The essential cofactor TRRAP recruits the histone acetyltransferase hGCN5 to c-Myc
SB McMahon, MA Wood, MD Cole - Molecular and cellular biology, 2000 - Taylor & Francis
SB McMahon, MA Wood, MD Cole
Molecular and cellular biology, 2000•Taylor & FrancisThe c-Myc protein functions as a transcription factor to facilitate oncogenic transformation;
however, the biochemical and genetic pathways leading to transformation remain
undefined. We demonstrate here that the recently described c-Myc cofactor TRRAP recruits
histone acetylase activity, which is catalyzed by the human GCN5 protein. Since c-Myc
function is inhibited by recruitment of histone deacetylase activity through Mad family
proteins, these opposing biochemical activities are likely to be responsible for the …
however, the biochemical and genetic pathways leading to transformation remain
undefined. We demonstrate here that the recently described c-Myc cofactor TRRAP recruits
histone acetylase activity, which is catalyzed by the human GCN5 protein. Since c-Myc
function is inhibited by recruitment of histone deacetylase activity through Mad family
proteins, these opposing biochemical activities are likely to be responsible for the …
The c-Myc protein functions as a transcription factor to facilitate oncogenic transformation; however, the biochemical and genetic pathways leading to transformation remain undefined. We demonstrate here that the recently described c-Myc cofactor TRRAP recruits histone acetylase activity, which is catalyzed by the human GCN5 protein. Since c-Myc function is inhibited by recruitment of histone deacetylase activity through Mad family proteins, these opposing biochemical activities are likely to be responsible for the antagonistic biological effects of c-Myc and Mad on target genes and ultimately on cellular transformation.
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