Carmen Pedraza

Updating Fearful Memories with Extinction Training during Reconsolidation: A Human Study Using Auditory Aversive Stimuli

Learning to fear danger in the environment is essential to survival, but dysregulation of the fear system is at the core of many anxiety disorders. As a consequence, a great interest has emerged in developing strategies for suppressing fear memories in maladaptive cases. Recent research has focused in the process of reconsolidation where memories become labile after being retrieved. In a behavioral manipulation, Schiller et al., (2010) reported that extinction training, administrated during memory reconsolidation, could erase fear responses. The implications of this study are crucial for the possible treatment of anxiety disorders without the administration of drugs. However, attempts to replicate this effect by other groups have been so far unsuccessful. We sought out to reproduce Schiller et al., (2010) findings in a different fear conditioning paradigm based on auditory aversive stimuli instead of electric shock. Following a within-subject design, participants were conditioned to two different sounds and skin conductance response (SCR) was recorded as a measure of fear. Our results demonstrated that only the conditioned stimulus that was reminded 10 minutes before extinction training did not reinstate a fear response after a reminder trial consisting of the presentation of the unconditioned stimuli. For the first time, we replicated Schiller et al., (2010) behavioral manipulation and extended it to an auditory fear conditioning paradigm.

Behavioral phenotype of maLPA1‐null mice: increased anxiety‐like behavior and spatial memory deficits

Lysophosphatidic acid (LPA) has emerged as a new regulatory molecule in the brain. Recently, some studies have shown a role for this molecule and its LPA1 receptor in the regulation of plasticity and neurogenesis in the adult brain. However, no systematic studies have been conducted to investigate whether the LPA1 receptor is involved in behavior. In this study, we studied the phenotype of maLPA1‐null mice, which bear a targeted deletion at the lpa1 locus, in a battery of tests examining neurologic performance, habituation in exploratory behavior in response to low and mild anxiety environments and spatial memory. MaLPA1‐null mutants showed deficits in both olfaction and somesthesis, but not in retinal or auditory functions. Sensorimotor co‐ordination was impaired only in the equilibrium and grasping reflexes. The mice also showed impairments in neuromuscular strength and analgesic response. No additional differences were observed in the rest of the tests used to study sensoriomotor orientation, limb reflexes and co‐ordinated limb use. At behavioral level, maLPA1‐null mice showed an impaired exploration in the open field and increased anxiety‐like response when exposed to the elevated plus maze. Furthermore, the mice exhibit impaired spatial memory retention and reduced use of spatial strategies in the Morris water maze. We propose that the LPA1 receptor may play a major role in both spatial memory and response to anxiety‐like conditions.

Aggravation of Chronic Stress Effects on Hippocampal Neurogenesis and Spatial Memory in LPA1 Receptor Knockout Mice

Background The lysophosphatidic acid LPA1 receptor regulates plasticity and neurogenesis in the adult hippocampus. Here, we studied whether absence of the LPA1 receptor modulated the detrimental effects of chronic stress on hippocampal neurogenesis and spatial memory. Methodology/Principal Findings Male LPA1-null (NULL) and wild-type (WT) mice were assigned to control or chronic stress conditions (21 days of restraint, 3 h/day). Immunohistochemistry for bromodeoxyuridine and endogenous markers was performed to examine hippocampal cell proliferation, survival, number and maturation of young neurons, hippocampal structure and apoptosis in the hippocampus. Corticosterone levels were measured in another a separate cohort of mice. Finally, the hole-board test assessed spatial reference and working memory. Under control conditions, NULL mice showed reduced cell proliferation, a defective population of young neurons, reduced hippocampal volume and moderate spatial memory deficits. However, the primary result is that chronic stress impaired hippocampal neurogenesis in NULLs more severely than in WT mice in terms of cell proliferation; apoptosis; the number and maturation of young neurons; and both the volume and neuronal density in the granular zone. Only stressed NULLs presented hypocortisolemia. Moreover, a dramatic deficit in spatial reference memory consolidation was observed in chronically stressed NULL mice, which was in contrast to the minor effect observed in stressed WT mice. Conclusions/Significance These results reveal that the absence of the LPA1 receptor aggravates the chronic stress-induced impairment to hippocampal neurogenesis and its dependent functions. Thus, modulation of the LPA1 receptor pathway may be of interest with respect to the treatment of stress-induced hippocampal pathology.

