Neurochemical and behavioral effects of catecholamine and protein synthesis inhibitors in mice

The role of protein synthesis in memory consolidation: progress amid decades of debate

A major component of consolidation theory holds that protein synthesis is required to produce the synaptic modification needed for long-term memory storage. Protein synthesis inhibitors have played a pivotal role in the development of this theory. However, these commonly used drugs have unintended effects that have prompted some to reevaluate the role of protein synthesis in memory consolidation. Here we review the role of protein synthesis in memory formation as proposed by consolidation theory calling special attention to the controversy involving the non-specific effects of a group of protein synthesis inhibitors commonly used to study memory formation in vivo. We argue that molecular and genetic approaches that were subsequently applied to the problem of memory formation confirm the results of less selective pharmacological studies. Thus, to a certain extent, the debate over the role of protein synthesis in memory based on interpretational difficulties inherent to the use of protein synthesis inhibitors may be somewhat moot. We conclude by presenting avenues of research we believe will best provide answers to both long-standing and more recent questions facing field of learning and memory.

Behavioral training-induced c-Fos expression in the rat nucleus basalis of Meynert during aging

The present study investigated the behavioral training-induced c-Fos expression in the nucleus basalis of Meynert (nbM) in differently aged rats. This study demonstrated that the c-Fos expression in nbM was significantly increased and the peak occurred at 2 h after dark-avoidance training. Although the increase of c-Fos expression was also observed after pseudotraining, the number of Fos-like immunoreactive neurons in pseudotrained rats was significantly less than that in dark-avoidance trained rats at each time-point. This result suggested that c-Fos expression might be involved in learning and memory processes. In addition, all the pseudotraining-, training- and memory arousing-induced c-Fos expression was decreased with increasing age, and the decrease was more notable in trained and memory aroused rats. This suggested that the total number of nbM neurons and/or the sensitivity of nbM neurons to experimental manipulations, especially learning and memory performance, might reduce during aging.

Protective effect of cerulein on memory impairment induced by protein synthesis inhibitors in rats

Previous studies have demonstrated that NMDA receptor antagonists and protein kinase C inhibitors induced marked memory impairment in rats, but that peripherally administered cerulein (CER) prevented these effects. In the present study, the effect of subcutaneously administered CER on amnesia induced by protein synthesis inhibitors was examined in passive and active avoidance responses and in the Morris water maze test. Intraperitoneal injection of the inhibitors produced marked memory impairment, but the effect was abolished by combined administration with CER. The effective dose of subcutaneously injected CER was, on a molar basis, three thousand- and six thousandfold less than the dose of anisomycin, and two hundred eighty- and three thousandfold less than the dose of puromycin in the passive and active avoidance response experiments, respectively. Similarly, in the Morris water maze test, behavioral disturbances produced by the protein synthesis inhibitors were abolished by CER. These results indicate the effectiveness of CER in preventing memory impairment induced by protein synthesis inhibitors.

C-fos protooncogene expression in rat brain after long-term training of two-way active avoidance reaction

C-fos nuclear protooncogene encodes a regulatory protein (Fos), able to directly influence both expression of itself and other genes. It has been repeatedly shown that c-fos expression coincides with different forms of cell activation, probably being functionally involved in the coupling of extracellular ligands to long-term cellular responses. In this study it has been found that c-fos mRNA accumulation in rat brain, as measured by northern blotting coincides with increase of performance level of learned behavior of a two-way active avoidance task. We have previously reported (Nikolaev et al., Brain Res. Bull., in press) that a single training session of two-way active avoidance strongly induces c-fos mRNA accumulation but that after long-term training up to the asymptotic level of performance no c-fos expression was detectable. In this paper we show that c-fos still remains inducible even after long-term, asymptotic training to darkness as conditioned stimulus (CS), provided that a novel stimulus, wide band noise, which elevated performance level, was given together with darkness as compound CS.

Expression of c-fos and other genes encoding transcription factors in long-term potentiation

The genes encoding transcription factors are known to be induced in many different biological phenomena of transition from one long-lasting state of cell functioning to another. It is widely believed that transcription factors control this transition by regulating the expression of other genes. Recently, several reports on gene expression after the induction of long-term potentiation (LTP) have been published. In particular, the c-fos nuclear protooncogene, encoding the Fos transcription factor, has been extensively investigated. However, the results of those studies were seemingly contradictory. The present commentary reviews available data in an attempt to resolve the apparent contradictions, showing that long-lasting LTP (i.e., lasting longer than a few hours) may involve c-fos expression, while shorter LTP may not.

