Ubiquitin ligases are the final, and potentially the most important determinant of
substrate specificity in
ubiquitination of
proteins. The ligases must simultaneously distinguish their protein substrate from thousands of other proteins in the
cell, and from other (ubiquitination-inactive) forms of the same protein. This can be achieved by different mechanisms, most of which involve recognition of
degrons: specific short
amino acid sequences or chemical motifs on the substrate.
N-degrons Proteolytic cleavage can lead to exposure of residues at the
N-terminus of a protein. According to the
N-end rule, different N-terminal amino acids (or N-degrons) are recognized to a different extent by their appropriate ubiquitin ligase (N-recognin), influencing the
half-life of the protein. For instance, positively charged (
Arg,
Lys,
His) and bulky
hydrophobic amino acids (
Phe,
Trp,
Tyr,
Leu,
Ile) are recognized preferentially and thus considered destabilizing
degrons since they allow faster degradation of their proteins.
Phosphodegrons A degron can be converted into its active form by a
post-translational modification such as
phosphorylation of a
tyrosine,
serine or
threonine residue. In this case, the ubiquitin ligase exclusively recognizes the phosphorylated version of the substrate due to stabilization within the
binding site. For example,
FBW7, the
F-box substrate recognition unit of an
SCFFBW7ubiquitin ligase, stabilizes a phosphorylated substrate by
hydrogen binding its
arginine residues to the phosphate, as shown in the figure to the right. In absence of the
phosphate, residues of FBW7 repel the substrate. Another example of small molecule control of protein degradation is
phytohormone auxin in plants. Auxin binds to TIR1 (the substrate recognition domain of
SCFTIR1ubiquitin ligase) increasing the affinity of TIR1 for its substrates (transcriptional
repressors: Aux/IAA), and promoting their degradation.
Misfolded and sugar degrons In addition to recognizing amino acids, ubiquitin ligases can also detect unusual features on substrates that serve as signals for their destruction. These recognition domains have small hydrophobic pockets allowing them to bind high-
mannose containing
glycans.
Structural motifs In addition to linear
degrons, the E3 ligase can in some cases also recognize
structural motifs on the substrate. In this case, the 3D motif can allow the substrate to directly relate its
biochemical function to
ubiquitination. This relation can be demonstrated with
TRF1 protein (regulator of human
telomere length), which is recognized by its corresponding E3 ligase (
FBXO4) via an
intermolecular beta sheet interaction. TRF1 cannot be ubiquinated while telomere bound, likely because the same TRF1 domain that binds to its E3 ligase also binds to telomeres. == Disease relevance ==