An internalization motif is created in the cytoplasmic domain of the transferrin receptor by substitution of a tyrosine at the first position of a predicted tight turn.

Receptors are internalized from the plasma membrane at approximately 10 times the rate of bulk membrane. The predominant model for the motif that promotes rapid internalization proposes a requirement for a tyrosine located in the first position of a tight turn. In this report we show that an internalization motif can be created de novo by substituting a tyrosine for the first or last residues of a tetrapeptide GDNS (residues 31-34) that is predicted to form a tight turn within the cytoplasmic domain of the human transferrin receptor. These substitutions restore wild-type levels of internalization to transferrin receptors that are poorly internalized due to missense mutations in the native internalization motif. The introduction of a tyrosine at the first or last position of the GDNS tetrapeptide in a transferrin receptor containing an unmodified wild-type internalization motif significantly increases the internalization rate above that of the wild-type receptor. Our results indicate that a functional novel internalization motif can be created by placing specific aromatic amino acids within the overall structure of an existing beta-turn in a cytoplasmic domain of a receptor.