When is adult hippocampal neurogenesis necessary for learning? Evidence from animal research

Abstract The hippocampus is a key brain structure involved in the short- and long-term processing of declarative memory. Since adult hippocampal neurogenesis was first found, numerous studies have tried to establish the contribution of newborn neurons to hippocampus-dependent cognitive functions. However, this large amount of research has generated contradictory results. In this paper, we review the body of evidence investigating the relationship between hippocampal neurogenesis and learning to conclude the functional role of adult-born hippocampal neurons. First, factors that could explain discrepancies among experiments are taken into account. Then, in addition to methodological differences, we emphasize the importance of the age of the newborn neurons studied, as to how their maturation influences both their properties and potential functionality. Next, we discuss which declarative memory components could require involvement of adult hippocampal neurogenesis, taking into consideration the representational demands of the task, its difficulty and the level of performance reached by the subject. Finally, other factors that could modulate neurogenesis and memory, such as stress levels or previous experience of the animal, should also be taken into consideration in interpreting experiments focused on neurogenesis. In conclusion, our analysis of published studies suggests that new adult-born neurons, under certain circumstances, have a crucial and irreplaceable role in hippocampal learning.

Hippocampal c-Fos activation in normal and LPA1-null mice after two object recognition tasks with different memory demands

Normal and LPA₁-null mice, that have well reported hippocampal deficits, were assessed in an episodic-like what-when-where memory task or in a comparable task designed to test memory for familiar objects and locations by discriminating them from novels. Both genotypes performed the novelty recognition task but failed to learn the what-when-where task. However, normal mice showed what-when memory that was impaired in nulls. Each task elicited a different pattern of c-Fos expression. In normal mice, the what-when-where task induced more hippocampal c-Fos activation in the CA1 area than the novelty-based task, correlating with the what-when memory. LPA₁-null mice displayed a basal c-Fos hyperactivity in the hippocampus and in the medial prefrontal cortex, which was regulated differently by the two behavioural tasks employed. Both tasks were matched in exploratory behaviour and c-Fos activation in stress-related brain areas for both genotypes. This study shows that the what-when-where memory task differs from a comparable novelty-based task in both the learning demands and the neuronal correlates. Moreover, results also stress the role of the LPA₁ receptor in hippocampal functioning.

Evidence for sexual difference in astrocytes of adult rat hippocampus

We quantified the number of glial fibrillary acidic protein immunoreactive (GFAP-IR) astrocytes in the CA1 and CA3 areas of the adult rat hippocampus. The dorsal and ventral regions of the hippocampus were taken into account to estimate the GFAP-IR cells using unbiased stereological techniques. Males had a higher number of GFAP-IR astrocytes in the CA3 area, whereas females had more in the CA1 area. No sex difference was found between dorsal and ventral regions, although most GFAP-IR astrocytes were located in the dorsal hippocampus.

Fear extinction and acute stress reactivity reveal a role of LPA(1) receptor in regulating emotional-like behaviors.

LPA1 receptor is one of the six characterized G protein-coupled receptors (LPA1–6) through which lysophosphatidic acid acts as an intercellular signaling molecule. It has been proposed that this receptor has a role in controlling anxiety-like behaviors and in the detrimental consequences of stress. Here, we sought to establish the involvement of the LPA1 receptor in emotional regulation. To this end, we examined fear extinction in LPA1-null mice, wild-type and LPA1 antagonist-treated animals. In LPA1-null mice we also characterized the morphology and GABAergic properties of the amygdala and the medial prefrontal cortex. Furthermore, the expression of c-Fos protein in the amygdala and the medial prefrontal cortex, and the corticosterone response following acute stress were examined in both genotypes. Our data indicated that the absence of the LPA1 receptor significantly inhibited fear extinction. Treatment of wild-type mice with the LPA1 antagonist Ki16425 mimicked the behavioral phenotype of LPA1-null mice, revealing that the LPA1 receptor was involved in extinction. Immunohistochemistry studies revealed a reduction in the number of neurons, GABA+ cells, calcium-binding proteins and the volume of the amygdala in LPA1-null mice. Following acute stress, LPA1-null mice showed increased corticosterone and c-Fos expression in the amygdala. In conclusion, LPA1 receptor is involved in emotional behaviors and in the anatomical integrity of the corticolimbic circuit, the deregulation of which may be a susceptibility factor for anxiety disorders and a potential therapeutic target for the treatment of these diseases.

