, a gradient of expression, correlating with the lineage, the stage of differentiation, and the growth factor responsiveness of the cell lines, was found among the different subclones: Epo greater than or equal to IL-3 greater than GM-CSF greater than G-CSF. Binding experiments demonstrated NFE-1 activity in all cell lines except the G-CSF-dependent line. Function of the NFE-1 protein was assessed by the expression of the CAT gene linked to the SV40 promoter and a mutant (-175 T----C) HPFH gamma-globin promoter. High level CAT expression was seen only in the Epo1 cells although low level expression was also seen in the parent 32D. These results demonstrate that the specificity of the expression of NFE-1 for the erythroid--megakaryocytic--mast cell lineages is obtained by progressive inactivation of its expression in alternative lineages.

A novel oncofetal gene is expressed in a stage-specific manner in murine embryonic development

A novel cDNA clone obtained from a murine T-lymphoma library hybridizes to transcripts expressed in placenta and embryos (Pem) in a stage-specific manner. The Pem cDNA sequence predicts an intracellular hydrophilic protein with no significant sequence similarity to other DNA or protein sequences. Pem transcripts are abundant in 7- and 8-day mouse embryos, but decrease precipitously thereafter. On Day 9 they become abundant in placenta and yolk sac, persisting there until parturition. Although Pem transcripts are present in immortalized and tumorigenic cell lines from several different cell lineages, they are not detectable in any of 15 adult tissues tested. The expression of Pem during fetal development and its presence in immortalized and neoplastic cell lines is consistent with the properties expected of an "oncofetal" gene.

Cell proliferation inhibited by MyoD1 independently of myogenic differentiation

Cell growth and differentiation are usually mutually exclusive. Transformation of myoblasts by retroviruses containing the myc oncogene inhibits differentiation, preventing cells from withdrawing from the cell cycle. If cell-cycle withdrawal is a prerequisite for myoblast differentiation, it is probably an early event in terminal cell differentiation, but this has not yet been established. MyoD1 regulates myogenesis. It is expressed only in skeletal muscle, but can convert other cells to muscle cells. The MyoD1 protein, a nuclear phosphoprotein in part similar to the myc family of proteins, is a DNA-binding protein binding to the enhancer sequences of the muscle-specific creatine phosphokinase gene. Thus, introduction of MyoD1 into cells provides a simple approach to study the effect of induction of differentiation on cell growth. In cultured NIH 3T3 cells, inhibition of cell proliferation occurs within 18 hours, and expression of myosin starts after 72 hours. Furthermore, injection of MyoD1 into quiescent NIH 3T3 cells inhibit cell proliferation independently of induction of differentiation. Deletion of the myc-like domain in the MyoD1 gene eliminates the inhibition of DNA synthesis, but substitution of the basic domain with the analogous domain from the E12 transcription factor inhibits growth yet fails to induce differentiation. Inhibition of DNA synthesis, therefore, seems to be controlled separately from myogenic differentiation.

A bovine homolog to the human myogenic determination factor myf-5: sequence conservation and 3' processing of transcripts

A bovine cDNA library from fetal skeletal muscle myoblasts. was screened with a 274 bp probe to a conserved region of the mouse MyoD1 cDNA. One positive recombinant, designated bmyf, was found to contain a 1931 bp insert with an open reading frame encoding a predicted protein highly related to the human myogenic factor myf-5 Human and bovine factors are 96% homologous in their predicted amino acid sequences. At the nucleotide level, bmyf and myf-5 are 92% identical in the coding region and 74 and 80% homologous in their 5'- and 3'-untranslated regions, respectively. The bmyf cDNA, nevertheless, extends 475 nucleotides beyond a polyadenylation signal common to both cDNAs. Bmyf transcripts are expressed exclusively in skeletal muscle where three transcripts of 1.5, 2 and 3 kb were detected. While the 1.5 kb transcript lacks sequences 3' to the polyadenylation signal at nt 1415 in the bmyf cDNA, both the 2 and 3 kb RNAs contain these sequences suggesting that bmyf transcripts are alternatively polyadenylated. Bmyf cDNA can activate the expression of the myogenic program in C3H10T1/2 fibroblasts as assayed by stable and transient transfection experiments.

