The transcription factor v-Myb is a potent inducer of myeloid leukemias, and its cellular homologue c-Myb plays a crucial role in the regulation of hematopoiesis. Recently, Bies and coworkers (Bies, J., Markus, J. & Wolff, L. (2002) J. Biol. Chem, 277, 8999-9009) presented evidence that murine c-Myb can be sumoylated under overexpression conditions in COS7 cells when cotransfected with FLAG-tagged SUMO-1. Here we provide independent evidence that human c-Myb is also subject to SUMO-1 conjugation under more physiological conditions as revealed by coimmunoprecipitation analysis of Jurkat cells and transfected CV-1 cells. Analysis in an in vitro conjugation system showed that modification of the two sites K503 and K527 is interdependent. A twohybrid screening revealed that the SUMO-1 conjugase Ubc9 is one of a few major Myb-interacting proteins. The moderate basal level of sumoylation was greatly enhanced by cotransfection of PIASy, an E3 ligase for SUMO-1. The functional consequence of abolishing sumoylation was enhanced activation both of a transiently transfected reporter gene and of a resident Myb-target gene. When single and double mutants were compared, we found a clear correlation between reduction in sumoylation and increase in transcriptional activation. Enhancing sumoylation by contransfection of PIASy had a negative effect on both Myb-induced and basal level reporter activation. Furthermore, PIASy caused a shift in nuclear distribution of c-Myb towards the insoluble matrix fraction. We propose that the negative influence on transactivation properties by the negative regulatory domain region of c-Myb depends on the sumoylation sites located here.Keywords: c-Myb; transcription; SUMO-1; Ubc9; PIASy.The c-Myb transcription factor plays a central role in the regulation of cell growth and differentiation, in particular in hematopoietic progenitor cells (reviewed in [1]). Homozygous null c-Myb/Rag1 chimerical mice are blocked in early T-cell development, while mice with a c-myb null mutation display severe hematopoietic defects leading to in utero death at E15 [2,3]. The c-Myb protein consists of an N-terminal DNA-binding domain (DBD), a central transactivation domain (TAD) and a C-terminal negative regulatory domain (NRD). The DBD of c-Myb is comprised of the three imperfect repeats: R 1 , R 2 and R 3 , each related to the helix-turn-helix motif [4][5][6][7].Oncogenic alterations, as found in AMV v-Myb, include both N-and C-terminal deletions as well as point mutations [8]. AMV v-myb is a potent and cell-type specific oncogene that transforms target cells in the macrophage lineage and induces monocytic leukemia [8,9]. Several studies have attempted to define oncogenic determinants of v-myb. N-and C-terminal deletions remove several sites of protein modification, including an N-terminal CK2 phosphorylation site (S11 and S12) [10], and a putative MAPK-site (S528) [11][12][13] as well as acetylation sites [14,15] located in the deleted portion of the C-terminal NRD. In addition, specific point mutations in v-My...
In the Myb family, as in other families of transcription factors sharing similar DNA-binding domains (DBDs), diversity of function is believed to rely mainly on the less conserved parts of the proteins and on their distinct patterns of expression. However, small conserved differences between DBDs of individual members could play a role in fine-tuning their function. We have compared the highly conserved DBDs of the three vertebrate Myb proteins (A-, B- and c-Myb) and found distinct functional differences. While A- and c-Myb behaved virtually identically in a variety of DNA-binding assays, B-Myb formed complexes of comparatively lower stability, rapidly dissociating under competitive conditions and showing less tolerance to binding site variations. The three protein domains also differed as substrates for protein kinases. Whereas PKA in theory should target the DBDs of A- and c-Myb, but not B-Myb, only c-Myb was phosphorylated by PKA. CK2 phosphorylated all three proteins, although on different sites in the N-terminal region. Finally, B-Myb was remarkably sensitive to cysteine-directed oxidation compared to the other Myb proteins. Our data suggest that the small differences that have evolved between individual Myb family members lead to clear differences in DBD properties even if their sequence recognition remains the same.
BackgroundThe transcription factor c-Myb is expressed in hematopoietic progenitor cells and other rapidly proliferating tissues, regulating genes important for proliferation, differentiation and survival. The DNA-binding domain (DBD) of c-Myb contains three tandemly arranged imperfect repeats, designated Myb domain R1, R2 and R3. The three-dimensional structure of the DBD shows that only the second and third Myb domains are directly involved in sequence-specific DNA-binding, while the R1 repeat does not contact DNA and only marginally affects DNA-binding properties. No structural information is available on the N-terminal 30 residues. Since deletion of the N-terminal region including R1 plays an important role in oncogenic activation of c-Myb, we asked whether this region confers properties beyond DNA-binding to the neighbouring c-Myb DBD.ResultsAnalysis of a putative RNA-binding function of c-Myb DBD revealed that poly(G) preferentially inhibited c-Myb DNA-binding. A strong sequence-selectivity was observed when different RNA polymers were compared. Most interesting, the poly(G) sensitivity was significantly larger for a protein containing the N-terminus and the R1-repeat than for the minimal DNA-binding domain.ConclusionPreferential inhibition of c-Myb DNA binding by poly(G) RNA suggests that c-Myb is able to interact with RNA in a sequence-selective manner. While R2 and R3, but not R1, are necessary for DNA-binding, R1 seems to have a distinct role in enhancing the RNA-sensitivity of c-Myb.
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