NAP and D-SAL: neuroprotection against the beta amyloid peptide (1-42).

INTRODUCTION: NAP (Asn-Ala-Pro-Val-Ser-Ile-Pro-Gln, single amino acid letter code, NAPVSIPQ), an eight amino acid neuroprotective peptide derived from activity-dependent neuroprotective protein (ADNP), exhibits some structural similarity to activity-dependent neurotropic factor-9 (ADNF-9; Ser-Alal-Leu-Leu-Arg-Ser-Ile-Pro-Ala, SALLRSIPA). Both peptides are also active in the all D-amino acid conformation, termed D-NAP and D-SAL. Original results utilizing affinity chromatography coupled to mass spectrometry identified tubulin, the subunit protein of microtubules, as the major NAP-associating protein in brain. The NAP-tubulin association was found to be diminished in the presence of ADNF-9, D-NAP, and D-SAL, suggesting a common target of neuroprotection. The beta amyloid peptide interacts with microtubules, and previous studies have demonstrated protection against beta amyloid (25-35) toxicity by NAP and ADNF-9. NAP also inhibits beta amyloid (25-35 and 1-40) aggregation. METHODS: Cerebral cortical cultures derived from newborn rats were used in neuronal survival assays to test the activity of both NAP and D-SAL against the major Alzheimer's disease toxic peptide beta amyloid (1-42). RESULTS: NAP and D-SAL protected cerebral cortical neurons against the major Alzheimer's disease toxic peptide beta amyloid (1-42). Maximal protection of both peptides was observed at concentrations of 10-15 to 10-10 mol/l. CONCLUSION: These findings, together with those of previous in vivo studies conducted in relevant Alzheimer's disease models, pave the path to drug development. Bioavailability studies indicated that NAP penetrates cells and crosses the blood-brain barrier after nasal or systemic administration. Phase II clinical trials of NAP are currently in progress by Allon Therapeutics Inc.

NAP, a neuroprotective drug candidate in clinical trials, stimulates microtubule assembly in the living cell.

NAP (NAPVSIPQ), derived from activity-dependent neuroprotective protein (ADNP) provides neuroprotection in vitro and in vivo against a wide variety of neurotoxic substances. To further understand the mechanism by which NAP provides broad neuroprotection it was essential to find NAP's binding partners. Previous results, using affinity chromatography coupled with mass spectrometry, identified tubulin, the subunit protein of microtubules, as the major NAP binding protein in neurons and glial cells. Here, following microtubule depolymerization in the presence of nocodazole, NAP treatment enhanced rapid microtubule assembly and stimulated neurite outgrowth. Nocodazole is an established inhibitor of axoplasmic transport and cell division that exerts its effect by depolymerizing microtubules. NAP shows selectivity in interacting with brain tubulin and does not affect dividing cells. This data demonstrates that NAP functions as a neuroprotectant, at least in part, through its interaction with tubulin with a resulting increase in microtubule assembly.

Tubulin is the target binding site for NAP-related peptides: ADNF-9, D-NAP, and D-SAL.

The authors set out to investigate whether NAP-related peptides interact with tubulin at a NAP binding site. Previous studies have shown that the neuroprotective peptide NAP binds to tubulin. As NAP (NAPVSIPQ) shares structural similarities with ADNF-9 (SALLRSIPA), and the all-D-enantiomers, D-NAP and D-SAL, it was hypothesized that all of these peptides compete with NAP-tubulin binding. Using NAP affinity column and extracts from newborn rat brain (cerebral cortex), we now show that the above-mentioned peptides compete with NAP binding to tubulin. The identification of tubulin as a target binding site for NAP-related peptides explains, in part, the broad neuroprotective activity offered by these potent peptides.

The femtomolar-acting NAP interacts with microtubules: Novel aspects of astrocyte protection.

Activity-dependent neuroprotective protein (ADNP), a gene product essential for brain formation, contains a short octapeptide sequence NAPVSIPQ (NAP) that protects neurons against a wide variety of insults. At the pico-molar concentration range, NAP provides neuroprotection by direct interaction with neurons. At the femtomolar concentration range, NAP requires the presence of glial cells to provide neuroprotection. To further understand the mechanism of neuroprotection afforded by NAP, specific binding proteins were searched for. Tubulin, the major subunit protein of microtubules, was identified as a NAP binding molecule. NAP structure allows membrane penetration, followed by tubulin binding and facilitation of microtubule assembly toward cellular protection in astrocytes. NAP (10(-15) M) promoted microtubule assembly in vitro and protected astrocytes against zinc intoxication which is associated with microtubule disruption. A two hour incubation period of astrocytes with femtomolar concentrations of NAP resulted in microtubule re-organization and transient increases in immunoreactive non-phosphorylated tau. Microtubules are the key component of the neuronal and glial cytoskeleton that regulates cell division, differentiation and protection, while tau pathology is a major contributor to Alzheimer's disease and other dementias. The findings described here may open up new horizons in research and development of neuroprotective compounds.

Peptide neuroprotection through specific interaction with brain tubulin.

This study aimed to identify the neuronal target for the potent neuroprotective peptide NAP. When added to pheochromocytoma cells (neuronal model), NAP was found in the intracellular milieu and was co-localized with microtubules. NAP induced neurite outgrowth and protected primary neurons against microtubule-associated ZnCl2 toxicity. Rapid microtubule reorganization into distinct microtubules ensued after NAP addition to both pheochromocytoma cells and primary cerebral cortical neurons, but not to fibrobalsts. While binding neuronal tubulin and protecting pheochromocytoma cells against oxidative stress, NAP did not bind tubulin extracted from fibroblasts, nor did it protect those cells against oxidative stress. Affinity chromatography identified the brain-specific betaIII-tubulin as a major NAP binding protein. Paclitaxel (a microtubule aggregating agent that interacts with beta-tubulin) reduced NAP tubulin binding. Thus, the underlying mechanism for the neuroprotection offered by NAP is targeting neuronal microtubules that are essential for neuronal survival and function.

A femtomolar acting octapeptide interacts with tubulin and protects astrocytes against zinc intoxication.

An octapeptide was previously described that protects neurons against a wide variety of insults directly and indirectly as a result of interactions (at femtomolar concentrations) with supporting glial cells. The current study set out to identify the octapeptide binding molecules so as to understand the high affinity mechanisms of cellular protection. Studies utilizing affinity chromatography of brain extracts identified tubulin, the brain major protein, as the octapeptide-binding ligand. Dot blot analysis with pure tubulin and the biotinylated octapeptide verified this finding. When added to cerebral cortical astrocytes, the octapeptide (10(-15)-10(-10) m) induced a rapid microtubule reorganization into distinct microtubular structures that were stained by monoclonal tubulin antibodies and visualized by confocal microscopy. Fluorescein-labeled octapeptide induced a similar change and was detected in the intracellular milieu, even when cells were incubated at 4 degrees C or at low pH. In a cell-free system, the octapeptide stimulated tubulin assembly into microtubules. Furthermore, treatment of astrocytes with zinc chloride resulted in microtubule disassembly and cell death that was protected by the octapeptide. In conclusion, the results suggest that the octapeptide crosses the plasma membrane and interacts directly with tubulin, the microtubule subunit, to induce microtubule reorganization and improved survival. Because microtubules are the key component of the neuronal and glial cytoskeleton that regulates cell division, differentiation, and protection, this finding may explain the breadth and efficiency of the cellular protective capacities of the octapeptide.