A natural hepatocyte growth factor/scatter factor autocrine loop in myoblast cells and the effect of the constitutive Met kinase activation on myogenic differentiation.

As a rule, hepatocyte growth factor/scatter factor (HGF/SF) is produced by mesenchymal cells, while its receptor, the tyrosine kinase encoded by the met proto-oncogene, is expressed by the neighboring epithelial cells in a canonical paracrine fashion. In the present work we show that both HGF/SF and met are coexpressed by undifferentiated C2 mouse myoblasts. In growing cells, the autocrine loop is active as the receptor exhibits a constitutive phosphorylation on tyrosine that can be abrogated by exogenously added anti-HGF/SF neutralizing antibodies. The transcription of HGF/SF and met genes is downregulated when myoblasts stop proliferating and differentiate. The coexpression of HGF/SF and met genes is not exclusive to C2 cells since it has been assessed also in other myogenic cell lines and in mouse primary satellite cells, suggesting that HGF/SF could play a role in muscle development through an autocrine way. To analyze the biological effects of HGF/SF receptor activation, we stably expressed the constitutively activated receptor catalytic domain (p65(tpr-met)) in C2 cells. This active kinase determined profound changes in cell shape and inhibited myogenesis at both morphological and biochemical levels. Notably, a complete absence of muscle regulatory markers such as MyoD and myogenin was observed in p65(tpr-met) highly expressing C2 clones. We also studied the effects of the ectopic expression of human isoforms of met receptor (h-met) and of HGF/SF (h-HGF/SF) in stable transfected C2 cells. Single constitutive expression of h-met or h-HGF/SF does not alter substantially the growth and differentiation properties of the myoblast cells, probably because of a species-specific ligand-receptor interaction. A C2 clone expressing simultaneously both h-met and h-HGF/SF is able to grow in soft agar and shows a decrease in myogenic potential comparable to that promoted by p65(tpr-met) kinase. These data indicate that a met kinase signal released from differentiation-dependent control provides a negative stimulus for the onset of myogenic differentiation.

The activity of differentiation factors induces apoptosis in polyomavirus large T-expressing myoblasts.

It is commonly accepted that pathways that regulate proliferation/differentiation processes, if altered in their normal interplay, can lead to the induction of programmed cell death. In a previous work we reported that Polyoma virus Large Tumor antigen (PyLT) interferes with in vitro terminal differentiation of skeletal myoblasts by binding and inactivating the retinoblastoma antioncogene product. This inhibition occurs after the activation of some early steps of the myogenic program. In the present work we report that myoblasts expressing wild-type PyLT, when subjected to differentiation stimuli, undergo cell death and that this cell death can be defined as apoptosis. Apoptosis in PyLT-expressing myoblasts starts after growth factors removal, is promoted by cell confluence, and is temporally correlated with the expression of early markers of myogenic differentiation. The block of the initial events of myogenesis by transforming growth factor beta or basic fibroblast growth factor prevents PyLT-induced apoptosis, while the acceleration of this process by the overexpression of the muscle-regulatory factor MyoD further increases cell death in this system. MyoD can induce PyLT-expressing myoblasts to accumulate RB, p21, and muscle- specific genes but is unable to induce G0(0) arrest. Several markers of different phases of the cell cycle, such as cyclin A, cdk-2, and cdc-2, fail to be down-regulated, indicating the occurrence of cell cycle progression. It has been frequently suggested that apoptosis can result from an unbalanced cell cycle progression in the presence of a contrasting signal, such as growth factor deprivation. Our data involve differentiation pathways, as a further contrasting signal, in the generation of this conflict during myoblast cell apoptosis.

Inhibition of in vitro myogenic differentiation by a polyomavirus early function.

In the present work we report on the role of a polyomavirus (Py) early function in interfering with both morphological and biochemical differentiation of the myogenic C2 cell line. The analysis of cell clones stably transfected with a plasmid carrying an ORI- Py genome showed that in the presence of the whole viral early region myogenesis is blocked and a transformed phenotype is evident. By using a plasmid that only encodes large-T function, the involvement of this individual early viral gene product was determined. Inhibition of myogenic differentiation by Py large T is proportional to the level of its expression. This inhibition does not appear to require alteration of cell growth properties. The analysis of muscle-specific functions expressed at different steps in the myogenic pathway showed that Py large T blocks the expression of terminal differentiation markers without altering the expression of the regulatory gene MyoD.

