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The Journal of Neuroscience, January 2, 2008, 28(1):258-263; doi:10.1523/JNEUROSCI.4922-07.2008
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Brief Communications
The Magnocellular Mediodorsal Thalamus is Necessary for Memory Acquisition, But Not Retrieval
Anna S. Mitchell andDavid Gaffan Department of Experimental Psychology, Oxford University, Oxford OX1 3UD, United Kingdom
Abstract
Top
Abstract
Introduction
Damage to the magnocellular mediodorsal thalamic nucleus (MDmc) in the human brain is associated with both retrograde and anterograde amnesia. In the present study we made selective neurotoxic MDmc lesions in rhesus monkeys and compared the effects of these lesions on memory acquisition and retrieval. Monkeys learned 300 unique scene discriminations preoperatively and retention was assessed in a one-trial preoperative retrieval test. Bilateral neurotoxic lesions of the MDmc, produced by 10 x 1 µl injections of a mixture of ibotenate and NMDA did not affect performance in the postoperative one-trial retrieval test. In contrast, new postoperative learning of a further 100 novel scene discriminations was substantially impaired. Thus, MDmc is required for new learning of scene discriminations but not for their retention and retrieval. This finding is the first evidence that MDmc plays a specific role in memory acquisition.
Key words: mediodorsal thalamus; prefrontal cortex; retrograde amnesia; episodic memory; new learning; primate
Introduction
Damage to the medial diencephalon in the human brain is associated with both retrograde and anterograde amnesia. On the basis of human neuropathology it is difficult to determine what sites of damage are critical in the production of diencephalic amnesia, but some evidence indicates that the processes underlying retrograde and anterograde amnesia may be independent of each other. Kopelman et al. (1999, 2003)
Experimental verification of this hypothesis would not only clarify the neuropathological basis of diencephalic amnesia, but would also confirm whether the acquisition and retrieval of memories is performed by the same neural systems. Thus, we tested whether selective neurotoxic lesions of the MDmc in monkeys produce both retrograde and anterograde amnesia. Here, we report the first pure measurement of retrograde amnesia, uncontaminated by anterograde amnesia, after MDmc lesions in monkeys. Our test used the object-in-place scene discrimination problems that model the "what" and "where" aspects of episodic memory in monkeys (Gaffan, 1994
We taught 300 unique scene discriminations to each monkey preoperatively, and then tested memory for those scenes in a preoperative and a postoperative retrieval test with only one trial for each of the 300 scenes. Because this one-trial test cannot be contaminated by any effect of postoperative reacquisition, it is a pure measure of memory retention and retrieval. After this test of retrograde amnesia, we assessed anterograde amnesia with a test of new postoperative learning of scene discriminations, requiring new learning of a set of 100 scenes over several days.
Materials and Methods
Subjects. Eight naive rhesus monkeys (Macaca mulatta), all male, 5.52–8.34 kg (between 2 and 3 years old) at the beginning of behavioral training, participated in this study. Three monkeys (MD4, MD5, and MD6) formed the MDmc lesion group. Five monkeys (CON1, CON2, CON3, CON4, and CON5) were unoperated controls. All three monkeys in the MDmc group, and four of the monkeys in the control group, performed the preoperative acquisition, the preoperative and postoperative one-trial retrieval tests, and a test of postoperative acquisition. The remaining control monkey, CON4, performed the preoperative acquisition and the preoperative and postoperative one-trial retrieval tests, but for reasons unconnected with the present study was not available for the test of postoperative acquisition. The same 300 unique scene discriminations were used for all of the monkeys in preoperative training. All experimental procedures were performed in compliance with the United Kingdom Animals (Scientific Procedures) Act of 1986.Apparatus. The computer-controlled test apparatus was identical to that which has been described previously in detail by Mitchell et al., (2007a)
Scene discrimination learning. The scene discrimination learning task was adapted from Gaffan (1994)
Behavioral training. A detailed explanation of pretraining is provided by Mitchell et al., (2007a)
The 300 unique scene discriminations were divided into three sets (A, B, C) of 100 discriminations each with only one set presented per training day. The presentation order was consistent throughout each cycle of six training days: A, B, A, C, B, and A. In this way, set A was presented three times, set B twice, and set C once within every cycle. For the first and second cycles monkeys saw only the first 50 and then only the second 50 unique scene discriminations from each of the three sets, respectively. After these 12 d of training, further cycles began using all 100 unique scenes from each of the three sets until learning reached a criterion set at 85% or above across all three presentations of set A within one cycle of six training days. A touch to the correct foreground object caused the object to flash for 2 s then a reward pellet was delivered into the hopper and the screen went blank. A touch to the incorrect object caused the screen to blank immediately, no reward was given and an intertrial interval imposed for 10 s. A correction trial was then administered in which the scene was re-presented with only the correct object present. Touches anywhere else in the scene caused the screen to blank and the trial was repeated. When the monkey completed the final trial of a training day the lunchbox opened automatically, the monkey received the large food reward and was allowed time to eat before being returned to the home enclosure.
