Neuroglobin and cellular prion protein (PrPC) are expressed in the nervous system and co-localized in the retinal ganglion cell layer. Both proteins do not have an unambiguously assigned function, and it was recently reported that PrPC aggregates rapidly in the presence of neuroglobin, whereas it does not aggregate in the presence of myoglobin, another globin with different tissue specificity. Electrostatic complementarity between the unstructured PrPC N-terminus and neuroglobin has been proposed to mediate this specific interaction. To verify this hypothesis experimentally, we have used a combined approach of automated docking and molecular dynamics (MD) studies carried out on short stretches of prion protein (PrP) N-terminus to identify the minimal electrostatically interacting aminoacidic sequences with neuroglobin. Subsequently, we have performed the synthesis of these peptides by solid phase methods, and we tested their interaction with neuroglobin by surface plasmon resonance (SPR). Preliminary results confirm unequivocally the specific interaction between synthetic PrP peptides and neuroglobin suggesting a crucial role of PrPC positively charged regions in this proteinprotein association.
Neuroglobin-prion protein interaction: what's the function?
Vitale RM;Amodeo P;
2011
Abstract
Neuroglobin and cellular prion protein (PrPC) are expressed in the nervous system and co-localized in the retinal ganglion cell layer. Both proteins do not have an unambiguously assigned function, and it was recently reported that PrPC aggregates rapidly in the presence of neuroglobin, whereas it does not aggregate in the presence of myoglobin, another globin with different tissue specificity. Electrostatic complementarity between the unstructured PrPC N-terminus and neuroglobin has been proposed to mediate this specific interaction. To verify this hypothesis experimentally, we have used a combined approach of automated docking and molecular dynamics (MD) studies carried out on short stretches of prion protein (PrP) N-terminus to identify the minimal electrostatically interacting aminoacidic sequences with neuroglobin. Subsequently, we have performed the synthesis of these peptides by solid phase methods, and we tested their interaction with neuroglobin by surface plasmon resonance (SPR). Preliminary results confirm unequivocally the specific interaction between synthetic PrP peptides and neuroglobin suggesting a crucial role of PrPC positively charged regions in this proteinprotein association.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
