Biophysical and Structural Methods to Study the bHLHZip Region of Human c-MYC.

The C-terminal region of the c-MYC transcription factor consists of approximately 100 amino acids that in its native state does not adopt a stable structure. When this region binds to the obligatory partner MAX via a coupled folding-and-binding mechanism, it forms a basic-helix-loop-helix-leucine zipper (bHLHZip) heterodimeric complex. The C-terminal region of MYC is the target for numerous drug discovery programs for direct MYC inhibition via blocking the dimerization event and/or binding to DNA, and a proper understanding of the partially folded, dynamic nature of the heterodimeric complex is essential to these efforts. The bHLHZip motif also drives protein-protein interactions with cofactors that are crucial for both transcriptional repression and activation of MYC target genes. Targeting these interactions could potentially provide a means of developing alternative approaches to halt MYC functions; however, the molecular mechanism of these regulatory interactions is poorly understood. Herein we provide methods to produce high-quality human c-MYC C-terminal by itself and in complex MAX, and how to study them using Nuclear Magnetic Resonance spectroscopy and X-ray crystallography. Our protein expression and purification protocols have already been used to study interactions with cofactors.

Methods of Expression, Purification, and Preparation of the c-Myc b-HLH-LZ for Its Biophysical Characterization.

The b-HLH-LZ domain of c-Myc is a key target for the development of cancer therapies by blunting its binding to DNA with cell penetrant b-HLH-LZs and/or by stabilizing it into a state that cannot recognize Max to activate and amplify transcription of oncogenic genes. Although recent milestones have been reached with DNA binding blunting of c-Myc with the cell penetrant b-HLH-LZ Omomyc, the targeting of its b-HLH-LZ with small molecules, peptides, or proteins is lagging. As reviewed recently, the main problem relies in the intrinsically disordered nature of the b-HLH-LZ of c-Myc. This greatly complicates the classical approach of targeting a docking site with inhibitors. The solution state methods such as NMR are progressing towards the characterization of the ensembles of structures or states the b-HLH-LZ can adopt. However, the delicate balance that dictates the population of these dynamically interchanging states relies on its primary structure and the weak polar, electrostatic and hydrophobic interactions allowed. In this context, it is of the utmost importance to study the b-HLH-LZ of c-Myc in its WT background and avoid the use of tags such as His-tags. These tags could disrupt the balance of forces which could alter the conformational and physical transitions and states it can undergo and adopt. Here, we describe a robust protocol to express the WT b-HLH-LZ in E. coli and purify it, without the need of tags, to obtain the required quantities for solution state biophysical characterization such as NMR.

Methods for the expression, purification, preparation, and biophysical characterization of constructs of the c-Myc and Max b-HLH-LZs.

Specific heterodimerization and DNA binding by the b-HLH-LZ transcription factors c-Myc and Max is central to the activation and repression activities of c-Myc that lead to cell growth, proliferation, and tumorigenesis (Adhikary and Eilers, Nat Rev Mol Cell Biol 6:635-645, 2005; Eilers and Eisenman, Genes Dev 22:2755-2766, 2008; Grandori et al., Annu Rev Cell Dev Biol 16:653-699, 2000; Whitfield and Soucek, Cell Mol Life Sci 69:931-934, 2011). Although many c-Myc-interacting partner proteins are known to interact through their HLH domain (Adhikary and Eilers, Nat Rev Mol Cell Biol 6:635-645, 2005), current knowledge regarding the structure and the determinants of molecular recognition of these complexes is still very limited. Moreover, recent advances in the development and use of b-HLH-LZ dominant negatives (Soucek et al., Nature 455:679-683, 2008) and inhibitors of c-Myc interaction with its protein partners (Bidwell et al., J Control Release 135:2-10, 2009; Mustata et al., J Med Chem 52:1247-1250, 2009; Prochownik and Vogt, Genes Cancer 1:650-659, 2010) or DNA highlight the importance of efficient protocols to prepare such constructs and variants. Here, we provide methods to produce and purify high quantities of pure and untagged b-HLH-LZ constructs of c-Myc and Max as well as specific c-Myc/Max heterodimers for their biophysical and structural characterization by CD, NMR, or crystallography. Moreover, biochemical methods to analyze the homodimers and heterodimers as well as DNA binding of these constructs by native electrophoresis are presented. In addition to enable the investigation of the c-Myc/Max b-HLH-LZ complexes, the protocols described herein can be applied to the biochemical characterization of various mutants of either partner, as well as to ternary complexes with other partner proteins.