Kristóf László

Intraamygdaloid microinjection of acylated-ghrelin influences passive avoidance learning

The brain-gut peptide acylated-ghrelin (A-Ghr) is a potent growth hormone (GH) secretagogue substance. A-Ghr is also known to influence on memory and learning processes. Its effect is mediated partly via GH secretagogue receptor (GHS-R) type 1a. The amygdaloid body (AMY) plays important role in memory and learning processes. Projections of ghrelinergic neurons were identified in the AMY, and previously we verified that A-Ghr infused into basolateral nucleus of the AMY (ABL) caused liquid food intake decrease. The aim of the present study was to examine the possible effects of A-Ghr in the ABL on learning. Male Wistar rats were examined in two-compartment passive avoidance paradigm. Animals were shocked with 0.4mA current and subsequently were microinjected bilaterally with 50 or 100 ng A-Ghr, 30 ng GHS-R antagonist d-Lys3-GHRP-6 (ANT), ANT+50 ng A-Ghr (dissolved in 0.15M sterile NaCl/0.4 microl) or vehicle into the ABL. Fifty nanogram A-Ghr significantly increased the latency time, the 100 ng and the ANT alone were ineffective. The effect of 50 ng A-Ghr was eliminated by the ANT pretreatment. Our results suggest that intraamygdaloid A-Ghr enhances learning processes and memory in aversive situations, and this effect can specifically be prevented by ANT pretreatment.

Role of intraamygdaloid acylated-ghrelin in spatial learning

According to recently published papers acylated-ghrelin (A-Ghr) modifies memory and learning. The basolateral nucleus of amygdala (ABL) participates in the regulation of memory and learning mechanisms. Previously we verified A-Ghr responsive neurons in the ABL by electrophysiological methods. In male Wistar rats effects of bilateral intraamygdaloid microinfusion of 50 ng, 100 ng A-Ghr, 15 ng Ghr receptor antagonist d-Lys3-GHRP-6 (ANT) or ANT+50 ng A-Ghr [dissolved in 0.15M sterile saline], or vehicle in 0.4 microl volume were investigated in Morris water maze paradigm. 50 ng A-Ghr significantly reduced latency to find the platform located in one of the quadrants of the maze. Effect of 50 ng A-Ghr was blocked by ANT pretreatment. ANT alone had no effect. Our results show that place learning linked memory processes are facilitated by A-Ghr in the rat ABL. It is a specific effect, because it could be eliminated by ANT pretreatment.

Effects of substance P microinjections into the globus pallidus and central nucleus of amygdala on passive avoidance learning in rats

Substance P (SP) has been implicated in learning and memory processes. This peptide facilitated learning when injected peripherally or directly into the ventral pallidum. SP has high affinity for neurokinin-1 (NK-1) receptors. WIN51,708 is a potent NK-1 receptor antagonist that can inhibit the physiological effects of SP. Immunohistochemical experiments showed that the globus pallidus (GP) and the amygdaloid (AMY) body are rich in SP immunoreactive elements. Pallidal lesions cause learning deficits in active and passive avoidance paradigms. Serious memory deficits develop after lesions of AMY and its role in conditioned fear has been suggested. The aim of our study was to examine whether the SP microinjected into the GP or central nucleus of AMY (ACE) can modify negative reinforcement. Male Wistar rats were conditioned in a passive avoidance situation. Animals were microinjected with 0.4 microl of 10 ng SP, 100 ng SP or vehicle solution into the GP or the ACE. Results showed that 10 ng SP significantly enhanced passive avoidance learning in both structures, while 100 ng SP was ineffective. Retention examined 1 week later was diminished in the GP and still significant in the ACE. The possible involvement o NK-1 receptors in the effects of SP microinjected into the ACE was also studied. Prior treatment with WIN51,708 could block the SP effects on passive avoidance paradigm. Our results are the first to demonstrate that SP plays important roles, though in different ways, in learning and memory processes related to the GP and AMY.

