Monomeric ß-amyloid interacts with type-1 insulin-like growth factor receptors to provide energy supply to neurons

ß-amyloid (Aß1-42) is produced by proteolytic cleavage of the transmembrane type-1 protein, amyloid precursor protein. Under pathological conditions, Aß1-42 self-aggregates into oligomers, which cause synaptic dysfunction and neuronal loss, and are considered the culprit of Alzheimer’s disease (AD). However, Aß1-42 is mainly monomeric at physiological concentrations, and the precise role of monomeric Aß1-42 in neuronal function is largely unknown. We report that the monomer of Aß1-42 activates type-1 insulin-like growth factor receptors and enhances glucose uptake in neurons and peripheral cells by promoting the translocation of the Glut3 glucose transporter from the cytosol to the plasma membrane. In neurons, activity-dependent glucose uptake was blunted after blocking endogenous Aß production, and re-established in the presence of cerebrospinal fluid Aß. APP-null neurons failed to enhance depolarization-stimulated glucose uptake unless exogenous monomeric Aß1-42 was added. These data suggest that Aß1-42 monomers were critical for maintaining neuronal glucose homeostasis. Accordingly, exogenous Aß1-42 monomers were able to rescue the low levels of glucose consumption observed in brain slices from AD mutant mice

The Inorganic Perspective of VEGF: Interactions of Cu2 + with Peptides Encompassing a Recognition Domain of the VEGF Receptor

The vascular endothelial growth factor A (VEGF-A) is a potent angiogenic factor, its activity may be influenced by the presence of copper(II) ions. To mimic the interaction between copper(II) and VEGF (Vascular Endotelial Growth Factor), the N- and C-terminally blocked peptide fragments VEGF73-101 and VEGF84-101, owing to VEGF165 protein, have been synthesized. These protein domains represent a specific recognition site with the VEGF receptor (VEGFR). Copper(II) complexes with VEGF73-101 and VEGF84-101 were investigated by means of potentiometry and UV-Vis, ESI-MS, CD, EPR spectroscopic methods. Both peptides have three histidine residues and display a binding high affinity for copper(II) ions. The proliferative activity of the peptides in the absence and presence of copper(II) ions as well as of VEGF-165 protein was also tested on HUVEC cells (Human Umbilical Vein Endothelial Cells). The VEGF73-101 showed a dose-dependent anti-proliferative activity, while the shorter peptide VEGF84-101 did not affect HUVEC proliferation, both in the presence and in the absence of VEGF

Small Hexokinase 1 Peptide against Toxic SOD1 G93A Mitochondrial Accumulation in ALS Rescues the ATP-Related Respiration

Mutations in Cu/Zn Superoxide Dismutase (SOD1) gene represent one of the most common causes of amyotrophic lateral sclerosis (ALS), a fatal neurodegenerative disorder that specifically affects motor neurons (MNs). The dismutase-active SOD1 G93A mutant is responsible for the formation of toxic aggregates onto the mitochondrial surface, using the Voltage-Dependent Anion Channel 1 (VDAC1) as an anchor point to the organelle. VDAC1 is the master regulator of cellular bioenergetics and by binding to hexokinases (HKs) it controls apoptosis. In ALS, however, SOD1 G93A impairs VDAC1 activity and displaces HK1 from mitochondria, promoting organelle dysfunction, and cell death. Using an ALS cell model, we demonstrate that a small synthetic peptide derived from the HK1 sequence (NHK1) recovers the cell viability in a dose–response manner and the defective mitochondrial respiration profile relative to the ADP phosphorylation. This correlates with an unexpected increase of VDAC1 expression and a reduction of SOD1 mutant accumulation at the mitochondrial level. Overall, our findings provide important new insights into the development of therapeutic molecules to fight ALS and help to better define the link between altered mitochondrial metabolism and MNs death in the disease