A1 Refereed original research article in a scientific journal
MAX ACTIVITY IS AFFECTED BY PHOSPHORYLATION AT 2 NH2-TERMINAL SITES
Authors: KOSKINEN PJ, VASTRIK I, MAKELA TP, EISENMAN RN, ALITALO K
Publisher: AMER ASSOC CANCER RESEARCH
Publication year: 1994
Journal: CELL GROWTH & DIFFERENTIATION
Journal name in source: CELL GROWTH & DIFFERENTIATION
Journal acronym: CELL GROWTH DIFFER
Volume: 5
Issue: 3
First page : 313
Last page: 320
Number of pages: 8
ISSN: 1044-9523
Abstract
Max is a nuclear phosphoprotein that has a dose-dependent role in regulation of Myc function. The DNA-binding activity of Max homodimers, but not of Myc/Max heterodimers, has been reported to be inhibited by NH2-terminal phosphorylation. (S. J. Berberich and M. D. Cole, Genes and Dev., 6: 166-176, 1992). Here, we have mapped the NH2-terminal in vivo phosphorylation sites of Max to Ser(2) and Ser(11) and show that the NH, termini of the two major alternatively spliced forms of Max (p21(max) and p22(max)) are equally phosphorylated despite differences in their amino acid sequences following Ser(11). A Max mutant deficient in the NH2-terminal phosphorylation was found to inhibit both basal and Myc-induced transcription of a reporter gene more efficiently than the wild-type protein. Similarly, the ability of Myc and Ras to induce transformation was more severely impaired by the mutant. These results indicate that the NH2-terminal phosphorylation diminishes the ability of Max to negatively interfere with Myc function. However, we found no evidence that Max phosphorylation would be regulated during cell growth or differentiation. Similarly, we observed no major cell cycle-dependent changes in the extent of phosphorylation between cell populations fractionated by centrifugal elutriation or by cell cycle inhibitors.
Max is a nuclear phosphoprotein that has a dose-dependent role in regulation of Myc function. The DNA-binding activity of Max homodimers, but not of Myc/Max heterodimers, has been reported to be inhibited by NH2-terminal phosphorylation. (S. J. Berberich and M. D. Cole, Genes and Dev., 6: 166-176, 1992). Here, we have mapped the NH2-terminal in vivo phosphorylation sites of Max to Ser(2) and Ser(11) and show that the NH, termini of the two major alternatively spliced forms of Max (p21(max) and p22(max)) are equally phosphorylated despite differences in their amino acid sequences following Ser(11). A Max mutant deficient in the NH2-terminal phosphorylation was found to inhibit both basal and Myc-induced transcription of a reporter gene more efficiently than the wild-type protein. Similarly, the ability of Myc and Ras to induce transformation was more severely impaired by the mutant. These results indicate that the NH2-terminal phosphorylation diminishes the ability of Max to negatively interfere with Myc function. However, we found no evidence that Max phosphorylation would be regulated during cell growth or differentiation. Similarly, we observed no major cell cycle-dependent changes in the extent of phosphorylation between cell populations fractionated by centrifugal elutriation or by cell cycle inhibitors.
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