A threshold for the protective effect of over-reinforced passive avoidance against scopolamine-induced amnesia

Acetylcholine-receptor blockers produce amnesia of aversively motivated behaviors. However, when animals are submitted to relatively high intensities of footshock (over-reinforcement), anticholinergic treatment does not induce memory impairments. The aim of this work was to determine whether the antiamnesic effect produced by increasing the magnitude of the negative reinforcer is gradually established or if a threshold should be reached to obtain such an effect. Wistar rats were trained in passive avoidance using 2.5, 2.6, 2.7, 2.8, 2.9 or 3.0 mA; 5 min after training they were given one systemic injection of scopolamine (8 mg/kg). An amnesic state was produced in the groups that were trained with the lower intensities (2.5-2.7 mA); with the three higher intensities near-perfect retention was evident. These results suggest that acetylcholine is critically involved in memory consolidation, and that by increasing the magnitude of the negative reinforcer, a threshold is reached where cholinergic activity of the nervous system is not necessary for the development of the consolidation process.

Induction of expression of genes encoding transcription factors in the rat brain elicited by behavioral training

c-fos and zif/268 are regulatory genes encoding transcription factors able to influence gene expression directly. It has been shown repeatedly that expression of transcription factors correlates with different forms of cell activation, probably being functionally involved in the coupling of extracellular signals with long-term cellular responses. This study describes that c-fos and zif/268 mRNA accumulation, as measured by northern blot analysis, occurs in the rat hippocampus as well as the visual cortex following behavioral training of two-way active avoidance response.

Memory-enhancing effects in male mice of pregnenolone and steroids metabolically derived from it

Immediate post-training intracerebroventricular administration to male mice of pregnenolone (P), pregnenolone sulfate (PS), dehydroepiandrosterone (DHEA), dehydroepiandrosterone sulfate (DHEAS), androstenedione, testosterone, dihydrotestosterone, or aldosterone caused improvement of retention for footshock active avoidance training, while estrone, estradiol, progesterone, or 16 beta-bromoepiandrosterone did not. Dose-response curves were obtained for P, PS, DHEA, and testosterone. P and PS were the most potent, PS showing significant effects at 3.5 fmol per mouse. The active steroids did not show discernible structural features or known membrane or biochemical effects that correlated with their memory-enhancing capacity. The above, together with the findings that DHEA acted even when given at 1 hr after training and that P, PS, and DHEA improved retention over a much wider dose range than do excitatory memory enhancers, led to the suggestion that the effects of the active steroids converge at the facilitation of transcription of immediate-early genes. P and PS, for which receptors have not yet been demonstrated, may exert their effects by serving as precursors for the formation of a panoply of different steroids, ensuring near-optimal modulation of transcription of immediate-early genes required for achieving the plastic changes of memory processes. Low serum levels of P in aging and the increases of cancer and behavioral disorders in individuals receiving drugs that block synthesis of cholesterol, the immediate precursor of P, suggest possible clinical utility for P.

Learned immobility explains the behavior of rats in the forced swimming test

The rat forced-swimming test (FST) is widely used for screening substances with a potential antidepressant effect. The rat immobility shown in the FST has been interpreted as "behavioral despair" and has been suggested as an animal model of human depression. In the following series of experiments it is shown that measuring rat mobility by an automatic recording device is more accurate than measuring immobility time by direct observation (Experiment 1 and 5). The automatic recording procedure was tested with imipramine and mianserin showing similar results to those reported in the literature using a direct observation procedure by the researcher (Experiment 2). In Experiment 3 it was demonstrated that: (a) rat mobility decreased with experience, (b) switching water depth on Day 2 of the test increased mobility and (c) anisomycin acts as a false positive. In Experiment 4 the possible state dependent effect of imipramine in the FST was studied. The effect of imipramine on rat behavior in the FST is not state dependent. The imipramine-saline group shows greater mobility than the saline-saline group and does not differentiate from the imipramine-imipramine group. Thus, it was suggested that imipramine could interfere with the acquisition and/or consolidation processes. In Experiment 5, it is shown that a single dose of 25 mg/kg of imipramine, administered before or immediately after training on Day 1, increases rat's mobility on Day 2, thus suggesting that imipramine alters the consolidation process. From these results it is suggested that the behavioral process involved in the FST is "learning to be immobile" instead of "behavioral despair" as previously suggested in the literature.