[Multidisciplinary approach to diagnosis and prevention of musculoskeletal diseases in work environment. Long term follow- up]. / Approccio multidisciplinare per la diagnosi e prevenzione delle malattie muscolo-scheletriche in ambiente di lavoro. Controllo a distanza.

To have the right value of the possible causes responsible of muscles-skeleton disorders, and to have a right therapeutic measures, the Authors have get ready an holistic method, that value not only the damage's point, but also research in the others body-districts, named Peripheral Receptors, the causes responsible of pathologic manifestation. The methods is used on 61 VDU and it consists in: clinical rachis exam (like EPM methods), postural, odontological, oculistic, podiatric and psychologic visits. The study have permitted to underlines muscles-skeletons disorders precociously, not only in symptomatic subjects, but also in those asymptomatic, so it is an important prevention's instrument, diagnostic framing and medico-legal of studied pathologies.

Synthesis of a new zinc finger peptide; comparison of its 'code' deduced and 'CASTing' derived binding sites.

Using two synthetic oligonucleotides, we have constructed a new gene containing three zinc finger motifs of the Cys2-His2 type. We named this artificial gene 'Mago'. The Mago nucleotide triplets encoding the amino acid positions, described to be crucial for DNA binding specificity, have been chosen on the basis of the proposed recognition 'code' that relates the zinc finger's primary structure to the DNA binding target. Here we demonstrate that Mago protein specifically binds the 'code' DNA target, with a dissociation constant (Kd) comparable to the Kd of the well known Zif268 protein with its binding site. Moreover, we show that the deduced Mago 'code' and the 'experimental' selected DNA binding sites are almost identical, differing only in two nucleotides at the side positions.

Poly(ADP-ribosyl)ation is implicated in the G0-G1 transition of resting cells.

Poly(ADP-ribosyl)ation, catalysed by a family of poly(ADP-ribose) polymerases (PARPs), plays an important role in a large variety of physiological processes, including cell proliferation, but its role in cell cycle progression is not yet completely defined. As reported here, the examination of early times following serum stimulation of quiescent fibroblasts suggests that poly(ADP-ribosyl)ation is necessary for the transition from the G0 phase to the G1 phase. We show that PARP activity is involved in this step through the regulation of immediate-early response genes, such as c-Fos and c-Myc. This is supported by the finding that exogenous Myc expression substantially restores cell cycle reactivation in the absence of polymer synthesis. Furthermore, using RNA interference, we show that PARP-1 is the PARP family member playing the most prominent role in the upregulation of c-Fos and c-Myc during G0-G1 transition. We report that even in lectin-stimulated peripheral blood mononucleated cells, the inhibition of PARP activity interferes with the upregulation of immediate-early genes and delays the induction of proliferation, suggesting a general role for PARP-1 in linking growth factor signaling with cell cycle entry.

Inhibition of in vitro muscle differentiation by the immortalizing oncogene py LT-ag.

The interference of Polyomavirus (Py) early functions with in vitro myogenic differentiation is the object of this study. Single cell analysis of C2 myogenic Py infected cells showed a mutual exclusion between Py early functions and muscle gene expression. The morphological and biochemical analysis of clones obtained from C2 cells stably transfected with a plasmid carrying an ORI- Py genome, showed that myogenesis is blocked and cells display the transformed phenotype. By using plasmids separately encoding Middle T or Large T functions, the involvement of individual early viral gene products was determined. Py Middle T alone does not inhibit myotube formation even though cells are morphologically transformed. Myogenic differentiation, on the other hand, is inhibited by Py Large T. This inhibition, which is proportional to the level of Py Large T expression, does not entail to require alteration of cell growth properties and acts by blocking the expression of myogenin and terminal differentiation markers without altering the expression of the regulatory gene MyoD.

p53-independent apoptosis induced by muscle differentiation stimuli in polyomavirus large T-expressing myoblasts.

