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. 1994 Oct 11;22(20):4250–4258. doi: 10.1093/nar/22.20.4250

Functional differences between the Oct2 transactivation domains determine the transactivation potential of individual Oct2 isoforms.

A Annweiler 1, S Zwilling 1, T Wirth 1
PMCID: PMC331935  PMID: 7937153

Abstract

The lymphocyte specific transcription factor Oct2 is involved in mediating the B-cell specific transcriptional activity of the octamer motif. Mutational analyses in the context of the complete Oct2 protein had indicated that Oct2 contains two transactivation domains. These two domains appeared to be redundant for activation from a promoter proximal position, whereas stimulation from a remote enhancer position specifically required the C-terminal transactivation domain and an additional B-cell restricted activity. We have generated fusion proteins between the DNA binding domain of the yeast Gal4 transcription factor and individual Oct2 protein domains to analyze their transactivation potential separately. We show that both N- and C-terminal domains can stimulate transcription from a promoter proximal position independently. However, only the C-terminal transactivation domain activates from a distance and it can only do so in B-cells. The C-terminal transactivation domain represents a composite transactivation domain. Whereas removal of just 9 aminoacids from the extreme C-terminus lead to a complete inactivation of this domain deletions from the other side resulted in a gradual loss of activity. We also characterized the transactivation potential of different N-terminal regions of Oct2 generated by alternative splicing. We show that the N-terminus of one of the isoforms, Oct2.3, contains a negative regulatory domain (NRD), which can inactivate the neighbouring glutamine-rich transactivation in cis. The presence of this NRD affects the overall phosphorylation state of the Oct2 protein. This result suggests that the mechanism of inactivation might involve differential protein phosphorylation.

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Selected References

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