Non-synaptic intercellular communication: presynaptic inhibition

Synapse is the most common and generally accepted structural basis for the interaction between neurons. It provides a "one-to-one" communication system between neurons. However, there is another possibility for interneuronal communication: when one neuron communicates with many others without making synaptic contact. In the past few years neurochemical, morphological and pharmacological evidence has been obtained that some neurotransmitters may be released from non-synaptic sites, for diffusion to target cells more distant than those seen in conventional synaptic transmission. The non-synaptic interneuronal communication between neurons plays a physiological role in the presynaptic modulation of chemical neurotransmission. This would be a transitional form between the classical neurotransmission and the broadcasting of neuroendocrine secretion.     

Sensorimotor reactivity (acoustic startle response) in rats with experimental depressive syndrome

Alterations of the sensorimotor responses in Wistar rats with experimental dopamine deficit-dependent depressive syndrome induced by neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine were measured by acoustic startle. In rats with innate high level of anxiety the development of behavioral depression was accompanied by the decrease in startle amplitude. In rats with innate low level of anxiety the decrease in startle amplitude did not reach the statistical significance. Correlation between the anxiety-phobic level and the expression of behavioral depression was not revealed. Independently of the initial anxiety-phobic level, in rats with depressive syndrome at the stage of behavioral rehabilitation after the neurotoxin withdrawal the prepulse inhibition of the acoustic startle was decreased as compared to control animals. It is suggested that the decrease in startle amplitude and, to a greater extent, the decrease in prepulse inhibition may characterize the development of dopamine deficit-dependent states.     

A photoswitchable GPCR-based opsin for presynaptic inhibition

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A possible coordinating role for presynaptic inhibition

Conditioning stimuli were applied to the common peroneal or superficial peroneal nerve in acute experiments on anesthetized cats. Changes in the N₁-component of the dorsal cord potential evoked by stimulation of one of these nerves or of other nerves (tibial, deep peroneal) and changes in the amplitude of antidromic action potentials in the afferent fibers of these nerves were investigated. The degree of reinforcement of antidromic action potentials, reflecting the degree of depolarization of the afferent terminals, was found to be greater for the passive nerve than for the active to which the conditioning stimulus was applied. Inhibition of the N₁-component of the dorsal cord potential was deeper when a pair of stimuli was applied to two different nerves (under these conditions only the mechanism of presynaptic inhibition was activated) than when they were applied to the same nerve. It is concluded that presynaptic inhibition, by selectively controlling afferent volleys, can evidently play a coordinating role.     

Habituation and prepulse inhibition of acoustic startle in rodents

The acoustic startle response is a protective response, elicited by a sudden and intense acoustic stimulus. Facial and skeletal muscles are activated within a few milliseconds, leading to a whole body flinch in rodents(1). Although startle responses are reflexive responses that can be reliably elicited, they are not stereotypic. They can be modulated by emotions such as fear (fear potentiated startle) and joy (joy attenuated startle), by non-associative learning processes such as habituation and sensitization, and by other sensory stimuli through sensory gating processes (prepulse inhibition), turning startle responses into an excellent tool for assessing emotions, learning, and sensory gating, for review see( 2, 3). The primary pathway mediating startle responses is very short and well described, qualifying startle also as an excellent model for studying the underlying mechanisms for behavioural plasticity on a cellular/molecular level(3). We here describe a method for assessing short-term habituation, long-term habituation and prepulse inhibition of acoustic startle responses in rodents. Habituation describes the decrease of the startle response magnitude upon repeated presentation of the same stimulus. Habituation within a testing session is called short-term habituation (STH) and is reversible upon a period of several minutes without stimulation. Habituation between testing sessions is called long-term habituation (LTH)(4). Habituation is stimulus specific(5). Prepulse inhibition is the attenuation of a startle response by a preceding non-startling sensory stimulus(6). The interval between prepulse and startle stimulus can vary from 6 to up to 2000 ms. The prepulse can be any modality, however, acoustic prepulses are the most commonly used. Habituation is a form of non-associative learning. It can also be viewed as a form of sensory filtering, since it reduces the organisms' response to a non-threatening stimulus. Prepulse inhibition (PPI) was originally developed in human neuropsychiatric research as an operational measure for sensory gating(7). PPI deficits may represent the interface of "psychosis and cognition" as they seem to predict cognitive impairment(8-10). Both habituation and PPI are disrupted in patients suffering from schizophrenia(11), and PPI disruptions have shown to be, at least in some cases, amenable to treatment with mostly atypical antipsychotics(12, 13). However, other mental and neurodegenerative diseases are also accompanied by disruption in habituation and/or PPI, such as autism spectrum disorders (slower habituation), obsessive compulsive disorder, Tourette's syndrome, Huntington's disease, Parkinson's disease, and Alzheimer's Disease (PPI)(11, 14, 15) Dopamine induced PPI deficits are a commonly used animal model for the screening of antipsychotic drugs(16), but PPI deficits can also be induced by many other psychomimetic drugs, environmental modifications and surgical procedures.     

