Repeated recall and PKMζ maintain fear memories in juvenile rats.

We examined the neural substrates of fear memory formation and maintenance when repeated recall was used to prevent forgetting in young animals. In contrast to adult rats, juveniles failed to show contextual fear responses at 4 d post-fear conditioning. Reconsolidation sessions 3 and 6 d after conditioning restored contextual fear responses in juveniles 7 d after initial training.

Medial prefrontal cortex processes threatening stimuli in juvenile rats.

To survive, all mammalian species must recognize and respond appropriately to threatening stimuli. In adults, the prelimbic medial prefrontal cortex (mPFC) appears to be involved in fear expression, whereas the infralimbic mPFC mediates fear extinction. In juvenile rats (PN26), the mPFC receives information on potential predators but does not act on it.

Norepinephrine mediates contextual fear learning and hippocampal pCREB in juvenile rats exposed to predator odor.

Predator odors induce unconditioned fear in the young animal and provide the opportunity to study the mechanisms underlying unlearned and learned fear. In the current study, cat odor produced unlearned, innate fear in infant (postnatal age 14; PN14) and juvenile (PN26) rats, but contextual fear learning occurred only in juveniles. It was hypothesized that contextual fear learning in juveniles is mediated by norepinephrine.

The role of the medial prefrontal cortex in innate fear regulation in infants, juveniles, and adolescents.

In adult animals, the medial prefrontal cortex (mPFC) plays a significant role in regulating emotions and projects to the amygdala and periaqueductal gray (PAG) to modulate emotional responses. However, little is known about the development of this neural circuit and its relevance to unlearned fear in pre-adulthood. To address these issues, we examined the mPFC of 14-d-old (infants), 26-d-old (juveniles), and 38- to 42-d-old (adolescents) rats to represent different developmental and social milestones.

Effects of the stimulus and chamber size on unlearned fear across development.

Predator odors have been found to induce unconditioned fear in adult animals and provide the opportunity to study the mechanisms underlying unlearned and learned fear. Predator threats change across an animal's lifetime, as do abilities that enable the animal to learn or engage in different defensive behaviors. Thus, the objective of this study was to determine the combination of factors that successfully induce unlearned fear to predator odor across development.

Plasticity of defensive behavior and fear in early development.

Animals have the ability to respond to threatening situations with sets of defensive behaviors. This review demonstrates that defensive behaviors change during early life in mammals. First, unlearned responses are reorganized during early ontogeny and expressed in an age-specific way.

Developing a framework for development: a discussion.

A multitude of scientific disciplines study the development of behavior. Their use of different methodological and conceptual approaches makes integration of findings difficult. In a symposium at the 38th Annual Meeting of the International Society for Developmental Psychobiology in Washington DC, the question was discussed if a general theory of development could unify the field.

Cortisol levels and hippocampus volumes in healthy preadolescent children.

Background: Research in animal models has demonstrated that elevated levels of glucocorticoids can inflict damage within the hippocampus. In adult humans, elevated cortisol levels have been associated with reduced hippocampal volumes; however, normative data in children are not available. The objective of this study was to examine possible associations of serum cortisol levels with hippocampal volumes and morphology in healthy children.

The role of the amygdala and olfaction in unconditioned fear in developing rats.

Early in ontogeny, young rats must be able to detect dangerous stimuli and to exhibit appropriate defensive behaviors. Different nuclei of the amygdala mediate unconditioned and conditioned fear responses to threat in adult rats. The aim of this study was to determine the role of the amygdala in unlearned fear behavior in young rats.

Age-specific threats induce CRF expression in the paraventricular nucleus of the hypothalamus and hippocampus of young rats.

Young animals respond to threatening stimuli in an age-specific way. Their endocrine and behavioral responses reflect the potential threat of the situation at a given age. The aim of the present study was to determine whether corticotropin-releasing factor (CRF) is involved in the endocrine and behavioral responses to threat and their developmental changes in young rats.

Adaptations or pathologies? Long-term changes in brain and behavior after a single exposure to severe threat.

The experience of a single threatening situation may alter the behavior of an animal in a long-lasting way. Long-lasting changes in behavior have been induced in laboratory animals to model and investigate the development and neural substrate of human psychopathologies. Under natural conditions, however, changes in behavior after an aversive experience may be adaptive because behavioral modifications allow animals to adjust to a threat for extended periods of time.

Mother lowers glucocorticoid levels of preweaning rats after acute threat.

Exposure to a deadly threat, an adult male rat, induced the release of corticosterone in 14-day-old rat pups. The endocrine stress response was decreased when the pups were reunited with their mother immediately after exposure. These findings demonstrate that social variables can reduce the consequences of an aversive experience.

Rat pups reduce ultrasonic vocalization after exposure to an adult male rat.

We examined how the experience of a threatening stimulus alters subsequent behavior in a situation where the immediate threat is absent. A small huddle of 12-day-old rats was exposed to a potentially infanticidal adult male rat for 5 min. During male exposure, pups were significantly more immobile than control pups.