The role of neurotensin in passive avoidance learning in the rat central nucleus of amygdala

Tridecapeptide neurotensin (NT) acts as a neurotransmitter and/or neuromodulator and plays a role in learning and reinforcement. The central nucleus of amygdala (CeA), which is relatively rich in NT and neurotensin-1 receptors (NTS1), participates in the regulation of memory and learning mechanisms. The aim of this study was to examine the possible effect of NT and NTS1 antagonist (ANT) on passive avoidance learning after their microinjection into the CeA of male wistar rats. NT significantly increased the latency time. Effect of NT was blocked by ANT pretreatment. ANT in itself had no effect. Our results show that in the rat CeA NT facilitates passive avoidance learning via NTS1.

Effects of neurotensin in amygdaloid spatial learning mechanisms

Neurotensin (NT) acts as a neurotransmitter and/or neuromodulator and plays a role in learning and reward related processes. The central nucleus of amygdala (CeA) participates in the regulation of memory and learning mechanisms. In Morris water maze test, rats were microinjected with NT or neurotensin receptor-1 (NTS1) antagonist SR 48692 (ANT). NT significantly reduced the escape latency. Effect of NT was blocked by ANT pretreatment. Our results show that in the rat CeA NT facilitates spatial learning. We clarified that NTS1s are involved in this action.

Positive reinforcing effects of substance P in the rat central nucleus of amygdala

Substance P (SP) can have positive reinforcing or aversive properties, depending on the dose used and the site of action in the brain. Experimental findings suggest that the amygdala is involved in reward-related processes. The presence of SP-immunoreactive fibers and cell bodies has been shown in the central nucleus (ACE) and neurokinin (NK)-1 and NK-3 receptors also could be found there. The rewarding or aversive effects of SP in the ACE were tested in conditioned place preference paradigm. 10 ng SP microinjections had positive reinforcing properties, while 100 ng SP had no effect. Prior treatment with NK-1 receptor antagonist could block the rewarding effects of SP, while the antagonist on its own did not influence place preference. Our results show that SP and NK-1 receptors play important roles in amygdaloid rewarding-reinforcing mechanisms.

The role of neurotensin in positive reinforcement in the rat central nucleus of amygdala.

In the central nervous system neurotensin (NT) acts as a neurotransmitter and neuromodulator. It was shown that NT has positive reinforcing effects after its direct microinjection into the ventral tegmental area. The central nucleus of amygdala (CeA), part of the limbic system, plays an important role in learning, memory, regulation of feeding, anxiety and emotional behavior. By means of immunohistochemical and radioimmune methods it was shown that the amygdaloid body is relatively rich in NT immunoreactive elements and NT receptors. The aim of our study was to examine the possible effects of NT on reinforcement and anxiety in the CeA. In conditioned place preference test male Wistar rats were microinjected bilaterally with 100 or 250 ng NT in volume of 0.4 microl or 35 ng neurotensin receptor 1 (NTS1) antagonist SR 48692 alone, or NTS1 antagonist 15 min before 100 ng NT treatment. Hundred or 250 ng NT significantly increased the time rats spent in the treatment quadrant. Prior treatment with the non-peptide NTS1 antagonist blocked the effects of NT. Antagonist itself did not influence the reinforcing effect. In elevated plus maze test we did not find differences among the groups as far as the anxiety index (time spent on the open arms) was concerned. Our results suggest that in the rat ACE NT has positive reinforcing effects. We clarified that NTS1s are involved in this action. It was also shown that NT does not influence anxiety behavior.

Microinjection of RFRP-1 in the central nucleus of amygdala decreases food intake in the rat

Several members of the RFamide peptide family are known to have role in the regulation of feeding. For example, neuropeptide FF and prolactin-releasing peptide cause anorexigenic, while 26RFa and QRFP result in orexigenic effects in rodents. I.c.v. microinjection of neuropeptide RFRP-1 significantly reduced food and water intake in chicks. However, feeding related effects of RFRP-1 have not been studied in mammals yet. The central part of amygdala (CeA) is essentially involved in the regulation of feeding and body weight. RFRP-1 positive nerve cells were detected in the rat hypothalamus and RFRP-1 immunoreactive fibers were identified in the CeA. RFRP analogs bind with relatively high affinity to the NPFF1 and NPFF2 receptors (NPFF-R). RFRP-1 has potent activity for NPFF1. Significant expression of NPFF1 was detected in the CeA. To evaluate the role of RFRP-1 in feeding regulation rats were microinjected with different doses of RFRP-1 and their food intake were quantified over a 60min period. Liquid food intake of male Wistar rats was measured after bilateral intraamygdaloid administration of RFRP-1 (25, 50 or 100ng/side, RFRP-1 dissolved in 0.15M sterile NaCl/0.4μl, respectively). The 50ng dose of RFRP-1 microinjections resulted in significant decrease of food intake. The 25 and 100ng had no effect. Action of 50ng (37.8pmol) RFRP-1 was eliminated by 20ng (41.4pmol) RF9 NPFF-R antagonist pretreatment. In open-field test 50ng RFRP-1 did not modify spontaneous locomotor activity and general behavior of animals did not change. Our results are the first reporting that RFRP-1 injected to the CeA result in a decrease of liquid food consumption. This is a receptor-linked effect because it was eliminated by a NPFF-R selective antagonist.

