Dorsal striatum and the temporal expectancy of an aversive event in Pavlovian odor fear learning

Interval timing, the ability to encode and retrieve the memory of intervals from seconds to minutes, guides fundamental animal behaviors across the phylogenetic tree. In Pavlovian fear conditioning, an initially neutral stimulus (conditioned stimulus, CS) predicts the arrival of an aversive unconditioned stimulus (US, generally a mild foot-shock) at a fixed time interval. Although some studies showed that temporal relations between CS and US events are learned from the outset of conditioning, the question of the memory of time and its underlying neural network in fear conditioning is still poorly understood. The aim of the present study was to investigate the role of the dorsal striatum in timing intervals in odor fear conditioning in male rats. To assess the animal's interval timing ability in this paradigm, we used the respiratory frequency. This enabled us to detect the emergence of temporal patterns related to the odor-shock time interval from the early stage of learning, confirming that rats are able to encode the odor-shock time interval after few training trials. We carried out reversible inactivation of the dorsal striatum before the acquisition session and before a shift in the learned time interval, and measured the effects of this treatment on the temporal pattern of the respiratory rate. In addition, using intracerebral microdialysis, we monitored extracellular dopamine level in the dorsal striatum throughout odor-shock conditioning and in response to a shift of the odor-shock time interval. Contrary to our initial predictions based on the existing literature on interval timing, we found evidence suggesting that transient inactivation of the dorsal striatum may favor a more precocious buildup of the respiratory frequency's temporal pattern during the odor-shock interval in a manner that reflected the duration of the interval. Our data further suggest that the conditioning and the learning of a novel time interval were associated with a decrease in dopamine level in the dorsal striatum, but not in the nucleus accumbens. These findings prompt a reassessment of the role of the striatum and striatal dopamine in interval timing, at least when considering Pavlovian aversive conditioning.

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Threat imminence dictates the role of the bed nucleus of the stria terminalis in contextual fear

10.1101/696112 ◽

2019 ◽

Author(s):

Travis D. Goode ◽

Gillian M. Acca ◽

Stephen Maren

Keyword(s):

Unconditioned Stimulus ◽

Fear Conditioning ◽

Stria Terminalis ◽

Conditioning Procedure ◽

Conditioned Stimuli ◽

Reversible Inactivation ◽

Bed Nucleus ◽

Contextual Fear ◽

Context Dependent

ABSTRACTPrevious work indicates that the bed nucleus of the stria terminalis (BNST) is involved in defensive freezing to unpredictable Pavlovian conditioned stimuli (Goode et al., 2019). Here we show that the BNST mediates freezing to contexts paired with remote (unpredictable), but not imminent (predictable), footshock. Rats underwent a fear conditioning procedure in which a single footshock unconditioned stimulus (US) was delivered either 1 (imminent) or 9 minutes (remote) after placement in the context; each rat received a total of four conditioning trials over two days. Contexts associated with either imminent or remote USs produced distinct patterns of freezing and shock-induced activity but freezing in each case was context-dependent. Reversible inactivation of the BNST reduced the expression of contextual freezing in the context paired with remote, but not imminent, footshock. Implications of these data are discussed in light of recent conceptualizations of BNST function, as well as for anxiety behaviors.

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Respiration and brain neural dynamics associated with interval timing during odor fear learning in rats

10.1101/2020.07.31.228866 ◽

2020 ◽

Author(s):

Maryne Dupin ◽

Samuel Garcia ◽

Belkacem Messaoudi ◽

Valérie Doyère ◽

Anne-Marie Mouly

Keyword(s):

Fear Conditioning ◽

Basolateral Amygdala ◽

Piriform Cortex ◽

Respiratory Rhythm ◽

Interval Timing ◽

Fear Learning ◽

Gamma Activity ◽

Time Interval ◽

Scalar Property ◽

Learned Fear

ABSTRACTIn fear conditioning, where a conditioned stimulus predicts the arrival of an aversive stimulus, the animal encodes the time interval between the two stimuli. Freezing, the most used index to assess learned fear, lacks the temporal resolution required to investigate interval timing at the early stages of learning. Here we monitored respiration to visualize anticipatory behavioral responses in an odor fear conditioning in rats, while recording theta (5-15Hz) and gamma (40-80Hz) brain oscillatory activities in the medial prefrontal cortex (mPFC), basolateral amygdala (BLA), dorsomedial striatum (DMS) and olfactory piriform cortex (PIR). We investigated the temporal patterns of respiration frequency and of theta and gamma activity power during the odor-shock interval. We found that akin to respiration patterns, theta temporal curves were modulated by the duration of the odor-shock interval in the four recording sites, and respected scalar property in mPFC and DMS. In contrast, gamma temporal curves were modulated by the interval duration only in the mPFC, and in a manner that did not respect scalar property. This suggests a preferential role for theta rhythm in interval timing. In addition, our data bring the novel idea that the respiratory rhythm might take part in the setting of theta activity dynamics.