Experiment 1: one-trial preoperative and postoperative retrieval tests. After reaching the training criterion, monkeys were given a rest for 12 d. Then the preoperative retrieval test was conducted. The first day consisted of "familiarization"; monkeys saw 100 trials using a simpler version of the task, one random typographic character was presented against a black background and the monkeys had to touch the character to receive a reward. Responses to anywhere else on the screen immediately ended the trial and it was represented after a 10 s delay. This familiarization ensured that the monkeys had not altered their motivation as a consequence of the extended break from testing. On the second day, the monkeys were presented with set A using the same testing methods experienced during preoperative training then on the third day set B was presented and on the fourth day set C. These four consecutive days of testing constituted the one-trial preoperative retrieval test. Monkeys were then matched based on their performance and assigned to the MDmc lesion or unoperated control group. MDmc monkeys were scheduled for surgery and the others for an equivalent period of rest. After "postoperative" recovery of at least 12 d all monkeys were tested on the one-trial postoperative retrieval test, which was identical to the preoperative retrieval test.
Experiment 2: acquisition of 100 novel scene discriminations. Before acquisition training began on 100 novel scenes all monkeys completed 20 d of within-session new scene learning (data not presented here) using the standard scene learning task described by Gaffan (1994)
Surgery. A more detailed description of the surgical methods and preoperative and postoperative drug treatments is provided in Mitchell et al., (2007b)
The monkey was placed in a stereotaxic head holder. After opening the skin, underlying galea and creating a right-sided D-shaped bone flap, the dura over the posterior part of the right hemisphere was cut and retracted to the midline. The splenium of the corpus callosum was cut in the midline with a glass aspirator. The tela choroidea was cauterized in the midline posterior and dorsal to the thalamus using a metal aspirator that was insulated to the tip. A stereotaxic manipulator holding a 10 µl Hamilton syringe with a blunt tipped 26-gauge needle was positioned above the posterior commissure at the midline using the third ventricle as a guide. Neurotoxic bilateral lesions to the MDmc were produced by 10 x 1 µl injections of a mixture of ibotenic acid (10 mg/ml; Biosearch Technologies, Novato, CA) and NMDA (10 mg/ml; Tocris, Bristol, UK) dissolved in sterile 0.1 M PBS. The monkey brain atlas of Ilinsky and Kultas-Ilinsky (1987)
4 min before being moved to the next site. The needle was then repositioned for the second set of coordinates: AP, +4.2 mm; ML, ±1.5 mm; DV, –5.0 mm. The third, fourth, and fifth sets of coordinates were as follows: AP, +4.2 mm, ML, ±1.5 mm, and DV, –3.0 mm; AP, +3.4 mm, ML, ±1.7 mm, and DV, –4.0 mm; and AP, +3.4 mm, ML, ±1.7 mm, and DV, –3.0 mm, respectively. In each case the DV coordinate was relative to the surface of the thalamus at the injection site.
When the lesions were complete, the dura was repositioned but not sewn, the bone flap was replaced and held with loose sutures, and the skin and galea were closed in layers. The monkey was removed from the head-holder and anesthesia discontinued. Nonsteroidal anti-inflammatory analgesic and antibiotic treatment continued after surgery in consultation with veterinary staff, typically for 5 d.
Histology. After completion of all behavioral testing each monkey was sedated with ketamine (10 mg/kg), deeply anesthetized with intravenous barbiturate and transcardially perfused with 0.9% saline followed by 10% formalin. The brains were cryoprotected in formalin-sucrose and then sectioned coronally on a freezing microtome at 50 µm thickness. A one-in-five series of sections was collected throughout the thalamus; these were mounted on gelatin-coated glass microscope slides and stained with cresyl violet.
MDmc lesions. The three monkeys that formed the MDmc lesion group had extensive bilateral lesions in the magnocellular division of the mediodorsal thalamic nucleus as intended (Figs. 1, 2). These lesions also damaged midline thalamic nuclei, namely the paraventricular and central intermedialis nuclei lying between the MDmc in the two hemispheres of the thalamus. This unavoidable damage alone could not have caused the new learning deficits (Gaffan and Murray, 1990
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Figure 1. Schematic diagrams of six sections, 1 mm apart, through the medial thalamus of a monkey taken from Gaffan and Murray (1990)
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Figure 2. MDmc lesions. Photomicrographs of the MDmc lesions for MD4, MD5, and MD6 corresponding as closely as possible to normal medial thalamus (NORM) and the schematic diagrams of Figure 1 are shown. Arrows indicate the borders of each lesion.
