Sergio Pistoi scite author profile

In vivo, the steady-state level of c-myc mRNA is mainly controlled by posttranscriptional mechanisms. Using a panel of transgenic mice in which various versions of the human c-myc proto-oncogene were under the control of major histocompatibility complex H-2K b class I regulatory sequences, we have shown that the 5 and the 3 noncoding sequences are dispensable for obtaining a regulated expression of the transgene in adult quiescent tissues, at the start of liver regeneration, and after inhibition of protein synthesis. These results indicated that the coding sequences were sufficient to ensure a regulated c-myc expression. In the present study, we have pursued this analysis with transgenes containing one or the other of the two c-myc coding exons either alone or in association with the c-myc 3 untranslated region. We demonstrate that each of the exons contains determinants which control c-myc mRNA expression. Moreover, we show that in the liver, c-myc exon 2 sequences are able to down-regulate an otherwise stable H-2K mRNA when embedded within it and to induce its transient accumulation after cycloheximide treatment and soon after liver ablation. Finally, the use of transgenes with different coding capacities has allowed us to postulate that the primary mRNA sequence itself and not c-Myc peptides is an important component of c-myc posttranscriptional regulation.In recent years, it has been realized that the rates of RNA decay in the nucleus and in the cytoplasm are important in determining the level of expression of a gene (reviewed in reference 5). In eukaryotic cells, the range of mRNA stability can vary over several orders of magnitude, and numerous studies have indicated that several mRNAs contain within them the information necessary to determine their stability. Transiently expressed genes such as those encoding proto-oncogenes and growth factors have far shorter half-lives than others, such as those encoding ␤-globin or albumin (15,32). The mechanisms of differential degradation are an attractive problem which covers several distinct aspects, such as analysis of the structural features of mRNA that determine its susceptibility to decay, identification of the locations of the destabilizing determinants, determination of the trans-acting factors with which they interact, and discovery of the physiological signals which alter rates of mRNA decay (reviewed in reference 30).

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Exon 2-Mediated c-mycmRNA Decay In Vivo Is Independent of Its Translation

Pistoi

Roland

Babinet

et al. 1996

Molecular and Cellular Biology

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We have previously shown that the steady-state level of c-myc mRNA in vivo is primarily controlled by posttranscriptional regulatory mechanisms. To identify the sequences involved in this process, we constructed a series of H-2/myc transgenic lines in which various regions of the human c-MYC gene were placed under the control of the quasi-ubiquitous H-2K class I regulatory sequences. We demonstrated that the presence of one of the two coding exons, exon 2 or exon 3, is sufficient to confer a level of expression of transgene mRNA similar to that of endogenous c-myc in various adult tissues as well as after partial hepatectomy or after protein synthesis inhibition. We now focus on the molecular mechanisms involved in modulation of expression of mRNAs containing c-myc exon 2 sequences, with special emphasis on the coupling between translation and c-myc mRNA turnover. We have undertaken an analysis of expression, both at the mRNA level and at the protein level, of new transgenic constructs in which the translation is impaired either by disruption of the initiation codon or by addition of stop codons upstream of exon 2. Our results show that the translation of c-myc exon 2 is not required for regulated expression of the transgene in the different situations analyzed, and therefore they indicate that the mRNA destabilizing function of exon 2 is independent of translation by ribosomes. Our investigations also reveal that, in the thymus, some H-2/myc transgenes express high levels of mRNA but low levels of protein. Besides the fact that these results suggest the existence of tissue-specific mechanisms that control c-myc translatability in vivo, they also bring another indication of the uncoupling of c-myc mRNA translation and degradation.

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Prometheus' myth revisited: transgenic mice as a powerful tool to study liver regeneration

Pistoi

Morello

1996

FASEB j.

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In this review, we present examples of the contribution of transgenic mice to our knowledge concerning the type of cells that are able to repopulate a damaged liver and information on the factors and mechanisms involved in postnatal liver growth and regeneration. The transgenic technology offers the opportunity to evaluate the physiological consequences of perturbating expression of a given gene in vivo. It has provided insights into the concerted action of extracellular (HGF/SF, TGF-alpha, EGF, TGF-beta) and intracellular factors (c-myc, c-fos, c-jun, p53, c-met, and others) in liver regeneration. Transgenic mice can also contribute to the dissection of the molecular mechanisms responsible for the regulated expression of these factors, both at the transcriptional and the posttranscriptional level. An illustration of such a strategy is given by the study of the sequences involved in the posttranscriptional regulation of the c-myc proto-oncogene. The recent improvement of gene targeting, in which endogenous genes are inactivated by homologous recombination, represents a further step toward the study of the function of a particular gene. Inactivation of most of the factors described in this review has been undertaken. However, further studies of their role in liver growth control are impeded by the fact that the corresponding knockout mice die prematurely. This problem could be overcome by the advent of new techniques, which will be briefly presented, aimed at turning genes on and off at will and in a tissue-specific manner.

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Structure and inducible regulation of the human MET promoter.

Gambarotta¹,

Pistoi²,

Giordano³

et al. 1994

Journal of Biological Chemistry

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Sergio Pistoi

Both Coding Exons Of The c-myc Gene Contribute to Its Posttranscriptional Regulation in the Quiescent Liver and Regenerating Liver and after Protein Synthesis Inhibition

Exon 2-Mediated c-mycmRNA Decay In Vivo Is Independent of Its Translation

Prometheus' myth revisited: transgenic mice as a powerful tool to study liver regeneration

Structure and inducible regulation of the human MET promoter.

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