Positive reinforcing effect of oxytocin microinjection in the rat central nucleus of amygdala

Neuropeptide oxytocin (OT) receives increasing attention since, it plays a role in various behaviors including anxiety, drug addiction, learning, social recognition, empathy, pair bonding and decreased aggression. The central nucleus of the amygdala (CeA), part of the limbic system, plays an important role in learning, memory, anxiety and reinforcing mechanisms. CeA was shown to be rich in OT-receptors (OTR). The aim of our study was to examine the possible effects of OT and OTR antagonist in the CeA on reinforcement using the conditioned place preference test and on anxiety using the elevated plus maze test. Male Wistar rats were microinjected bilaterally with 10 ng OT or 100 ng OT (Sigma: O6379, injected in volume of 0.4μl) or 10ng OTR antagonist (Sigma: L-2540) alone, or OTR antagonist 15 min prior 10 ng OT treatment or vehicle solution into the CeA. Rats receiving 10 ng OT spent significantly more time in the treatment quadrant during the test session, while 100 ng OT treatment produced no effect. Prior treatment with the non-peptide OTR antagonist blocked the effects of OT. The antagonist in itself did not influence the place preference. The elevated plus maze test revealed that 10 ng OT significantly increased the time spent in the open arms. OTR antagonist pre-treatment could inhibit this effect and the antagonist in itself did not affect the time spent in the open arms. Our results show that in the rat CeA OT has dose-dependent, positive reinforcing and anxiolytic effects, via OTR demonstrated by the blocking effects of selective OTR antagonist.

Effects of intraamygdaloid microinjections of acylated-ghrelin on liquid food intake of rats

Ghrelin (Ghr) has two main forms in the blood: the acylated (A-Ghr) and non-acylated (NA-Ghr) Ghr. A-Ghr was discovered as a potent growth hormone (GH) secretion increasing substance acting on GH secretagouge receptor (GHS-R) type 1a. A-Ghr facilitates food intake after its i.p., i.c.v. or direct hypothalamic application. Immunohistological assays identified projections of ghrelinergic neurons to the basolateral nucleus (ABL) of the amygdala (AMY). A-Ghr injected into the hypothalamus caused c-Fos overexpression in the AMY area that has an important role in food intake and body weight regulation. In separate experiments, liquid food intake of male wistar rats was measured after bilateral intraamygdalar or bilateral i.c.v. administration of A-Ghr (25, 50, 100, 250, and 500 ng/side or 500 and 1000 ng/side, A-Ghr dissolved in 0.15 M sterile NaCl/0.4 microl or 1 microl, respectively). In the ABL, A-Ghr microinjections in the 50-250 ng dose range resulted in significant decrease of food intake. The 25 and 500 ng had no effect. Action of 50 ng (14.83 pmol) or 100 ng (30.16 pmol) A-Ghr was eliminated by 15 ng (16.13 pmol) or 30 ng (32.25 pmol) GHS-R antagonist (D-Lys3-GHRP-6) pretreatment. The administration of 30 ng D-Lys3-GHRP-6 in itself had no influence on feeding. I.c.v. applied 1000 ng A-Ghr increased liquid food intake. Our results are the first ones reporting that A-Ghr injected into the ABL resulted in a decrease of liquid food consumption, within a limited dose range. This is a receptor-linked effect because it was eliminated by a GHS-R specific antagonist.