PROJECT SUMMARY/ABSTRACT
Our recent discovery of orally brain permeable small molecules that mimic the bioactivity of Humanin (HN)
peptide to enhance and normalize neuronal phospho-Akt (p-Akt) levels provides a unique opportunity for
evaluating this new approach in Alzheimer's disease (AD). In this proposal, we will direct our efforts to
optimize this new class of agents, focusing on screening additional hits, enhancing their potency, drug-like
properties, solubility, oral brain permeability and efficacy in an AD model towards development of this novel
therapeutic approach for AD. We will also use modeling to identify HN based peptidomimetics for testing. Our
data show that these small molecule HN mimetics, like HN, can suppress neuronal death through its activation
of the gp130 receptor and signaling via the PI3/Akt pathway and provide neuroprotection for primary
hippocampal neurons against N-methyl D-aspartate (NMDA) and Aβ-induced neurotoxicity. HN is a naturally
occurring mitochondrial-derived brain peptide that decreases with age and may act as a neuroprotective factor
against AD-relevant neurotoxicity. Treatment of hippocampal neurons with our HN mimetic compound 2
resulted in an increase in p-Akt, and this correlated to its observed neuroprotective effects. In AD patients, a
significant decrease in p-Akt has been reported. Similarly, in aged apolipoprotein E4 (ApoE4) mice, there is a
significant decrease in p-Akt in the brain relative to age-matched ApoE3 mice suggesting that PI3/Akt signaling
is affected by ApoE4, a risk factor in AD. Activation of PI3/Akt signaling can transcriptionally modulate genes
related to memory such as choline acetyltransferase (ChAT) and vesicular acetylcholine transporter (VAChT)
and may also regulate postsynaptic proteins involved in neuroplasticity. AD is the most prevalent age-related
dementia, currently afflicting more than 5.4 million people in the US. Given the urgent need for new
therapeutic approaches for AD, these HN mimetics could provide promising lead candidates for therapeutic
development. In Aim 1, we plan to evaluate small molecule HN mimetics and peptidomimetics for activation of
gp130 and normalization of p-Akt along with their neuroprotection against Aβ and NMDA induced neurotoxicity.
In Aim 2, we would conduct a design and synthesis campaign using current SAR and new docking/modeling
data to identify small mimetics, peptides and peptidomimetics. We will optimize potency, drug-like properties,
solubility and oral brain bioavailability for efficacy testing. The best analogs/peptidomimetics from Aims 1 and 2
will undergo in vitro ADMET profiling and pharmacokinetic (PK) studies, along with phosphoproteomics
analyses, in Aim 3 to prioritize the optimal compounds for in vivo efficacy testing in the ApoE4(TR):5XFAD
murine model of AD as part of Aim 4. The goal is to identify orally available HN-mimetics that
enhance/normalize brain p-Akt levels and improve cognition. Like HN itself, they could also have broader
therapeutic applications in traumatic brain injury (TBI), stroke, Aβ-induced cerebrovascular dementia,
amyotrophic lateral sclerosis (ALS) and could lead to a new class of preclinical candidates for AD.