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Role of the hypophysis in erythropoietin production during hypoxia

Blood ◽

10.1182/blood.v51.6.1117.bloodjournal5161117 ◽

1978 ◽

Vol 51 (6) ◽

pp. 1117-1124

Author(s):

C Peschle ◽

IA Rappaport ◽

MC Magli ◽

G Marone ◽

F Lettieri ◽

...

Keyword(s):

Cell Mass ◽

Progressive Increase ◽

Male Rats ◽

Time Interval ◽

Rat Serum ◽

Hypoxic Conditions ◽

Erythropoietin Production ◽

Red Cell Mass ◽

Hypophysectomized Rats

Hypophysectomized or sham-operated male rats were exposed to hypoxia (0.42--0.40 or 0.37--0.35 atm for 6, 12, or 24 hr) applied 2 wk to 7 mo after surgery. Erythropoietin (Ep) levels in rat serum were evaluated on the basis of the exhypoxic polycythemic mouse assay. Ep activity evoked by hypoxia was significantly lower in hypophysectomized rats than in sham-operated controls. Progressive increase of the EP response to hypoxia correlated with extension of the time interval between hypophysectomy and hypoxia from 2 wk to 2--4 mo apparently mediated by the simultaneous inverse decline of red cell mass (RCM) values, i.e., of the “relative plethora” induced by a low O2 demand associated with relatively high RCM values. However, after 3--7 mo hypoxic Ep activity was still lower than in sham-operated controls. In these ablated animals the relative plethora became negligible or absent; accordingly, the Ep response apparently had reached plateau levels. These studies indicate that hypophysis (hypophyseal and target hormones, with the exception of estrogens) modulates Ep production under hypoxic conditions, possibly via a permissive enhancement of renal Ep activity.

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Temporal Behavior in Auditory Fear Conditioning: Stimulus Property Matters

International Journal of Comparative Psychology ◽

10.46867/ijcp.2015.28.02.04 ◽

2015 ◽

Vol 28 ◽

Author(s):

Julie Boulanger Bertolus ◽

Jeroen Knippenberg ◽

Anna Verschueren ◽

Pascale Le Blanc ◽

Bruce L. Brown ◽

...

Keyword(s):

Fear Conditioning ◽

Temporal Pattern ◽

Conditioning Stimulus ◽

Fixed Time ◽

Sensory Properties ◽

Time Interval ◽

Strong Impact ◽

Lever Pressing ◽

Conditioned Responses ◽

Neutral Tone

The accuracy of time judgments depends upon many factors, including the sensory properties of the to-be-timed stimulus. In auditory Pavlovian fear conditioning, an initially neutral tone (conditioned stimulus, CS) predicts the arrival of an aversive event (unconditioned stimulus, US) at a fixed time interval. The temporal relation between the CS and US events is encoded, leading to the development of a temporal pattern of responding. Little attention has been paid to the potential impact of the characteristics of the CS tone on the development of this temporal pattern. Here we compared the acquisition of the temporal pattern of conditioned responses of rats to different CS tone frequencies. Rats were first conditioned to lever press for food. Then, while lever pressing for food, they were presented with 60-s tones of two very different frequencies 1kHz or 11kHz, each paired with a foot-shock given 30s after tone onset. This fear conditioning led to the appearance of conditioned suppression of the lever pressing. On probe trials the tone duration was 60 s, and the reinforcer was omitted. With training, a pattern of suppression evolved during the probe trials, showing a maximum of suppression near the programmed time of the shock US, however the 11kHz CS tone yielded better temporal control than did the 1kHz tone. A second experiment investigated rats’ abilities to discriminate between two times of shock arrival (10s or 30s) predicted by the different tone frequencies (1kHz or 11kHz), In this experiment, rats showed poorer discriminative timing performance when the lower frequency (1kHz) was associated with the longer duration (30s). Our results suggest a strong impact of the CS sensory properties on the expression of temporal learning within the context of auditory fear conditioning in rats.

