Specialized neurons in emotional memory play important role in fear
Fear memory encoding, the process responsible for persistent reactions to trauma-associated cues, is influenced by a sparse but potent population of inhibitory cells called parvalbumin-interneurons (PV-INs) in the amygdala, according to a new study.
The study focused on identifying the synaptic connections between inhibitory PV-INs, sensory pathways and neighboring principal neurons in the basolateral amygdala, a brain region involved in detecting and responding to dangerous situations.
Stimuli encountered during a traumatic event can elicit strong emotional reactions long after the threat has subsided. These emotional memories are thought to be encoded through changes in the neural connections, or synapses, within the basolateral amygdala that provide outputs to other brain areas, controlling the so-called “fight or flight” response.
These principal neurons increase their activity when an animal learns a threatening stimulus association. At other times, these cells are very quiet, despite their ongoing bombardment by sensory stimulation.
“Our study is the first to show that this default silencing may, in part, be attributable to a sparse population of inhibitory PV-INs,” says Roger Clem, PhD.
“The complex anatomy of these cells may allow them to function like master regulators on a hair trigger, springing into action to suppress their neighbors when they detect even the slightest sensory perturbation.”
To investigate whether fear learning alters PV-IN properties and their silencing effect on surrounding neurons, the team introduced fear conditioning in a mouse model, pairing an auditory tone with a subsequent aversive foot shock.
They found that when animals acquire a fear memory, the suppressive influence of PV-INs is relieved, allowing the fear system to respond more vigorously when the auditory stimulus is re-encountered in order to trigger a fight-or-flight response.
All sensations, movements, thoughts, memories and feelings are the result of signals that pass through nerve cells (neurons), the primary functional unit of the brain and central nervous system. When a signal passes from the cell body to the end of the cell axon that stretches away from the cell body, chemicals known as neurotransmitters are released into the synapse, the place where signals are exchanged between cells.
The neurotransmitters then cross the synapse and attach to receptors on the neighboring cell, which can change the properties of the receiving cell.
Found throughout the brain and produced by neurons, gamma aminobutyric acid (GABA) is an inhibitory neurotransmitter that binds to GABA receptors, making the neighboring neuron less excitable. Fear-related disorders like anxiety and post-traumatic stress disorder (PTSD) are thought to partly result from an imbalance of excitatory and inhibitory nerve cells in the basolateral amygdala.
The current study team investigated GABA-synthesizing PV-INs after fear conditioning. Specifically, using electrophysiological and optogenetic techniques, the research team found that both input to and output from these cells was decreased after fear learning. In addition, the team found that memory encoding specifically affected PV-INs that respond most robustly to sensory input and that are thus uniquely positioned to regulate emotional reactivity.
The study findings indicate that inhibitory plasticity is a normal consequence of memory encoding and when dysregulated, it could lead to the hyper excitability of the amygdala, a hallmark of PTSD.
“Further investigation of the function of these PV-IN circuits under various stress paradigms may identify which of the processes we describe might be involved in pathological fear expression and ultimately, could establish cellular targets for reducing inappropriate amygdala responses and subsequent fear behaviors,” says Dr. Clem.
Lucas, E., Jegarl, A., Morishita, H., & Clem, R. (2016). Multimodal and Site-Specific Plasticity of Amygdala Parvalbumin Interneurons after Fear Learning Neuron DOI: 10.1016/j.neuron.2016.06.032