Results
Monkeys destined to have bilateral neurotoxic lesions to MDmc or to remain as unoperated controls (CONs) did not differ in their ability to remember the scenes as measured by the total number of errors made in the preoperative one-trial retrieval test (Table 1). Monkeys with MDmc lesions, like the unoperated control monkeys, showed the same level of retention in the postoperative retrieval test as in the preoperative retrieval test. Thus, damage to the MDmc did not produce retrograde amnesia (Fig. 3, left). A 2 (group, control vs MDmc) x 2 (testing phase, preoperative vs postoperative) x 3 (set, three different sets of 100 scenes) repeated-measures ANOVA confirmed that there was no difference for lesion group or testing phase and no interaction of lesion group with any other factor (all F values < 1.0). There was only a significant difference for the retention levels of the three different sets (F(2,12) = 44.13, p < 0.001) that did not vary with lesion, reflecting the differing rates of training for the three sets of scenes during preoperative acquisition. Time spent completing the preoperative and postoperative one-trial retrieval tests did not differ for group, testing phase or set (F values < 1.0).
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Table 1. Preoperative and Postoperative Retention and New Learning
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Figure 3. Preoperative and postoperative retention (left). The mean number of total errors made during the preoperative and postoperative one-trial retrieval tests of set A (presented three times in every cycle of 6 d of training during initial acquisition), set B (presented twice), and set C (presented once). New learning is shown on the right. The total number of errors made to reach the criterion of 85% correct across three consecutive trials during postoperative acquisition of 100 novel unique scene discriminations (set D) for neurotoxic magnocellular MDmc and unoperated control (CON) monkeys is shown.
Despite preserved memory of preoperatively learned scenes in the one-trial retrieval test, the monkeys with bilateral neurotoxic lesions to the MDmc had severe impairments in new learning. The MDmc lesion group were impaired in acquisition of 100 novel unique scene discriminations (set D) presented for learning in the same way as the preoperative sets, with one trial per scene per day. Monkeys with MDmc lesions accumulated more errors (Fig. 3, right) to reach the retention criterion of 85% correct across three consecutive trials (mean, 396.33; SD, 160.45) than unoperated controls (mean, 198.75; SD, 82.94), (t(5) = 2.15, p = 0.042, one-tailed). The MDmc group also required more trials to reach criterion (mean, 13.67; SD, 4.73) compared with controls (mean, 7.00; SD, 2.71), (t(5) = 2.39, p < 0.031). Individual performance data for acquisition of set D are presented in Table 1.
Discussion
The present results demonstrate the dissociable contribution of the MDmc to memory acquisition and retrieval. Because the MDmc lesions only impaired new learning and not retention and retrieval, these data confirm the hypothesis that memory processes associated with retention and retrieval versus new learning involve differing interactions within the brain. Importantly, these results were produced using the same type of stimuli and testing conditions across the tests of retrieval and of new learning, and preoperatively monkeys destined to have MDmc lesions and unoperated controls did not differ in their acquisition rates of sets A, B, or C (see Table 1). Therefore, the impairment in new learning is not caused by other unrelated factors such as a perceptual, or other visual impairment, a lack of motivation, or an attentional deficit.As the current data indicate, the MDmc is not critical for memory retrieval. Thus, it would appear that retrograde amnesia suffered in clinical cases of diencephalic amnesia is not the result of damage to the MDmc (Kopelman et al., 2003
Although the MDmc is not critical for memory retrieval, the current data support the proposal that damage to the MDmc contributes to the anterograde amnesia suffered in clinical cases of diencephalic amnesia. We theorize that interactions between MDmc and prefrontal cortex, specifically, are important for new learning of information, but not for retrieval of previously acquired information. The MDmc has prominent interconnections with the ventral and medial prefrontal cortex (Walker's areas 11, 12, 13, and 14) (Giguere and Goldman-Rakic, 1988
Footnotes
Received Sept. 27, 2007; revised Nov. 28, 2007; accepted Nov. 29, 2007.This work was supported by the Medical Research Council, United Kingdom. We thank Dr. M. Baxter and Professor J. Aggleton for comments on a previous version of this manuscript, and M. Brown, P. Browning, G. Daubney, K. Murphy, and S. Mygdal for technical support.
Correspondence should be addressed to Dr. Anna S. Mitchell, Department of Experimental Psychology, Oxford University, South Parks Road, Oxford OX1 3UD, UK. Email: anna.mitchell{at}psy.ox.ac.uk
Copyright © 2008 Society for Neuroscience 0270-6474/08/280258-06$15.00/0
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