Inhibition of cerebral protein synthesis: performance at different times after passive avoidance training.

Inhibition of cerebral protein synthesis impairs long-term memory in a variety of species and tasks. Recently it was reported that subcutaneous injection of the protein synthesis inhibitor cycloheximide impaired short-term retention, measured 10 min after training in a passive avoidance task. To examine the possibility that inhibition of cerebral protein synthesis may sometimes disrupt short-term memory, mice were injected subcutaneously with cycloheximide (120 mg/kg) or anisomycin (150 mg/kg), or bitemporally with cycloheximide or anisomycin (100 mug/side) and given one training trial in a passive avoidance box. Subcutaneously injected cycloheximide reduced step-through latencies 10 min after training as reported previously, but anisomycin or bitemporally injected cycloheximide did not. All 4 drug groups exhibited impaired long-term memory. Since the results obtained at short intervals after training varied depending on the drug and route of injection, the impairment produced by subcutaneous cycloheximide at 10 min after training cannot be attributed to inhibition of cerebral protein synthesis. It is suggested that performance at short intervals after training reflects drug side effects on step-through behavior. By contrast, the impairment obtained at long intervals after training is consistent with the hypothesis that cerebral protein synthesis is required for formation of long-term memory.     

Application of a protein synthesis inhibitor into the ventral tegmental area,but not the nucleus accumbens,prevents behavioral sensitization to cocaine

Recent evidence implicates a crucial role for the ventral tegmental area (VTA) in the initiation of behavioral sensitization produced by repeated psychostimulant exposure, while changes in the nucleus accumbens (NAcc) are not critical during the initiation stage. We investigated whether the development of behavioral sensitization to repeated daily cocaine could be prevented by daily administration of the protein synthesis inhibitor, anisomycin, delivered onto VTA neurons. Rats were given five daily treatments as follows: obturators containing crystalline anisomycin or no compound (sham) were placed directly into the VTA 15 min prior to a saline (1 ml/kg, i.p.) or cocaine (15 mg/kg, i.p.) injection. After withdrawal for 8–9 days, the locomotor response to the same dose of saline or cocaine was monitored. No differences in the locomotor response to an acute saline challenge were found across the four groups. Animals given sham treatments in the VTA and daily cocaine demonstrated a significant augmentation in the locomotor response to a cocaine challenge compared to saline controls. Anisomycin treatments alone produced no effects on acute cocaine-induced locomotion. Further, a cocaine challenge in animals receiving daily anisomycin and cocaine elicited a non-augmented response similar to that of saline controls. Thus, the sensitized locomotor response to a cocaine challenge in daily cocaine pretreated animals was completely blocked by daily anisomycin treatment in the VTA. When daily anisomycin was administered into the NAcc along with daily cocaine, no blockade of behavioral sensitization was observed. These results provide support for a critical role of long-term changes in gene expression in the vicinity of VTA neurons mediating the development of sensitization to psychostimulants. © 1995 Wiley-Liss, Inc.     

Fever evoked by macrophage inflammatory protein-1 (MIP-1) injected into preoptic or ventral septal area of rats depends on intermediary protein synthesis

Macrophage inflammatory protein-1 (MIP-1), a novel cytokine composed of α/β subunits, is released from macrophages during infection, MIP-1 injected intravenously in the rabbit or into the anterior hypothalamic, preoptic area (AH/POA) of the rat causes an intense fever, which is not blocked by prostaglandin synthesis inhibitors, ibuprofin or indomethacin, respectively. The purpose of this study was to determine the role of de novo protein synthesis on the fever evoked by MIP-1 applied to thermosensitive cells of the AH/POA. Guide cannulae were implanted bilaterally above the AH/POA or ventral septal area (VSA) and medially above the third cerebral ventricle in each of 11 male Sprague-Dawley rats. Following postoperative recovery, body temperature (T_b) was monitored by a colonic thermistor probe. The bilateral microinjection of MIP-1 in a dose of 14 pg per 0.5 μ1 into the AH/POA caused a biphasic elevation in T_b to 0.9 ± 0.2 °C within 3.0 h, and persisted for over 6.0 h. An identical injection of MIP-1 into the VSA increased T_b biphasically to 0.1 ± 0.1 °C within 1.0 h and to 0.8 ± 0.3 °C within 3.0 h. The infusion into the third ventricle of 80 μg/10 μ1 of the inhibitor of protein synthesis, anisomycin, either 10 or 30 min before the microinjection of MIP-1 into the AH/POA, attenuated significantly the rise in T_b for 1.0 to 3.0 h or 2.5 to 3.0 h, respectively. These results coincide with the earlier finding that anisomycin inhibits both endotoxin- and IL-1β-induced fevers. Further, the synthesis of a new protein factor may be required functionally for the initiation and maintenance of a fever whose mechanism of induction apparently is metabolically independent of the cyclooxygenase pathway.     