Expression of the MyoD1 muscle determination gene defines differentiation capability but not tumorigenicity of human rhabdomyosarcomas

Several human rhabdomyosarcoma cell lines, cultured primary tumor explants, and biopsies of tumor and normal skeletal muscle tissue expressed a 2.0-kilobase transcript that hybridized to the mouse muscle determination gene MyoD1. This transcript was found in tumor cell lines and primary explants that developed multinucleated myotubes but was absent in Wilms' tumors or cell lines and primary explants that developed multinucleated myotubes but was absent in Wilms' tumors or cell lines derived from other mesenchymal tumor cell types. Expression of the human homolog of MyoD1 therefore can define a tumor as a rhabdomyosarcoma. Transfection of the mouse MyoD1 gene into the human rhabdomyosarcoma cell line RD increased the ability of the tumor cells to differentiate into multinucleated myotubes and enhanced myosin heavy-chain gene expression but did not decrease tumorigenicity in nude mice.

Methylation and expression of the Myo D1 determination gene

Mouse embryo cells induced to differentiate with the demethylating agent 5-azacytidine represent an excellent model system to investigate the molecular control of development. Clonal derivatives of 10T1/2 cells that have become determined to the myogenic or adipogenic lineages can be isolated from the multipotential parental line after drug treatment. These determined derivatives can be cultured indefinitely and will differentiate into end-stage phenotypes on appropriate stimulation. A gene called Myo D1, recently isolated from such a myoblast line, will confer myogenesis when expressed in 10T1/2 or other cell types (Davis et al. 1987). The cDNA for Myo D1 contains a large number of CpG sequences and the gene is relatively methylated in 10T1/2 cells and an adipocyte derivative, but is demethylated in myogenic derivatives. Myo D1 may therefore be subject to methylation control in vitro. On the other hand, preliminary observations suggest that Myo D1 is not methylated at CCGG sites in vivo so that a de novo methylation event may have occurred in vitro. These observations may have significance in the establishment of immortal cell lines and tumours.

Mesodermal cell determination and differentiation

Many in vitro systems have been designed to study the processes governing cell determination and differentiation during development. Mammalian culture systems have been particularly helpful in elucidating the mechanisms regulating gene expression during differentiation in cells of mesodermal origin, namely, myoblasts, preadipocytes, and chondroblasts. Studies have shown that particular cis-acting sequences and trans-acting factors are important in determining tissue-specific and developmental gene expression in these systems. The role of growth factors, oncogenes, and other agents during differentiation has also been examined. Recently four putative muscle determination genes have been isolated and are being characterized. These studies have been useful in postulating models of how development proceeds in vivo and how differentiation and transformation to a neoplastic phenotype may be related.

Cell interactions and gene expression in early hematopoiesis

As part of an investigation of the mechanisms controlling gene expression during lineage commitment, we have investigated the transcriptional status of hematopoietic lineage-specific genes and the interactions of early hematopoietic progenitor cells with stromal cells of the marrow microenvironment. The results indicate that a subset of otherwise lineage-restricted genes are transcriptionally active and/or DNAse I hypersensitive (i.e., "primed" for transcription) in multipotent, interleukin 3-dependent hematopoietic cells, and that they may become inaccessible and transcriptionally silent when cells are induced to adopt a single lineage during commitment. The external influences regulating gene expression in hematopoietic cells include binding interactions with stromal cells and exposure to locally presented growth factors. These interactions are thought to be essential for hematopoietic cell development and may be dysregulated in chronic myeloid leukemia.

