Abstract

The ubiquitin proteolytic pathway is a major system for selective protein degradation in eukaryotic cells. One of the first steps in the degradation of a protein via this pathway involves selective modification of -NH₂ groups of internal lysine residues by ubiquitination. To date, this amino group has been the only known target for ubiquitination. Here we report that the N-terminal residue of MyoD is sufficient and necessary for promotion of conjugation and subsequent degradation of the protein. Substitution of all lysine residues in the protein did not affect significantly its conjugation and degradation either in vivoor in vitro. In cells, degradation of the lysine-less protein is inhibited by the proteasome inhibitors MG132 and lactacystin. Inhibition is accompanied by accumulation of high molecular mass ubiquitinated forms of the modified MyoD. In striking contrast, wild-type MyoD, in which all the internal Lys residues have been retained but the N-terminus has been extended by fusion of a short peptide, is stable both in vivo and in vitro. In a cell-free system, ATP and multiple ubiquitination are essential for degradation of the lysine-less protein. Specific chemical modifications have yielded similar results. Selective blocking of the -NH₂ group of wild-type protein renders it stable, while modification of the internal Lys residues with preservation of the free N-terminal group left the protein susceptible to degradation. Our data suggest that conjugation of MyoD occurs via a novel modification involving attachment of ubiquitin to the N-terminal residue. The polyubiquitin chain is then synthesized on an internal Lys residue of the linearly attached first ubiquitin moiety.