Abnormal proliferation signals, driven by cellular or viral oncogenes, can result in the induction of apoptosis under sub-optimal cell growth conditions. The tumor suppressor p53 plays a central role in mediating oncogene-induced apoptosis, therefore transformed cells lacking p53 are generally resistant to apoptosis-promoting treatments. In a previous work we have reported that the expression of polyomavirus large T antigen causes apoptosis in differentiating myoblasts and that this phenomenon is dependent on the onset of muscle differentiation in the absence of a correct cell cycle arrest. Here we report that polyomavirus large T increases the levels and activity of p53, but these alterations are not involved in the apoptotic mechanism. Apoptosis in polyomavirus large T-expressing myoblasts is not prevented by the expression of a p53 dominant-negative mutant nor it is increased by p53 over-expression. Moreover, forced differentiation induced through the over-expression of the muscle regulatory factor MyoD, leads to apoptosis without altering p53 function and, more significantly, even in a p53-null background. Our results indicate that apoptosis induced by the activation of muscle differentiation pathways in oncogene-expressing cells can occur in a p53-independent manner.

Double-stranded internucleosomal cleavage of apoptotic DNA is dependent on the degree of differentiation in muscle cells.

Apoptotic cell death has been correlated to DNA fragmentation into discrete segments corresponding to the length of nucleosomal protected fragments of 180-200 base pairs or multiples of it. This DNA degradation has been ascribed to endonuclease activity that cleaves internucleosomally, thus giving rise to a ladder distribution upon electrophoretic migration. This strict correlation was, however, shown to have notable exceptions, since in some cases only single strand cleavage in the internucleosomal DNA regions has been observed (Tomei, D. L., Shapiro, P. J., and Cope, O. F. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 853-857). In the present work we show that mouse muscle cells, able to differentiate in vitro, if subjected to apoptosis present no DNA degradation into ladder form unless differentiation is previously induced. Furthermore, C3H/10T1/2 fibroblast cells, known to undergo apoptosis without DNA ladder formation, if converted to a myogenic program by MyoD expression, display internucleosomal DNA degradation upon induction of differentiation.

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.

Mutations in the VP1 coding region of polyomavirus determine differentiating stage specificity.

Polyomavirus mutants capable of replicating in undifferentiated murine C2 myoblasts were selected and characterized. These mutants grow normally in 3T6 mouse fibroblast cells, and they do not complement the wild-type virus in coinfection experiments of C2 myoblasts. Of 12 isolates, 10 possess duplications of the regulatory region including the enhancer A domain. On the bases of the regulatory region structure and the presence and length of the enhancer duplication, the mutant viruses could be grouped into three classes. One mutant class (e.g., PyMB3) possesses an enhancer duplication of 91 bp identical to that of a previously characterized polyomavirus mutant, PyNB11/1. We have demonstrated that this enhancer duplication gives rise at its junction to a novel recognition motif for the transcriptional factor NF-1 (M. Caruso, C. Iacobini, C. Passananti, A. Felsani, and P. Amati, EMBO J. 9:947-955, 1990). The regulatory region PyMB3 virus recombined in a wild-type genome context maintains the mutant phenotype. The other two types of mutants, one with a 30-bp enhancer duplication (e.g., PyMB40) and one with a wild-type enhancer structure (e.g., PyMB27), possess two similar but distinct 6-bp deletions in the same region of the VP1 coding gene. In both cases, the ability to replicate in undifferentiated C2 myoblasts is strictly correlated to the mutation in the VP1 coding region.

The problem of subclinical localised paroxysmal rhythmic discharges (psychomotor variant discharges). Report of two cases.

Two cases are reported of patients whose EEGs showed localised rhythmic seizure activity in the midtemporal regions of one or both hemispheres, unaccompanied by any clinical symptoms: the patients' histories differed: one was of classic migraine and the other complex partial epilepsy. The frequency and morphology of the paroxysmal anomalies was identical in the waking state and in sleep. The nosographic classification of the phenomenon is discussed with reference to Gibbs' reports regarding the "psychomotor variant type of seizure discharge", to the work of Lipman and Hughes on "rhythmic mid-temporal discharge" and to that of Westmoreland and Klass on the "subclinical rhythmic EEG discharge of adults". But in contrast to the last phenomenon there were no signs pointing to a diffuse cerebrovascular disease. Reports of such a pattern are rare in the European literature and nonexistent in the Italian literature, facts which make an ordinary interpretation of the phenomenon difficult.

