A key requirement for synaptic Reelin signaling in ketamine-mediated behavioral and synaptic action

Ketamine is a noncompetitive N-methyl-D-aspartate (NMDA) receptor antagonist that produces rapid antidepressant action in some patients with treatment-resistant depression. However, recent data suggest that ∼50% of patients with treatment-resistant depression do not respond to ketamine. The factors that contribute to the nonresponsiveness to ketamine’s antidepressant action remain unclear. Recent studies have reported a role for secreted glycoprotein Reelin in regulating pre- and postsynaptic function, which suggests that Reelin may be involved in ketamine’s antidepressant action, although the premise has not been tested. Here, we investigated whether the disruption of Reelin-mediated synaptic signaling alters ketamine-triggered synaptic plasticity and behavioral effects. To this end, we used mouse models with genetic deletion of Reelin or apolipoprotein E receptor 2 (Apoer2), as well as pharmacological inhibition of their downstream effectors, Src family kinases (SFKs) or phosphoinositide 3-kinase. We found that disruption of Reelin, Apoer2, or SFKs blocks ketamine-driven behavioral changes and synaptic plasticity in the hippocampal CA1 region. Although ketamine administration did not affect tyrosine phosphorylation of DAB1, an adaptor protein linked to downstream signaling of Reelin, disruption of Apoer2 or SFKs impaired baseline NMDA receptor–mediated neurotransmission. These results suggest that maintenance of baseline NMDA receptor function by Reelin signaling may be a key permissive factor required for ketamine’s antidepressant effects. Taken together, our results suggest that impairments in Reelin-Apoer2-SFK pathway components may in part underlie nonresponsiveness to ketamine’s antidepressant action.

Effects of memristive synapse radiation interactions on learning in spiking neural networks

This study uses advanced modeling and simulation to explore the effects of external events such as radiation interactions on the synaptic devices in an electronic spiking neural network. Specifically, the networks are trained using the spike-timing-dependent plasticity (STDP) learning rule to recognize spatio-temporal patterns (STPs) representing 25 and 100-pixel characters. Memristive synapses based on a TiO2 non-linear drift model designed in Verilog-A are utilized, with STDP learning behavior achieved through bi-phasic pre- and post-synaptic action potentials. The models are modified to include experimentally observed state-altering and ionizing radiation effects on the device. It is found that radiation interactions tend to make the connection between afferents stronger by increasing the conductance of synapses overall, subsequently distorting the STDP learning curve. In the absence of consistent STPs, these effects accumulate over time and make the synaptic weight evolutions unstable. With STPs at lower flux intensities, the network can recover and relearn with constant training. However, higher flux can overwhelm the leaky integrate-and-fire post-synaptic neuron circuits and reduce stability of the network.

Cortical representation of touch in silico

With its six layers and ~12000 neurons, a cortical column is a complex network whose function is plausibly greater than the sum of its constituents’. Functional characterization of its network components will require going beyond the brute-force modulation of the neural activity of a small group of neurons. Here we introduce an open-source, biologically inspired, computationally efficient network model of the somatosensory cortex’s granular and supragranular layers after reconstructing the barrel cortex in soma resolution. Comparisons of the network activity to empirical observations showed that the in silico network replicates the known properties of touch representations and whisker deprivation-induced changes in synaptic strength induced in vivo. Simulations show that the history of the membrane potential acts as a spatial filter that determines the presynaptic population of neurons contributing to a post-synaptic action potential; this spatial filtering might be critical for synaptic integration of top-down and bottom-up information.

Coding for the Brain: RNA, its Photons, and Piagetian Higher-Intelligence through Action

Modelling human intelligence? Hyland identified three approaches: •Physiological, •Mentalistic (as if outside 3D space), and •Mechanistic. Arguably their apparent incompatibility arises from a mistaken choice of scale, centred on the synapse as a basic unit for thought. Instead RNA-codons are now proposed as those fundamental elements (cf. Hydén’s forgotten 1960s findings). This also seems compatible with both (i) information-technology’s digitisation, and (ii) Piaget’s concepts of “schèmes,” and developmental stages. For the more-complex code-structures (“schémata”) needed for higher Piagetian stages, their necessary physical configuration is then considered — packable into virus-like “boxes” (capsids —typically 125nm diameter). These could be free to relocate into cortex-“archives” — either within Rakic’s migratory new-neurons, or the bloodstream! Such ultra-miniaturisation needs to communicate by INFRA-RED signals — via myelin coaxial cables, but also somewhat free to operate radio-like, dependent on “call-sign” coding (like phone-numbers). Also any “radio-like” abilities would allow continued participation after relocation (as if mobile-phones using WiFi). Meanwhile traditional synaptic Action-Potential signalling is seen as analogue adjustment-signals: (i) in orthodox peripheral muscle-control, and (ii) as constantly updating deep-brain “wiring” via well-known Hebbian principles (an important, but secondary task — after main infra-red transmissions). Gut-contents have a surprise-role in mental abilities — a phenomenon which is also tentatively explained as a supplementary “useful-junk RNA” source. Piaget-as-Epistemologist saw “equilibration” (coherence) as the vital-but-fallible criterion for theory evaluation, both in the brain, and within science. That philosophy is applied here.