Modulation by corticospinal volleys of presynaptic inhibition to Ia afferents in man.

New methods have been recently developed to explore selectively presynaptic inhibition of Ia afferents in humans. They have allowed us to describe a highly specialized organisation in these pathways. A differential control has been disclosed during voluntary movements among various motoneuronal pools: at the onset of a selective voluntary contraction presynaptic inhibition of Ia afferents projecting to the 'contracting' motoneurons is strongly decreased whereas presynaptic inhibition of Ia afferents to antagonistic or synergistic motoneuronal pools, not involved in the contraction, is increased. Indirect arguments suggested that these modulations are centrally patterned. A differential control has been also disclosed between upper and lower limb pathways. Using transcranial magnetic stimulation to induce a descending corticospinal volley, we have shown that a corticospinal volley inhibits preferentially 'presynaptic interneurons'at the lumbar spinal level, an effect which is strengthened by a cutaneous input whereas it preferentially activates 'presynaptic interneurons' at the cervical spinal level, an effect which is inverted by a cutaneous input.     

Channel gating: twist to open

Recent studies of the bacterial mechanosensitive channel MscL have combined a number of different approaches to come up with a model for the channel gating mechanism.     

Determinants of G protein inhibition of presynaptic calcium channels

The modulation of presynaptic calcium (Ca) channels by heterotrimeric G proteins is a key factor for the regulation of neurotransmission. Over the past 20 yr, a significant understanding of the molecular events underlying this regulation has been acquired. It is now widely accepted that binding of G protein betagamma dimers directly to the cytoplasmic region linking domains I and II of the Ca channel alpha1 subunit results in a stabilization of the closed conformation of the channel, thereby inhibiting current activity. The extent of the inhibition is dependent on the Gbeta subunit isoform, and is antagonized by both strong membrane depolarizations and protein kinase C-dependent phosphorylation of the channel. Finally, the inhibition is critically modulated by regulator of G protein signaling proteins, and by proteins forming the presynaptic vesicle release complex. Thus, the regulation of the activities of presynaptic Ca channels is becoming increasingly complex, a feature that may contribute to the overall fine-tuning of Ca entry into presynaptic nerve termini, and thus, neurotransmission.     

On mechanisms of depression in pathways of presynaptic inhibition

We investigated inhibition of the N₁-component of the spinal cord dorsal potential (CDP) evoked by experimental stimulation of the n. peroneus in spinal cats. Stimulation was carried out following two conditioning stimuli administered at different time intervals to the same or different cutaneous nerves. The interval between the last conditioning stimulus and the experimental one remained constant (20 msec). It is demonstrated that there is no dependence between weakening of inhibitory action of the second conditioning stimulus and inhibition of the dorsal horn interneurons excited by it that generate the N₁-component of the CDP. It is hypothesized that mechanisms which act on the principle of negative feedback are present in the vincinity of the synaptic junctions of cutaneous afferent fibers with neurons of the substantia gelationsa, and that these mechanisms restrict the development of presynaptic inhibition during inflow of a series of afferent impulses into the cord.Dnepropetrovsk State University. Translated from Neirofiziologia, Vol. 1, No. 3, pp. 253–261, November–December, 1969.     

Adenosine mediation of presynaptic feedback inhibition of glutamate release

Conditions of increased metabolic demand relative to metabolite availability are associated with increased extracellular adenosine in CNS tissue. Synaptic activation of postsynaptic NMDA receptors on neurons of the cholinergic brainstem arousal center can increase sufficient extracellular adenosine to act on presynaptic A1 adenosine receptors (A1ADRs) of glutamate terminals, reducing release from the readily releasable pool. The time course of the adenosine response to an increase in glutamate release is slow (tau > 10 min), consistent with the role of adenosine as a fatigue factor that inhibits the activity of cholinergic arousal centers to reduce arousal.     