A regulatory hierarchy for cell specialization in yeast

The specialized sets of genes that determine different cell types in yeast are controlled by combinations of DNA-binding proteins some of which are present only in certain cell types whereas others are present in all cell types. Final differentiation requires an inductive signal that triggers both gene transcription and cell-cycle arrest. Synthesis of the proteins coded by the 'master regulatory' mating-type locus is regulated so as to generate a heterogeneous mitotic cell population containing a stem-cell lineage.

Polyomavirus genome and polyomavirus enhancer-driven gene expression during myogenesis

The mRNAs for myogenic functions are coordinately transcribed with polyomavirus (Py) early mRNA during in vitro differentiation of mouse C2 myoblast cells. Sequence analysis shows that the A domain of the Py enhancer includes an E1A-like consensus sequence that is also found in the 5' upstream region of two genes expressed during myoblast differentiation: alpha-actin and myosin light chain. Therefore, the coordinate expression of such genes with Py early mRNA may be activated by a common cellular regulatory factor. In the present work, we report that C2 cells surviving Py infection are unable to differentiate and do not express alpha-actin and myosin light-chain mRNAs. Hybrids between such Py-resistant myoblast cells and the parental cells exhibited dominance of the permissibility to Py growth and of the expression of myogenic mRNAs. In C2 cells transiently transfected with a chimeric plasmid (pSVPy12CAT) harboring the bacterial chloramphenicol acetyltransferase (CAT) gene driven by the Py enhancer-promoter region, the CAT gene was expressed irrespective of their stage of differentiation. Moreover, undifferentiated stably transfected cells expressing the CAT gene restricted viral growth. Py-resistant C2 myoblasts transiently transfected with pSVPy12CAT also expressed the CAT gene driven by the Py enhancer. This contradictory finding is similar to results previously obtained by other investigators with cloned genes specific for myogenic functions, and it may be explained by a structural difference between the pSVPy12CAT and the Py genomic organizations in which the viral enhancer operates.

Expression of the MyoD1 muscle determination gene defines differentiation capability but not tumorigenicity of human rhabdomyosarcomas

Several human rhabdomyosarcoma cell lines, cultured primary tumor explants, and biopsies of tumor and normal skeletal muscle tissue expressed a 2.0-kilobase transcript that hybridized to the mouse muscle determination gene MyoD1. This transcript was found in tumor cell lines and primary explants that developed multinucleated myotubes but was absent in Wilms' tumors or cell lines and primary explants that developed multinucleated myotubes but was absent in Wilms' tumors or cell lines derived from other mesenchymal tumor cell types. Expression of the human homolog of MyoD1 therefore can define a tumor as a rhabdomyosarcoma. Transfection of the mouse MyoD1 gene into the human rhabdomyosarcoma cell line RD increased the ability of the tumor cells to differentiate into multinucleated myotubes and enhanced myosin heavy-chain gene expression but did not decrease tumorigenicity in nude mice.

The ski oncogene induces muscle differentiation in quail embryo cells

Quail embryo cells (QECs) are primary cultures of fibroblastoid cells that become myogenic after infection with avian retroviruses expressing the ski oncogene (SKVs). ski also stimulates proliferation of QECs and induces morphological transformation and anchorage-independent growth. Paradoxically, ski-transformed clones picked from soft agar are capable of muscle differentiation. ski-induced differentiation is essentially indistinguishable from that of uninfected myoblasts in culture with regard to muscle-specific gene expression, commitment, and inhibition by growth factors or other oncogenes. However, ski-induced myoblasts have less stringent requirements for growth and differentiation. Uninfected QECs cannot differentiate and do not express an early marker for the myogenic lineage. Clonal analysis indicates that at least 40% of QECs are converted by ski to differentiating myoblasts. The data suggest that ski induces either the capacity for differentiation in an "incompetent" muscle precursor or the determination of nonmyogenic cells to the myogenic lineage.

