Michael Furrer scite author profile

Myc proteins are powerful proto-oncoproteins and important promoters of growth and proliferation during normal development. They are thought to exercise their effects upon binding to their partner protein Max, and their activities are largely antagonized by complexes of Max with Mnt or an Mxd family protein. Although the biological functions of Myc, Mxd and Mnt have been intensively studied, comparatively little is known about the in vivo role of Max. Here we generate Max loss-of-function and reduction-of-function mutations in Drosophila melanogaster to address the contribution of Max to Myc-dependent growth control. We find that many biological activities of Myc do not, or only partly, require the association with Max--for example, the control of endoreplication and cell competition-and that a Myc mutant that does not interact with Max retains substantial biological activity. We further show that Myc can control RNA polymerase III independently of Max, which explains some of Myc's observed biological activities. These studies show the ability of Myc to function independently of Max in vivo and thus change the current model of Max network function.

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Whole-Genome Analysis Reveals a Strong Positional Bias of Conserved dMyc-Dependent E-Boxes

Hulf¹,

Bellosta²,

Furrer³

et al. 2005

Molecular and Cellular Biology

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Myc is a transcription factor with diverse biological effects ranging from the control of cellular proliferation and growth to the induction of apoptosis. Here we present a comprehensive analysis of the transcriptional targets of the sole Myc ortholog in Drosophila melanogaster, dMyc. We show that the genes that are downregulated in response to dmyc inhibition are largely identical to those that are up-regulated after dMyc overexpression and that many of them play a role in growth control. The promoter regions of these targets are characterized by the presence of the E-box sequence CACGTG, a known dMyc binding site. Surprisingly, a large subgroup of (functionally related) dMyc targets contains a single E-box located within the first 100 nucleotides after the transcription start site. The relevance of this E-box and its position was confirmed by a mutational analysis of a selected dMyc target and by the observation of its evolutionary conservation in a different Drosophila species, Drosophila pseudoobscura. These observations raise the possibility that a subset of Myc targets share a distinct regulatory mechanism.

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PAF1 complex component Leo1 helps recruit Drosophila Myc to promoters

Gerlach

Furrer

Gallant

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The Myc oncogene is a transcription factor with a powerful grip on cellular growth and proliferation. The physical interaction of Myc with the E-box DNA motif has been extensively characterized, but it is less clear whether this sequence-specific interaction is sufficient for Myc's binding to its transcriptional targets. Here we identify the PAF1 complex, and specifically its component Leo1, as a factor that helps recruit Myc to target genes. Since the PAF1 complex is typically associated with active genes, this interaction with Leo1 contributes to Myc targeting to open promoters.

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Drosophila Myc Interacts with Host Cell Factor (dHCF) to Activate Transcription and Control Growth

Furrer

Balbi²,

Albarca-Aguilera³

et al. 2010

Journal of Biological Chemistry

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The Myc proto-oncoproteins are transcription factors that recognize numerous target genes through hexameric DNA sequences called E-boxes. The mechanism by which they then activate the expression of these targets is still under debate. Here, we use an RNAi screen in Drosophila S2 cells to identify Drosophila host cell factor (dHCF) as a novel co-factor for Myc that is functionally required for the activation of a Myc-dependent reporter construct. dHCF is also essential for the full activation of endogenous Myc target genes in S2 cells, and for the ability of Myc to promote growth in vivo. Myc and dHCF physically interact, and they colocalize on common target genes. Furthermore, down-regulation of dHCF-associated histone acetyltransferase and histone methyltransferase complexes in vivo interferes with the Myc biological activities. We therefore propose that dHCF recruits such chromatin-modifying complexes and thereby contributes to the expression of Myc targets and hence to the execution of Myc biological activities.Myc genes were identified for their powerful transforming capabilities in vertebrate systems and later shown to be essential for normal development (reviewed in Refs. 1, 2). The molecular functions of Myc are evolutionarily conserved, and the single Myc homolog in Drosophila melanogaster (called Myc when referring to the protein, and diminutive or dm when referring to alleles) can substitute for vertebrate Myc (3) and vice versa (Ref. 4, for a recent review see Ref. 5). Drosophila Myc prominently controls cellular growth; null mutations prevent organismal growth and lead to death during early larval stages (6), whereas hypomorphic dm mutations prolong development and result in small adult flies, made up of smaller than wild-type cells (7). Conversely, overexpression of Myc results in bigger cells, but also stimulates apoptosis (7,8). These effects of Myc are mediated by the transcriptional regulation of a large number of target genes (9, 10), including genes transcribed by RNA polymerases I (11) and III (12).

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Michael Furrer

Max-independent functions of Myc in Drosophila melanogaster

Whole-Genome Analysis Reveals a Strong Positional Bias of Conserved dMyc-Dependent E-Boxes

PAF1 complex component Leo1 helps recruit Drosophila Myc to promoters

Drosophila Myc Interacts with Host Cell Factor (dHCF) to Activate Transcription and Control Growth

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