Concerted gating mechanism underlying KATP channel inhibition by ATP

KATP channels assemble from four regulatory SUR1 and four pore-forming Kir6.2 subunits. At the single-channel current level, ATP-dependent gating transitions between the active burst and the inactive interburst conformations underlie inhibition of the KATP channel by intracellular ATP. Previously, we identified a slow gating mutation, T171A in the Kir6.2 subunit, which dramatically reduces rates of burst to interburst transitions in Kir6.2DeltaC26 channels without SUR1 in the absence of ATP. Here, we constructed all possible mutations at position 171 in Kir6.2DeltaC26 channels without SUR1. Only four substitutions, 171A, 171F, 171H, and 171S, gave rise to functional channels, each increasing Ki,ATP for ATP inhibition by >55-fold and slowing gating to the interburst by >35-fold. Moreover, we investigated the role of individual Kir6.2 subunits in the gating by comparing burst to interburst transition rates of channels constructed from different combinations of slow 171A and fast T171 "wild-type" subunits. The relationship between gating transition rate and number of slow subunits is exponential, which excludes independent gating models where any one subunit is sufficient for inhibition gating. Rather, our results support mechanisms where four ATP sites independently can control a single gate formed by the concerted action of all four Kir6.2 subunit inner helices of the KATP channel.     

Static otolithic drive alters presynaptic inhibition in soleus motor pool

The vestibular system has both direct and indirect connections to the soleus motor pool via the vestibulospinal and reticulospinal tracts. The exact nature of how this vestibular information is integrated within the spinal cord is largely unknown. The purpose of this study was to identify whether changes in static otolithic drive altered the amount of presynaptic inhibition in the soleus H-reflex pathway. Changes in static otolithic drive were investigated in sixteen healthy participants using a tilt table. Two presynaptic pathways (common peroneal and femoral) to the soleus H-reflex were tested in three weight conditions (supine, non-weight bearing, and weight bearing). The dependent variable was the peak-to-peak amplitude of the soleus H-reflex. Inhibition to the soleus motor pool through the common peroneal nerve pathway differed significantly during weight conditions and tilt. During tilt and non-weight bearing there was greater inhibition of the soleus H-reflex compared to supine, however, this effect was reversed during tilt and weight bearing. Facilitation from the femoral nerve pathway was reduced by tilt compared to supine, but this reduction was unaffected by weight condition. This supports a role of the vestibular system as providing complex, task-dependent presynaptic input to motoneurons in the lower limbs.     

Prepulse inhibition of acoustic startle in aromatase knock-out mice: effects of age and gender

Estrogen has been suggested to play a neuromodulatory and neuroprotective role on the brain dopamine system. We used aromatase knockout (ArKO) mice that lack a functional aromatase enzyme and are unable to convert testosterone into estrogen, and assessed prepulse inhibition of acoustic startle, locomotor hyperactivity to amphetamine treatment and rotarod performance. Mice were tested at either 1 month, 4–5 months or 12–18 months of age. In male, but not female ArKO mice, there was an age-related reduction of prepulse inhibition. The 12–18 months old male ArKO mice also showed significantly greater amphetamine-induced hyperactivity. Mice heterozygous for the mutation showed no deficits or were in-between wildtype mice and ArKO mice. We postulate that these data indicate a neuroprotective role of estrogen, particularly in male mice, on ageing of brain mechanisms involved in prepulse inhibition and locomotor activity regulation. It is likely that these brain mechanisms are or include dopaminergic activity.     

Sensorimotor gating and spatial learning in α7‐nicotinic receptor knockout mice

The role of acetylcholine and specific nicotinic receptors in sensorimotor gating and higher cognitive function has been controversial. Here, we used a commercially available mouse with a null mutation in the Chrna7^tm1Bay gene [α7‐nicotinic acetylcholine receptor (nAChR) knockout (KO) mouse] in order to assess the role of the α7‐nAChR in sensorimotor gating and spatial learning. We examined prepulse inhibition (PPI) of startle and nicotine‐induced enhancement of PPI. We also tested short‐ and long‐term habituation of the startle response as well as of locomotor behaviour in order to differentiate the role of this receptor in the habituation of evoked behaviour (startle) vs. motivated behaviour (locomotion). To address higher cognition, mice were also tested in a spatial learning task. Our results showed a mild but consistent PPI deficit in α7‐nAChR KO mice. Furthermore, they did not show nicotine‐induced enhancement of startle or PPI. Short‐ and long‐term habituation was normal in KO mice for both types of behaviours, evoked or motivated, and they also showed normal learning and memory in the Barnes maze. Thorough analysis of the behavioural data indicated a slightly higher degree of anxiety in α7‐nAChR KO mice; however, this could only be partially confirmed in an elevated plus maze test. In summary, our data suggest that α7‐nAChRs play a minor role in PPI, but seem to mediate nicotine‐induced PPI enhancement. We found no evidence to suggest that they are important for habituation or spatial learning .