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Activation of VTA GABA Neurons Disrupts Reward Seeking by Altering Temporal Processing

10.1101/2020.08.18.256073 ◽

2020 ◽

Author(s):

Andrea K. Shields ◽

Mauricio Suarez ◽

Ken T. Wakabayashi ◽

Caroline E. Bass

Keyword(s):

Temporal Processing ◽

Interval Timing ◽

Gabaergic Neurons ◽

Male Rats ◽

Session Length ◽

Gaba Neurons ◽

Reward Seeking ◽

Perception Of Time ◽

Cue Processing

AbstractThe role of ventral tegmental area (VTA) dopamine in reward, cue processing, and interval timing is well characterized. Using a combinatorial viral approach to target activating DREADDs (Designer Receptors Exclusively Activated by Designer Drugs, hM3D) to GABAergic neurons in the VTA of male rats, we previously showed that activation disrupts responding to reward-predictive cues. Here we explored how VTA GABA neurons influence the perception of time in two fixed interval (FI) tasks, one where the reward or interval is not paired with predictive cues (Non-Cued FI), and another where the start of the FI is signaled by a constant tone that continues until the rewarded response is emitted (Cued FI). Under vehicle conditions in both tasks, responding was characterized by “scalloping” over the 30s FI, in which responding increased towards the end of the FI. However, when VTA GABA neurons were activated in the Non-Cued FI, the time between the end of the 30s interval and when the rats made a reinforced response increased. Additionally, post-reinforcement pauses and overall session length increased. In the Cued FI task, VTA GABA activation produced erratic responding, with a decrease in earned rewards. Thus, while both tasks were disrupted by VTA GABA activation, responding that is constrained by a cue was more sensitive to this manipulation, possibly due to convergent effects on timing and cue processing. Together these results demonstrate that VTA GABA activity disrupts the perception of interval timing, particularly when the timing is set by cues.

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Role of the hypophysis in erythropoietin production during hypoxia

Blood ◽

10.1182/blood.v51.6.1117.1117 ◽

1978 ◽

Vol 51 (6) ◽

pp. 1117-1124 ◽

Cited By ~ 20

Author(s):

C Peschle ◽

IA Rappaport ◽

MC Magli ◽

G Marone ◽

F Lettieri ◽

...

Keyword(s):

Cell Mass ◽

Progressive Increase ◽

Male Rats ◽

Time Interval ◽

Rat Serum ◽

Hypoxic Conditions ◽

Erythropoietin Production ◽

Red Cell Mass ◽

Hypophysectomized Rats

Abstract Hypophysectomized or sham-operated male rats were exposed to hypoxia (0.42--0.40 or 0.37--0.35 atm for 6, 12, or 24 hr) applied 2 wk to 7 mo after surgery. Erythropoietin (Ep) levels in rat serum were evaluated on the basis of the exhypoxic polycythemic mouse assay. Ep activity evoked by hypoxia was significantly lower in hypophysectomized rats than in sham-operated controls. Progressive increase of the EP response to hypoxia correlated with extension of the time interval between hypophysectomy and hypoxia from 2 wk to 2--4 mo apparently mediated by the simultaneous inverse decline of red cell mass (RCM) values, i.e., of the “relative plethora” induced by a low O2 demand associated with relatively high RCM values. However, after 3--7 mo hypoxic Ep activity was still lower than in sham-operated controls. In these ablated animals the relative plethora became negligible or absent; accordingly, the Ep response apparently had reached plateau levels. These studies indicate that hypophysis (hypophyseal and target hormones, with the exception of estrogens) modulates Ep production under hypoxic conditions, possibly via a permissive enhancement of renal Ep activity.

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Respiration and brain neural dynamics associated with interval timing during odor fear learning in rats

Scientific Reports ◽

10.1038/s41598-020-74741-2 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Maryne Dupin ◽

Samuel Garcia ◽

Belkacem Messaoudi ◽

Valérie Doyère ◽

Anne-Marie Mouly

Keyword(s):