Cue-induced alcohol-seeking behaviour is reduced by disrupting the reconsolidation of alcohol-related memories

Rationale  In humans, the retrieval of memories associated with an alcohol-related experience frequently evokes alcohol-seeking behaviour. The reconsolidation hypothesis states that a consolidated memory could again become labile and susceptible to disruption after memory retrieval. Objectives  The aim of our study was to examine whether retrieval of alcohol-related memories undergoes a reconsolidation process. Methods  For this purpose, male Wistar rats were trained to self-administer ethanol in the presence of specific conditioned stimuli. Thereafter, animals were left undisturbed in their home cages for the following 21 days. Memory retrieval was performed in a single 5-min exposure to all alcohol-associated stimuli. The protein synthesis inhibitor anisomycin, the non-competitive N-methyl-d-aspartate (NMDA) receptor antagonist MK-801 and acamprosate, a clinically used drug known to reduce a hyper-glutamatergic state, were given immediately after retrieval of alcohol-related memories. The impact of drug treatment on cue-induced alcohol-seeking behaviour was measured on the following day and 7 days later. Results  Administration of both anisomycin and MK-801 reduced cue-induced alcohol-seeking behaviour, showing that memory reconsolidation was disrupted by these compounds. However, acamprosate had no effect on the reconsolidation process, suggesting that this process is not dependent on a hyper-glutamatergic state but is more related to protein synthesis and NMDA receptor activity. Conclusions  Pharmacological disruption of reconsolidation of alcohol-associated memories can be achieved by the use of NMDA antagonists and protein synthesis inhibitors and may thus provide a potential new therapeutic strategy for the prevention of relapse in alcohol addiction. C. von der Goltz and V. Vengeliene contributed equally to this work.     

Characteristics of retrograde amnesia following reactivation of memory in mice

Amnesia for approach-avoidance learning was induced in mice by injecting the protein synthesis inhibitor anisomycin (ANI) immediately, 1, or 2 hours, but not 3 hours after training. A robust amnesia could be demonstrated if ANI was administered 3 hours after training, immediately following a 60 second exposure to the training apparatus or to a structurally similar environment. The temporal gradient of effectiveness of amnesia production by ANI was significantly steeper following reactivation treatment than it was following initial training. In addition, while amnesia produced by the conventional procedure remained stable for 6 days, the amnesia induced following reactivation treatment spontaneously recovered 4 days after training. These findings are discussed in terms of their relevance to interpretations of retrograde amnesia studies.     

Effects of acetoxycycloheximide and anisomycin on approach and escape responses to hypothalamic stimulation

The effects of acetoxycycloheximide (AXM) (7 mg/kg) and anisomycin (ANI) (25 and 150 mg/kg) on approach and escape responses induced by hypothalamic stimulation were studied in a situation in which male Swiss mice could initiate a continuous brain stimulation train by pressing a lever at one end of a box (ON-lever) and terminate this stimulation train by pressing a lever at the other end of the box (OFF-lever). AXM and ANI induced a large decrease in ON-OFF responses regardless of the level of stimulation presented (a low level just above the stimulation threshold and a high level which was twice the low level). Correspondingly, a significant increase was observed in the mean time during which animals remained unstimulated (NST) whereas mean time during which animals remained stimulated (ST) increased only slightly. The relative NST increase after treatment was always greater than the relative ST increase either at sites where before treatment NST was greater than ST or at sites where NST was shorter than ST. However, the animals in this latter electrode placement group (ST greater than NST) continued to shuttle and to make lever-pressing responses on the ON-lever, whereas the animals in the other placement group (ST less than NST) did not. These results are discussed in terms of possible interactions between disruptions of reinforcing systems induced by protein inhibitors and their effects on memory.     

