Abstract
In most cells, proteins belonging to the Rel/NF-kappa B family of transcription factors are held in inactive form in the cytoplasm by an inhibitor protein, I kappa B alpha. Stimulation of the cells leads to degradation of the inhibitor and transit of active DNA-binding Rel/NF-kappa B dimers to the nucleus. I kappa B alpha is also able to inhibit DNA binding by Rel/NF-kappa B dimers in vitro, suggesting that it may perform the same function in cells when the activating signal is no longer present. Structurally, the human I kappa B alpha molecule can be divided into three sections: a 70-amino-acid N terminus with no known function, a 205-residue midsection composed of six ankyrin-like repeats, and a very acidic 42-amino-acid C terminus that resembles a PEST sequence. In this study we examined how the structural elements of the I kappa B alpha protein correlate with its functional capabilities both in vitro and in vivo. Using a battery of I kappa B alpha mutants, we show that (i) a dimer binds a single I kappa B alpha molecule, (ii) the acidic C-terminal region of I kappa B alpha is not required for protein-protein binding and does not mask the nuclear localization signal of the dimer, (iii) the same C-terminal region is required for inhibition of DNA binding, and (iv) this inhibition may be accomplished by direct interaction between the PEST-like region and the DNA-binding region of one of the subunits of the dimer.
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