Polyomavirus large T antigen induces alterations in cytoplasmic signalling pathways involving Shc activation.

It has been extensively demonstrated that growth factors play a key role in the regulation of proliferation. Several lines of evidence support the hypothesis that for the induction of cell cycle progression in the absence of exogenous growth factors, oncogenes must either induce autocrine growth factor secretion or, alternatively, activate their receptors or their receptor substrates. Cells expressing polyomavirus large T antigen (PyLT) display reduced growth factor requirements, but the mechanisms underlying this phenomenon have yet to be explored. We conducted tests to see whether the reduction in growth factor requirements induced by PyLT was related to alterations of growth factor-dependent signals. To this end, we analyzed the phosphorylation status of a universal tyrosine kinase substrate, the transforming Shc adapter protein, in fibroblasts expressing the viral oncogene. We report that the level of Shc phosphorylation does not decrease in PyLT-expressing fibroblasts after growth factor withdrawal and that this PyLT-mediated effect does not require interaction with protein encoded by the retinoblastoma susceptibility gene. We also found that the chronic activation of the adapter protein is correlated with the binding of Shc to Grb-2 and with defects in the downregulation of mitogen-activated protein kinases. In fibroblasts expressing the nuclear oncoprotein, we also observed the formation of a PyLT-Shc complex that might be involved in constitutive phosphorylation of the adapter protein. Viewed comprehensively, these results suggest that the cell cycle progression induced by PyLT may depend not only on the direct inactivation of nuclear antioncogene products but also on the indirect induction, through the alteration of cytoplasmic pathways, of growth factor-dependent nuclear signals.

Retinoblastoma antioncogene is involved in the inhibition of myogenesis by polyomavirus large T antigen.

The expression of polyomavirus large T antigen in stably transfected C2 myoblast cells inhibits terminal differentiation without inducing a transformed phenotype. In the present work, we report on the lifting of this inhibition by a mutation that prevents polyomavirus large T antigen from binding to the product of the retinoblastoma susceptibility gene (p105 RB). In contrast with cells containing wild-type large T, those with the Rb binding site mutant large T showed the same up-regulation of myosine heavy chain and myogenin mRNA expression as control cells. Furthermore, we correlate the cell cycle alteration induced by polyomavirus large T antigen expression with the inability of the cells to undergo terminal differentiation.

Selection of mouse neuroblastoma cell-specific polyoma virus mutants with stage differentiative advantages of replication.

Two mouse neuroblastoma cell lines were analyzed for their permissivity for polyoma virus growth. One (N18) is fully permissive for polyoma replication, the other (41A3) shows limited permissivity and the viral genome persists, without noticeable cell death. Virus persistence does not seem to alter the cells' ability to differentiate in vitro and leads to selection of viral mutants altered in the untranscribed regulatory region of the genome. The mutant types obtained appear to be related to the degree of host cell differentiation. Nucleotide sequence analysis of the restriction fragment covering the regulatory region shows that duplications are present in all mutants, while deletions in the non-duplicated segment are only present in mutants selected from less differentiated cells. These alterations involve both domains of the regulatory region that are considered to be essential for DNA replication and for enhancer activity. Mixed infections with polyoma wild type show that the selected mutants have cis-advantage in replication in neuroblastoma cells and not in 3T6 cells. Mutants carrying the deletion in the non-duplicated segment of the enhancer show a selective advantage in replication over the undeleted one in mixed infection. This advantage is much stronger in neuroblastoma cells in suspension (less-differentiated stage) than in monolayer cells (more-differentiated stage). An interpretation of the overall structure of the regulatory enhancer region, based on the observed differences between the mutants selected at different stages of differentiation in neuroblastoma and previously described mutants selected in undifferentiated cells, is discussed.