Protein synthesis inhibition and memory for pole jump active avoidance and extinction

This study utilizes a pole jump active avoidance task to investigate the effects of protein synthesis on memory formation. An extinction training procedure for this task is also described. Amnesia for extinction is produced by inhibition of protein synthesis and is also demonstrated by active responding, so it is clear that there is no general impairment sufficient to disrupt motor skill, motivation, or retrieval of stored memories. It was found that while inhibition of protein synthesis in brain for 2 hr did not produce amnesia, inhibition for 6 to 8 hr did. These results demonstrate that for both shock-motivated learning and non-shock motivated extinction learning, the duration of inhibition of protein synthesis is important in determining whether amnesia occurs. We conclude that inhibition of cerebral protein synthesis can best account for amnesia induced by anisomycin, cycloheximide, and acetoxycycloheximide.     

Recovery as a function of the degree of amnesia due to protein synthesis inhibition

Retrograde amnesia following inhibition of cerebral protein synthesis has generally been explained as either a failure of consolidation or impairment of a retrieval mechanism. Major evidence for the retrieval hypothesis is provided by studies which utilize a reminder (usually footshock) to attenuate the effect of the protein inhibitor. To examine this question, mice were injected subcutaneously with anisomycin (1 mg/animal, 7 mg/animal, or 1 mg/animal every 2 hr x 7) and given one training trial in a passive avoidance box. All animals received a single retention test on each of four consecutive days, starting either 1, 7, or 21 days after training. One-half of the mice in each group received a footshock reminder 1 hr after their initial test. The footshock reminder did not attenuate the inhibitor-induced amnesia, but multiple testing did produce partial recovery in animals demonstrating some memory of training (both Saline and Anisomycin animals). Animals injected with anisomycin whose testing began 1 day after training demonstrated partial recovery irrespective of drug dosage level. The extent of amnesia and recovery were dependent upon both drug dosage and training-test interval. Implications for the consolidation and retrieval hypotheses are discussed.     

Effects of protein synthesis inhibition on memory for active avoidance training.

Inhibition of brain protein synthesis by anisomycin and acetoxycycloheximide was studied in mice for its biochemical and behavioral effects. By employing both drugs in low doses in a series of injections, we were able to maintain inhibition of protein synthesis of 80% or greater for up to 14 hr without causing detectable permanent physiological impairment. The drugs were employed as amnestic agents in mice trained to avoid footshock in a T-maze. As the duration of inhibition increased, the percentage of mice classed as amnesic increased. This amnesia could be reduced by increasing (a) the rate of acquisition, or (b) the number of training trials. Anisomycin was shown to cause a significant degree of amnesia for the escape component as well as the avoidance component of the learning. A single injection of anisomycin given 15 min prior to training did not cause significant changes in the acquisition or retention of avoidance conditioning, when comparison was made with saline-injected controls. Only additional injections given after training to prolong inhibition caused amnesia. Thus, those injections critical in obtaining amnesia were given at a time at which interference with acquisition could not have occurred, so the results bear clearly on memory processes.     

Anisomycin activates p38 MAP kinase to induce LTD in mouse primary visual cortex

Anisomycin is both a well-established protein synthesis inhibitor and a potent activator of the p38/JNK MAPK pathway. It has been used to block the late phase of long-term potentiation (LTP) and long-term depression (LTD) in hippocampus. In this study, we have found that anisomycin produces a time-dependent decline in the magnitude of the field EPSP (fEPSP) in acute brain slices of mouse primary visual cortex. This anisomycin-mediated fEPSP depression occludes NMDA receptor-dependent LTD induced by low-frequency stimulation (LFS). In contrast, two other protein synthesis inhibitors, emetine and cycloheximide, have no effect either on baseline synaptic transmission or on LTD. Moreover, the decline of the fEPSP caused by anisomycin can be rescued by the application of the p38 inhibitor SB203580 but not by the JNK inhibitor SP600125. These results indicate that activation of p38 MAPK by anisomycin induces LTD and subsequently occludes electrically induced LTD. Also, the occlusion of LFS-LTD by anisomycin suggests that common mechanisms may be shared between the two forms of synaptic depression. Consistent with this view, bath application of a membrane permeant peptide derived from the carboxyl tail of GluR2 subunit of AMPA receptor, which specifically blocks regulated AMPA receptor endocytosis, thereby preventing the expression of LFS-induced LTD, significantly reduced the anisomycin-induced decline of the fEPSP. In conclusion, our results indicate that anisomycin produces long-lasting depression of AMPA receptor-mediated synaptic transmission by activating p38 MAPK-mediated endocytosis of APMA receptors in mouse primary visual cortex.