Chronic immobilization in the malpar1 knockout mice increases oxidative stress in the hippocampus.

ABSTRACT The lysophosphatidic acid LPA1 receptor has recently been involved in the adaptation of the hippocampus to chronic stress. The absence of LPA1 receptor aggravates the chronic stress-induced impairment of both hippocampal neurogenesis and apoptosis that were accompanied with hippocampus-dependent memory deficits. Apoptotic death and neurogenesis in the hippocampus are regulated by oxidative stress. In the present work, we studied the involvement of LPA1 receptor signaling pathway in the regulation of the hippocampal redox after chronic stress. To this end, we used malpar1 knockout (KO) and wild-type mice assigned to either chronic stress (21 days of restraint, 3 h/day) or control conditions. Lipid peroxidation, the activity of the antioxidant enzymes catalase (CAT), superoxide dismutase (SOD), and glutathione peroxidase (GPX), as well as mitochondrial function stimulation, monitored through the activity of cytochrome c oxidase (COX), were studied in the hippocampus. Our results showed that chronic immobilization stress enhanced lipid peroxidation as well as the activity of the antioxidant enzymes studied (CAT, SOD, and GPX). This effect was only observed in absence of LPA1 receptor. Furthermore, only malpar1 KO mice submitted to chronic stress exhibited a severe downregulation of the COX activity, suggesting the presence of mitochondrial damage. Altogether, these results suggest that malpar1 KO mice display enhanced oxidative stress in the hippocampus after chronic stress. This may be involved in the hippocampal abnormalities observed in this genotype after chronic immobilization, including memory, neurogenesis, and apoptosis.

TIAPRIDE-INDUCED CATALEPSY IS POTENTIATED BY GAMMA-HYDROXYBUTYRIC ACID ADMINISTRATION

1. The effect of administration of gammahydroxybutyrate (GHB) and tiapride, either alone or in combination, on catalepsy behavior was examined in male mice. 2. Catalepsy was measured by bar and grid tests. Two successive evaluations were carried out 30 and 60 min after injections. 3. Tiapride (175 and 200 mg/kg) and gammahydroxybutyrate (200 mg/kg) provoked an increase of catalepsy scores, exhibiting different time courses. GHB produced a marked but short lasting catalepsy with a peak of action at 30 min, while tiapride produced a catalepsy state with a peak of action at 60 min. 4. Tiapride-induced catalepsy was potentiated by gammahydroxybutyrate administration at 30 min (bar test) and 60 min (bar and grid tests). 5. These results underlie the view that GHB interacts with central dopamine D2 transmission.

1-Oleoyl Lysophosphatidic Acid: A New Mediator of Emotional Behavior in Rats

The role of lysophosphatidic acid (LPA) in the control of emotional behavior remains to be determined. We analyzed the effects of the central administration of 1-oleoyl-LPA (LPA 18∶1) in rats tested for food consumption and anxiety-like and depression-like behaviors. For this purpose, the elevated plus-maze, open field, Y maze, forced swimming and food intake tests were performed. In addition, c-Fos expression in the dorsal periaqueductal gray matter (DPAG) was also determined. The results revealed that the administration of LPA 18∶1 reduced the time in the open arms of the elevated plus-maze and induced hypolocomotion in the open field, suggesting an anxiogenic-like phenotype. Interestingly, these effects were present following LPA 18∶1 infusion under conditions of novelty but not under habituation conditions. In the forced swimming test, the administration of LPA 18∶1 dose-dependently increased depression-like behavior, as evaluated according to immobility time. LPA treatment induced no effects on feeding. However, the immunohistochemical analysis revealed that LPA 18∶1 increased c-Fos expression in the DPAG. The abundant expression of the LPA1 receptor, one of the main targets for LPA 18∶1, was detected in this brain area, which participates in the control of emotional behavior, using immunocytochemistry. These findings indicate that LPA is a relevant transmitter potentially involved in normal and pathological emotional responses, including anxiety and depression.