The protein synthesis inhibitor, anisomycin, causes exacerbation of the iminodipropionitrile-induced spasmodic dyskinetic syndrome in rats

The effects of anisomycin on dyskinetic head movements, circling, and locomotor activity were investigated in the IDPN-induced syndrome. Intracerebroventricular (ICV) injections of anisomycin in conjunction with IDPN caused exacerbation of all aspects of the syndrome, although circling and vertical head dyskinesias (retrocollis) were the most affected. Animals treated with only anisomycin showed persistent retrocollis but not laterocollis or circling. Biochemical studies confirmed the increases in the concentration of serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) previously observed in the striata of IDPN-treated rats two weeks after stopping administration of the drug. Rats treated with anisomycin alone also showed significant increases in striatal 5-HT and 5-HIAA concentrations which were somewhat higher on the side of the ICV infusions. Coadministration of IDPN and anisomycin did not cause any further increases in 5-HT or 5-HIAA. These results suggest that inhibition of protein synthesis by IDPN may be one of the processes involved in the development of the persistent dyskinetic syndrome.

Orotate improves memory and enhances synaptic long-term potentiation in active avoidance behaviour in rats with perforant path stimulation as the conditioned stimulus

Male Wistar rats were trained in an active avoidance task with stimulation of the perforant path with impulse trains of 15 Hz as the conditioning stimulus. Immediately after the first training session, methylglucamine orotate (225 micrograms), a memory improving drug, was injected intraventricularly. The retention of the learned behaviour was determined on the following day in a relearning session. Field potentials evoked in the dentate area by test stimuli from the perforant path electrode were recorded at different times after learning and relearning sessions to determine whether there were functional changes in the perforant path-granular cell synapses, which are involved in the conditioning pathway. Untreated control animals exhibited a so-called 'postconditioning potentiation', expressed as a long-lasting increase of both the excitatory postsynaptic potential (EPSP) and the population spike of the granular cells of the evoked test potentials. This finding reproduces previously published results. Methylglucamine orotate-treated rats showed significantly more conditioned reactions in the relearning sessions compared with untreated controls and a significantly more pronounced potentiation of the population spike, whereas the postconditioning potentiation of the field EPSP remained unaffected by the treatment. When both the control animals and the methylglucamine orotate-treated rats were divided into subgroups of good and poor learners according to their learning scores from the first training session, differences between the effect of the drug became evident. In good learners, the treatment with methylglucamine orotate after the learning session slightly, but significantly, improved retention compared with that of untreated good learners.(ABSTRACT TRUNCATED AT 250 WORDS)

Anisomycin, an inhibitor of protein synthesis, blocks late phases of LTP phenomena in the hippocampal CA1 region in vitro

Long-term potentiation (LTP) with its extremely long duration has been frequently regarded as an elementary mechanism of information storage in the nervous system or at least as a suitable model for the study of mechanisms underlying functional plasticity and processes of learning and memory formation. Considering the necessity of an increased protein synthesis for memory consolidation and for the maintenance of LTP in granular synapses in vivo it was of interest to determine whether the LTP of the CA1 region of the hippocampus depends on protein synthesis as well. For the solution of this question anisomycin (ANI), a reversible blocker of protein synthesis, was used at a concentration of 20 microM, which blocked the [3H]leucine incorporation in hippocampal slices by at least 85%. It has been shown that in the CA1 region in vitro the maintenance of LTP (i.e. a late phase greater than 5 h) depends on an ongoing protein synthesis. A 3-h treatment with ANI immediately following multiple tetanization resulted in gradually developing loss of field excitatory postsynaptic potential (EPSP) and population spike (PS) potentiation (15 +/- 19% increase of the PS instead of the 96 +/- 14% increase in non-treated control experiments at the 8th h after tetanization). Furthermore, a late PS potentiation (greater than 6 h) of a second non-tetanized pathway to CA1 pyramidal cells has been observed (increase by 64 +/- 18% at the 8th h) for the first time. This potentiation was ANI-sensitive as well and suggests that the maintenance of LTP is dependent on a postsynaptic mechanism.