How fixed is the differentiated state? Lessons from heterokaryons

The differentiated state is highly stable in vivo. Yet, in response to nuclear transplantation, tissue regeneration or cell fusion, the nuclei of differentiated cells exhibit a remarkable capacity to change. I review here the utility of heterokaryons, multinucleated cell hybrids, in elucidating the mechanisms that establish and maintain the differentiated state and yet allow such plasticity.

On the relationships between the rate of cytoskeletal stable assemblies turnover, stability of the differentiated state, development and aging

There is a general consensus that biological specificity is a structure-derived property. If a living system is going to maintain its structure and function then the newly synthesized molecules should replace the faulty ones at the correct time and in the correct places so that the previously established cellular topology will be preserved. In addition, pre-existing spatial determinants which will direct the asymmetrical assembly of the newly synthesized molecules should be available. Therefore, regulation of turnover of cellular architecture represents an essential feature of living systems. In considering the underlying causes of cellular senescence it seemed reasonable to focus on the relationship between development of a stable phenotype and the turnover of cellular and extracellular stable assemblies, currently thought to be involved in maintaining the stability of the differentiated state. In recent years evidence has accumulated suggesting a reciprocal relationship between cytoarchitecture turnover rate and achievement of a stable structure. The lack of a feedback control on the turnover of cellular stable assemblies and/or a low turnover rate of cytoarchitecture components would mean that they will be subjected to damaging processes such as oxidation, cross-linking, aminoacid racemization or non-enzymatic browning which are known to occur in other long-lived proteins. The consequence would be the generation, with advancing age, of faulty cellular structures which, in turn, would alter the deposition of newly synthesized molecules. This process may lead to a progressive breakdown in cellular and extracellular stable structures. The process of directed assembly seems to be general for biological systems displaying history-dependent development. We believe that it is this strategy which imposes severe limitations on presegregated spatial determinants turnover rates and, therefore plays a major role in initiating the aging process. We also suggest that species-specific life-span might be determined by the species-specific regulatory networks which governs the cell-specific cytoarchitecture damaging rate. Moreover, aging appears to be an intrinsic feature of biological systems displaying history-dependent development and should be absent in systems displaying history-independent life-cycles, such as bacteria, some species of protozoa, and certain transformed cell lines. An important feature of protein turnover is that this process requires metabolic energy. Therefore, we can expect that structure preservation strategy is a part of a more general energy-saving strategy, a view previously expressed by T.B.L. Kirkwood (Nature, Lond., 1977, 270, 301-304).

The domain model for eukaryotic DNA organization. 2: A molecular basis for constraints on development and evolution

A model for eukaryotic DNA organization has been proposed in which DNA regulatory processes depend on multiple site-specific DNA-nuclear matrix interactions throughout a DNA domain. In this model gene regulation depends on combinations of a few control factors in a cell to activate cell type-specific genes. This model suggests simple molecular mechanisms for organismal development which can account for sequential activation of appropriate groups of genes throughout development and for specific constraints on developmental pathways. Additionally, these suggested developmental pathways are consistent with mechanisms of evolution in which gradualism and punctuated equilibrium are not exclusive of one another and are interrelated mechanisms of evolution that are both induced by specific chromosomal mutations.

Activity-dependent regulation of gene expression in muscle and neuronal cells

In both the central and the peripheral nervous systems, impulse activity regulates the expression of a vast number of genes that code for synaptic proteins, including neuropeptides, enzymes involved in neurotransmitter biosynthesis and degradation, and membrane receptors. In recent years, the mechanisms involved in these regulations became amenable to investigation by the methods of recombinant DNA technology. The first part of this review focuses on the activity-dependent control of nicotinic acetylcholine receptor biosynthesis in vertebrate muscle, a model case for the regulation of synaptic protein biosynthesis at the postsynaptic level. The second part summarizes some examples of neuronal proteins whose biosynthesis is under the control of transsynaptic impulse activity. The first, second, and third intracellular messengers involved in membrane-to-gene signaling are discussed, as are possible posttranscriptional control mechanisms. Finally, models are proposed for a role of neuronal activity in the genesis and stabilization of the synapse.