The prokineticin receptor antagonist PC1 rescues memory impairment induced by ß amyloid administration through the modulation of prokineticin system.

Growing evidences demonstrate that chemokines and chemokine receptors are up-regulated in resident central nervous system cells during Alzheimer's disease contributing to neuroinflammation and neurodegeneration. Prokineticin 2 belongs to a new family of chemokines which recently emerged as a critical player in immune system and inflammatory diseases. Since pharmacological blockade in vitro of the prokineticin system is able to antagonize Amyloid ß-induced neurotoxicity, the aim of the present study was to investigate in vivo effects of prokineticin receptor antagonist PC1 on memory impairment in a rodent model of Alzheimer's disease. Rats were intracerebroventricular infused with Aß1-42 and behavioral responses as well as the expression profile in hippocampus of prokineticin 2 and its receptors were investigated. Results demonstrated that Aß1-42-infused rats developed significant memory impairments together with a marked up-regulation of both prokineticin 2 and its receptors in hippocampal neurons and astrocytes. Treatment with PC1 significantly improved learning capability of Aß1-42-infused rats restoring the balance of prokineticin system. This study pointed to a neuroprotective role of PC1 on Aß1-42-induced memory deficits that could be ascribed to the ability of PC1 to modulate rat hippocampal prokineticin system and to recover the impaired Aß1-42-induced neurogenesis. This suggests that prokineticin system antagonism could be considered as a new approach for the study of AD etiopathology.

PK2ß ligand, a splice variant of prokineticin 2, is able to modulate and drive signaling through PKR1 receptor.

Prokineticin-2 (PK2) is a secreted bioactive peptide that signals through two GPCRs, the prokineticin receptors (PKRs), and regulates a variety of biological processes including angiogenesis, immunity and nociception. The PK2 primary transcript has two alternative splice variants, PK2 and PK2L (a Long form) which is cleaved in an active peptide, named PK2ß that preferentially binds to PKR1 receptor. The aim of this study was to characterize the PK2ß. Using different Saccharomyces cerevisiae strains, we examined the specificity of PKR1 and PKR2 G-protein coupling following PK2ß binding. Data obtained in yeast confirmed that PK2 binds both receptors, inducing a comparable response throughout a promiscuous coupling of G protein subtypes. Conversely, we demonstrated, for the first time, that PK2ß preferentially binding to PKR1, activates a signaling cascade that not depends on Gαi/o coupling. The binding specificity of PK2ß for PKR1 was evaluated by the analysis of PKR mutant in yeast and GST pull-down experiments, suggesting an important role of PKR1 amino-terminal region. We also evaluated the ability of PK2ß to differentially activate PKR1 and/or PKR2 by in vivo nociceptive experiments and we showed that PK2ß induces intense sensitization of peripheral nociceptors to painful stimuli through the activation of PKR1. To analyze PK2ß-induced signal transduction, we demonstrated the inability of PK2ß to induce STAT3 protein phosphorylation in organotypic primary explants from mice Dorsal Root Ganglion (DRG), an important pain station. The control of the concentration ratio between PK2ß and PK2 could be one of the keys to allow the specificity of the cell response of prokineticin signaling pathway.

Maternal exposure to low levels of corticosterone during lactation protects adult rat progeny against TNBS-induced colitis: A study on GR-mediated anti-inflammatory effect and prokineticin system.

The early phase of life represents a critical period for the development of an organism. Interestingly, early life experiences are able to influence the development of the gastrointestinal tract and the reactivity to colonic inflammatory stress. We recently demonstrated that adult male rats exposed to low doses of corticosterone during lactation (CORT-nursed rats) are protected against experimental colitis induced by the intracolonic infusion of 2,4,6-trinitrobenzenesulfonic acid (TNBS). Based on these interesting results, we wanted to better investigate which cellular actors could be involved in the protection of CORT-nursed rats from TNBS-induced experimental colitis. Therefore, in the present work, we focused our attention on different factors implicated in GR-mediated anti-inflammatory effect. To address this issue, colonic tissues, collected from control and CORT-nursed healthy animals and from control and CORT-nursed colitic rats, were processed and the following inflammatory factors were evaluated: the expression of (i) glucocorticoid receptors (GR), (ii) glucocorticoid-induced leucine zipper (GILZ), (iii) phospho-p65NF-κB, (iv) the pro-inflammatory cytokines IL-1ß and TNF-α, (v) the prokineticins PK2 and PK2L and (vi) their receptors PKR1 and PKR2. We found that adult CORT-nursed rats, in comparison to controls, showed increased expression of colonic GR and reduced expression of pro-inflammatory molecules (IL-1ß, TNF-α, PK2 and PK2L) in response to inflammatory colitis. The observed changes were associated with an increase in GILZ colonic expression and with a reduction in phospo-p65NF-κB colonic expression.