Fear Conditioning ◽

Basolateral Amygdala ◽

Piriform Cortex ◽

Respiratory Rhythm ◽

Interval Timing ◽

Fear Learning ◽

Gamma Activity ◽

Time Interval ◽

The Novel ◽

Scalar Property

Abstract In fear conditioning, where a conditioned stimulus predicts the arrival of an aversive stimulus, the animal encodes the time interval between the two stimuli. Here we monitored respiration to visualize anticipatory behavioral responses in an odor fear conditioning in rats, while recording theta (5–15 Hz) and gamma (40–80 Hz) brain oscillatory activities in the medial prefrontal cortex (mPFC), basolateral amygdala (BLA), dorsomedial striatum (DMS) and olfactory piriform cortex (PIR). We investigated the temporal patterns of respiration frequency and of theta and gamma activity power during the odor-shock interval, comparing two interval durations. We found that akin to respiration patterns, theta temporal curves were modulated by the duration of the odor-shock interval in the four recording sites, and respected scalar property in mPFC and DMS. In contrast, gamma temporal curves were modulated by the interval duration only in the mPFC, and in a manner that did not respect scalar property. This suggests a preferential role for theta rhythm in interval timing. In addition, our data bring the novel idea that the respiratory rhythm might take part in the setting of theta activity dynamics related to timing.

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Communication between the mediodorsal thalamus and prelimbic cortex regulates timing performance in rats

10.1101/2021.06.18.449036 ◽

2021 ◽

Author(s):

Benjamin J De Corte ◽

Kelsey A Heslin ◽

Nathan Cremers ◽

John H Freeman ◽

Krystal L Parker

Keyword(s):

Decision Making ◽

Male Rats ◽

Time Interval ◽

Prelimbic Cortex ◽

Motivational Systems ◽

Starting Point ◽

Reciprocal Connections ◽

Future Events ◽

The Brain

Predicting when future events will occur and adjusting behavior accordingly is critical to adaptive behavior. Despite this, little is known about the brain networks that encode time and how this ultimately impacts decision-making. One established finding is that the prefrontal cortex (PFC) and its non-human analogues (e.g., the rodent prelimbic cortex; PL) mediate timing. This provides a starting point for exploring the networks that support temporal processing by identifying areas that interact with the PFC during timing tasks. For example, substantial work has explored the role of frontostriatal circuits in timing. However, other areas are undoubtedly involved. The mediodorsal nucleus of the thalamus (MD) is an excellent candidate region. It shares dense, reciprocal connections with PFC-areas in both humans and non-human species and is implicated in cognition. However, causal data implicating MD-PFC interactions in cognition broadly is still sparse, and their role in timing specifically is currently unknown. To address this, we trained male rats on a time-based, decision-making task referred to as the 'peak-interval' procedure. During the task, presentation of a cue instructed the rats to respond after a specific interval of time elapsed (e.g., tone-8 seconds). We incorporated two cues; each requiring a response after a distinct time-interval (e.g., tone-8 seconds / light-16 seconds). We tested the effects of either reversibly inactivating the MD or PL individually or functionally disconnecting them on performance. All manipulations caused a comparable timing deficit. Specifically, responses showed little organization in time, as if primarily guided by motivational systems. These data expand our understanding of the networks that support timing and suggest that MD-PL interactions specifically are a core component. More broadly, our results suggest that timing tasks provide a reliable assay for characterizing the role of MD-PL interactions in cognition using rodents, which has been difficult to establish in the past.

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Challenges of Fear Conditioning Research in the Age of RDoC

Zeitschrift für Psychologie ◽

10.1027/2151-2604/a000303 ◽

2017 ◽

Vol 225 (3) ◽

pp. 189-199 ◽

Cited By ~ 5

Author(s):

Tina B. Lonsdorf ◽

Jan Richter

Keyword(s):

Fear Conditioning ◽

Clinical Diagnosis ◽

Research Domain Criteria ◽

Major Focus ◽

The Future ◽

Definition Of ◽

Methodological Considerations ◽

Research Domain

Abstract. As the criticism of the definition of the phenotype (i.e., clinical diagnosis) represents the major focus of the Research Domain Criteria (RDoC) initiative, it is somewhat surprising that discussions have not yet focused more on specific conceptual and procedural considerations of the suggested RDoC constructs, sub-constructs, and associated paradigms. We argue that we need more precise thinking as well as a conceptual and methodological discussion of RDoC domains and constructs, their interrelationships as well as their experimental operationalization and nomenclature. The present work is intended to start such a debate using fear conditioning as an example. Thereby, we aim to provide thought-provoking impulses on the role of fear conditioning in the age of RDoC as well as conceptual and methodological considerations and suggestions to guide RDoC-based fear conditioning research in the future.

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