Repression by the Mad(Mxi1)-Sin3 complex

The functions of Myc in transformation and transactivation are countered by the suppressive actions of the Mad(Mxi1) family. Mad(Mxi1) proteins not only compete with Myc for dimerization to Max and binding to Myc/ Max consensus sites but also recruit powerful repressors of gene expression. A prediction of the yin-yang relationship between Myc and Mad(Mxi1) families would be that the latter constitutes a new class of tumor suppressors. Here, we review the current literature on the Mad(Mxi1) family, with particular attention paid to the molecular mechanisms by which these proteins antagonize the actions of Myc in normal and neoplastic cells. BioEssays 20 :808–818, 1998. © 1998 John Wiley & Sons, Inc.     

Myc and Max function as a nucleoprotein complex.

The Myc family of oncoproteins are thought to regulate proliferation and differentiation in a wide variety of cell types. Recent studies show that Myc proteins form sequence-specific DNA-binding complexes with Max, a new member of the helix-loop-helix leucine zipper protein class. The properties of the Myc-Max complex suggest a mechanism for Myc's function in both normal and neoplastic cell behavior.     

The c-Myc protein induces cell cycle progression and apoptosis through dimerization with Max.

The c-Myc protein (Myc) is involved in cellular transformation and mitogenesis, but is also a potent inducer of programmed cell death, or apoptosis. Whether these apparently opposite functions are mediated through common or distinct molecular mechanisms remains unclear. Myc and its partner protein, Max, dimerize and bind DNA in vitro and in vivo through basic/helix-loop-helix/leucine zipper motifs (bHLH-LZ). By using complementary leucine zipper mutants (termed MycEG and MaxEG), which dimerize efficiently with each other but not with their wild-type partners, we demonstrate that both cell cycle progression and apoptosis in nontransformed rodent fibroblasts are induced by Myc-Max dimers. MycEG or MaxEG alone are inactive, but co-expression restores ability to prevent withdrawal from the cell cycle and to induce cell death upon removal of growth factors. Thus, Myc can control two alternative cell fates through dimerization with a single partner, Max.     

Determination of the dissociation constants for recombinant c-Myc, Max, and DNA complexes: the inhibitory effect of linoleic acid on the DNA-binding step

c-Myc, the protein product of protooncogene c-myc, functions in cell proliferation, differentiation, and neoplastic disease. In this study, recombinant c-Myc and Max proteins, encompassing DNA binding (basic region) and dimerization (helix-loop-helix/leucine zipper) domain of human origin, were expressed in bacteria as Myc87 and Max85. Myc87 was purified under denatured conditions and was renatured again. The dissociation constant for the protein dimers and for dimer/DNA complexes were not detectable by isothermal titration calorimetry because of the low degree of solubility of Myc87 and Max85. Therefore, we set up equations which were used to determine the dissociation constants from the proportion of protein-DNA complexes. The dimer dissociation constants in TBS were 5.90(+/-0.54)x10(-7)M for Max85/Max85 homodimer, 6.85(+/-0.25)x10(-3)M for Myc87/Myc87 homodimer, and 2.55(+/-0.29)x10(-8)M for Myc87/Max85 heterodimer, and the DNA-binding dissociation constants in TBS were 1.33(+/-0.21)x10(-9)M for Max85/Max85/DNA, 2.27(+/-0.08)x10(-12)M for Myc87/Myc87/DNA, and 4.43(+/-0.37)x10(-10)M for Myc87/Max85/DNA. In addition, we revealed that linoleic acid which is known as an inhibitor for the formation of Max/Max/DNA complex reduced the affinity of Max homodimer for DNA. This result indicates that linoleic acid may bind to the DNA-binding region of Max homodimer.