Jean-François Naud scite author profile

Specific heterodimerization plays a crucial role in the regulation of the biology of the cell. For example, the specific heterodimerization between the b-HLH-LZ transcription factors c-Myc and Max is a prerequisite for c-Myc transcriptional activity that leads to cell growth, proliferation and tumorigenesis. On the other hand, the Mad proteins can compete with c-Myc for Max. The Mad/Max heterodimer antagonizes the effect of the c-Myc/Max heterodimer. In this contribution, we have focused on the specific heterodimerization between the b-HLH-LZ domains of c-Myc and Max using CD and NMR. While the c-Myc and Max b-HLH-LZ domains are found to preferentially form a heterodimer; we demonstrate for the first time that a significant population of the Max homodimeric b-HLH-LZ can also form and hence interferes significantly with the specific heterodimerization. This indicates that the Max/Max homodimer can also interfere with c-Myc/Max functions, therefore adding to the complexity of the regulation of transcription by the Myc/Max/Mad network. The demonstration of the existence of the homodimeric population was made possible by the application of numerical routines that enable the simulation of composite spectroscopic signal (e.g. CD) as a function of temperature and total concentration of proteins. From a systems biology perspective, our routines may be of general interest as they offer the opportunity to treat many competing equilibriums in order to predict the probability of existence of protein complexes.

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The Arf tumor suppressor protein inhibits Miz1 to suppress cell adhesion and induce apoptosis

Herkert

Dwertmann

Herold

et al. 2010

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Thermodynamics of b-HLH-LZ Protein Binding to DNA: The Energetic Importance of Protein−DNA Contacts in Site-Specific E-Box Recognition by the Complete Gene Product of the Max p21 Transcription Factor

et al. 2007

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The Myc/Mad/Max network of dimeric basic region-helix-loop-helix-leucine zipper (b-HLH-LZ) transcription factors bind to enhancer box sequences (E-box) in the promotors of a large set of genes that control cell metabolism, proliferation, and differentiation. Max (Myc-associated factor X) is the obligate heterodimerization partner of Myc and Mad proteins. On the other hand, Max is the only member of the family capable of forming a stable homodimer. As part of the transcriptional regulation mechanism, Myc/Max and Mad/Max heterodimers and Max homodimers are thought to compete for binding to the E-box target sequences. E-box recognition is structurally supported by the b-HLH-LZ structural motif, which also promotes dimerization. However, the actual dimerization and heterodimerization constants of the complete gene products and their affinities for E-box sequences are not known. Also, the detailed thermodynamic characterization of DNA binding by these transcription factors has not been done yet. Such knowledge is necessary for complete understanding of the transcriptional regulation carried out by the Myc/Mad/Max network. Here, we report the first in-depth thermodynamic characterization of the stability and specific DNA binding of a full length gene product of the Myc/Mad/Max family, namely, Max protein isoform p21 (Max p21). Using calorimetric methods (DSC and ITC) we have determined the dimerization constant of Max p21 in the low micromolar range, and the Max p21/E-box complex dissociation constant in the low nanomolar range at 37 degrees C. The association is driven by a large exothermic effect, which is partly compensated by entropic factors. The energetic contribution to binding affinity of seven highly conserved residues that contact the DNA was probed by X-to-Ala mutagenesis. The results demonstrate that high binding affinity critically relies on the side chain of Arg 26. Furthermore, the mutational analysis points to the important role of the persistent helical turn that comprises this residue at the junction of the basic region and helix H1. Altogether, the study supports the idea that Max p21 can bind E-box sequences in vivo and likely participates directly in the regulation of transcription as homodimer.

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