GnRH protective effects against long-term potentiation impairment induced by AANAT-siRNA.

There is an interplay between the gonadotropin-releasing hormone (GnRH) and melatoninergic systems. The key enzyme of melatonin synthesis (arylalkylamine N-acetyltransferase, AANAT), and GnRH receptors are expressed in the hippocampus. While it has been shown that hippocampal AANAT enzyme activity is necessary for proper hippocampal cognitive function, their role in long-term potentiation (LTP) induction is not fully understood. In current study, the impact of GnRH on LTP induction was investigated, while hippocampal melatonin synthesis had been inhibited. The melatonin synthesis was inhibited by AANAT-siRNA administration, and LTP was induced using in vivo field potential electrophysiological recording. Animals were divided into 5 groups: Intact, vehicle, siRNA, GnRH and siRNA+GnRH. All animals, except intact group, experienced the stereotaxic surgery and intra-hippocampal cannulation to receive vehicle agent, AANAT siRNA (0.5 µg/hip), GnRH (1 ng/rat), and AANAT siRNA+GnRH. The recognition memory was assessed by Novel object recognition test. The field potential electrophysiology experiment was conducted by stimulating the Schaffer collateral pathway, and LTP induction was carried out through high-frequency stimulation (HFS). After recording, animals' brain was isolated and quickly frozen for further hippocampal melatonin levels measurement by LC-MS and AANAT mRNA levels by qRT-PCR. GnRH injection in the hippocampus increased local AANAT-mRNA expression and melatonin levels. GnRH-treated animals displayed higher LTP amplitude compared to intact, vehicle and siRNA groups. While the reduction in hippocampal melatonin levels by AANAT-siRNA inhibited LTP and impaired recognition memory, the GnRH prevented these adverse effects. The data suggests that GnRH have protective effects against AANAT-siRNA-induced LTP decline. The protective mechanism at least partially, may be related to the increased expression of local AANAT-mRNA.

Inhibition of hippocampal melatonin synthesis by siRNA induced learning and memory deficits in male rats.

Melatonin, the multi-functional neurohormone, is synthesized in the extra-pineal tissues such as the hippocampus. The key enzyme in hippocampal melatonin synthesis is arylalkylamine-N-acetyltransferase (AANAT). The importance of melatonin synthesis in the hippocampus has not yet been determined. We investigated hippocampal AANAT role in cognitive function using gene silencing small interference RNA (siRNA) technology. The hippocampal local melatonin synthesis was inhibited by AANAT-siRNA injection. The time-gene silencing profile of AANAT-siRNA was obtained by RT-PCR technique. The cytotoxicity of siRNA dose was determined by MTT assay on the B65 neural cells. Animals received the selected dosage of AANAT-siRNA. Then, the spatial working memory (Y maze), object recognition memory and spatial reference memory (Morris's water maze, MWM) were evaluated. The anxiety-like behaviors were evaluated by the elevated plus maze. After one week, following the probe test of MWM, the rats were sacrificed for histological analysis. The hippocampal melatonin levels were measured using the liquid chromatography-mass spectrometry technique. The hippocampal melatonin levels in the AANAT-siRNA group decreased. Animals receiving the AANAT-siRNA showed deficits in spatial learning and working memory which were verified by increased escape latency and reduced spontaneous alternations, respectively. There was an increase in anxiety-like behaviors as well as a deficit in recognition memory in the AANAT-siRNA group. The Nissl staining and immunohistochemistry of activated caspase-3 showed the neuronal loss and cell apoptosis in hippocampal tissue of the AANAT-siRNA group. The 18F-FDG-PET imaging displayed lower glucose metabolism following the reduction in AANAT mRNA. Data suggest that the AANAT mRNA and hippocampal melatonin synthesis might be an essential factor for learning, memory and some aspects of cognition, as well as homeostasis of hippocampal cells.

The increment of annexin V-positive microvesicles versus annexin V-negative microvesicles in CSF of an animal model of Alzheimer's disease.

OBJECTIVE: Extracellular microvesicles (MVs) as a specific signaling molecule have received much attention in nervous system studies. Alterations in the tissue redox status in pathological conditions, such as Alzheimer's disease (AD), facilitate the translocation of cell membrane phosphatidylserine to the outer leaflet and lead to the MVs shedding. Annexin V binds with high affinity to phosphatidylserine. Some arguments exist about whether Annexin V-negative MVs should be considered in pathological conditions. MATERIAL AND METHOD: We compared the kinetics of two phenotypes of Annexin V-positive and Annexin V-negative MVs in the cerebrospinal fluid (CSF) of amyloid-ß (Aß)-treated male Wistar rats with flow cytometry technique. The Aß was injected bilaterally into the cerebral ventricles. Thioflavin T staining was used to confirm the presence of hippocampal Aß fibrils two weeks post-Aß injection. Levels of hippocampal interleukin-1ß were assessed as an inflammatory index. The CSF malondialdehyde (MDA) concentration was determined. The cognitive impairment and anxiety behaviors were assessed by object recognition and elevated plus maze tests, respectively. RESULTS: Elevation of MDA levels and a significant rise in the scoring of IL-1ß staining were found in the Aß group. The Aß induced anxiogenic behavior, impaired novel object recognition memory, and increased the CSF levels of the total number of MVs. The number of Annexin V-positive MVs was significantly higher than Annexin V-negative MVs in all groups. CONCLUSION: Data showed that Annexin V-positive MVs potentially have a significant contribution to the pathophysiology of the Aß-induced cognitive impairment. To catch a clear image of microvesicle production in pathological conditions, both phenotypes of Annexin V-positive and Annexin V-negative MVs should be analyzed and reported.