The differential contribution of pacemaker neurons to synaptic transmission in the pyloric network of the Jonah crab, Cancer borealis

Many neurons receive synchronous input from heterogeneous presynaptic neurons with distinct properties. An instructive example is the crustacean stomatogastric pyloric circuit pacemaker group, consisting of the anterior burster (AB) and pyloric dilator (PD) neurons, which are active synchronously and exert a combined synaptic action on most pyloric follower neurons. Previous studies in lobster have indicated that AB is glutamatergic, whereas PD is cholinergic. However, although the stomatogastric system of the crab Cancer borealis has become a preferred system for exploration of cellular and synaptic basis of circuit dynamics, the pacemaker synaptic output has not been carefully analyzed in this species. We examined the synaptic properties of these neurons using a combination of single-cell mRNA analysis, electrophysiology, and pharmacology. The crab PD neuron expresses high levels of choline acetyltransferase and the vesicular acetylcholine transporter mRNAs, hallmarks of cholinergic neurons. In contrast, the AB neuron expresses neither cholinergic marker but expresses high levels of vesicular glutamate transporter mRNA, consistent with a glutamatergic phenotype. Notably, in the combined synapses to follower neurons, 70–75% of the total current was blocked by putative glutamatergic blockers, but short-term synaptic plasticity remained unchanged, and although the total pacemaker current in two follower neuron types was different, this difference did not contribute to the phasing of the follower neurons. These findings provide a guide for similar explorations of heterogeneous synaptic connections in other systems and a baseline in this system for the exploration of the differential influence of neuromodulators. NEW & NOTEWORTHY The pacemaker-driven pyloric circuit of the Jonah crab stomatogastric nervous system is a well-studied model system for exploring circuit dynamics and neuromodulation, yet the understanding of the synaptic properties of the two pacemaker neuron types is based on older analyses in other species. We use single-cell PCR and electrophysiology to explore the neurotransmitters used by the pacemaker neurons and their distinct contribution to the combined synaptic potentials.

The differential contribution of pacemaker neurons to synaptic transmission in the pyloric network of the Jonah crab, Cancer borealis

Many neurons receive synchronous input from heterogeneous presynaptic neurons with distinct properties. An instructive example is the crustacean stomatogastric pyloric circuit pacemaker group, consisting of the anterior burster (AB) and pyloric dilator (PD) neurons, which are active synchronously and exert a combined synaptic action on most pyloric follower neurons. Although the stomatogastric system of the crab Cancer borealis has become a preferred model system for exploration of cellular and synaptic basis of circuit dynamics, in this species, the identity of the PD neuron neurotransmitter and its contribution to the total pacemaker group synaptic output remain unexplored. We examined the synaptic properties of the crab PD neuron using a combination of single cell mRNA analysis, electrophysiology and pharmacology. The crab PD neuron expresses high levels of choline acetyltransferase and the vesicular acetylcholine transporter mRNAs, hallmarks of cholinergic neurons. Conversely, the AB neuron does not express either of these cholinergic markers, and expresses high levels of vesicular glutamate transporter mRNA, consistent with a glutamatergic phenotype. Notably, in the combined synapses to the LP and PY neurons, the major contribution is from the glutamatergic AB neuron and only between 25-30% of the synaptic strength is due to the PD neuron. However, there was no difference between the short-term synaptic plasticity in the total pacemaker synapse compared to that of the PD neuron alone. These findings provide a guide for similar explorations of heterogeneous synaptic connections in other systems and a baseline in this system for the exploration of the differential influence of neuromodulators.

Otilonium Bromide: A Drug with a Complex Mechanism of Action

Otilonium bromide (OB) is a drug with spasmolytic activity belonging to quaternary ammonium derivatives and extensively used to treat patients affected by the Irritable Bowel Syndrome (IBS). Thanks to its peculiar pharmacokinetic, OB concentrates in the large bowel wall and acts locally. From the pharmacodynamics point of view, OB is able to inhibit i) the main patterns of human colonic motility in vitro; ii) the contractility caused by excitatory motor neurons stimulation (pre-synaptic action) and iii) the contractility caused by the direct action of excitatory neurotransmitters (post-synaptic action). Interestingly, these effects derive from a complex interaction between the drug and several cellular targets. The main action consists in the blockade of Ca2+ entry through L-type Ca2+ channels and interference with intracytoplasmatic Ca2+ mobilization necessary for SMC contraction, thus preventing excessive bowel contractions and abdominal cramps. Further, OB blocks the T-type Ca2+ channels and interferes with the muscarinic responses; it interacts, directly or indirectly, with the tachykinin receptors on SMC and on primary afferent neurons whose combined effects may result in the reduction of motility and abdominal pain. In summary, a revision of this complex picture of OB activity could help to better address its therapeutic use.

Tumor Necrosis Factor and Interleukin-1β Modulate Synaptic Plasticity during Neuroinflammation

Cytokines are constitutively released in the healthy brain by resident myeloid cells to keep proper synaptic plasticity, either in the form of Hebbian synaptic plasticity or of homeostatic plasticity. However, when cytokines dramatically increase, establishing a status of neuroinflammation, the synaptic action of such molecules remarkably interferes with brain circuits of learning and cognition and contributes to excitotoxicity and neurodegeneration. Among others, interleukin-1β (IL-1β) and tumor necrosis factor (TNF) are the best studied proinflammatory cytokines in both physiological and pathological conditions and have been invariably associated with long-term potentiation (LTP) (Hebbian synaptic plasticity) and synaptic scaling (homeostatic plasticity), respectively. Multiple sclerosis (MS) is the prototypical neuroinflammatory disease, in which inflammation triggers excitotoxic mechanisms contributing to neurodegeneration. IL-β and TNF are increased in the brain of MS patients and contribute to induce the changes in synaptic plasticity occurring in MS patients and its animal model, the experimental autoimmune encephalomyelitis (EAE). This review will introduce and discuss current evidence of the role of IL-1β and TNF in the regulation of synaptic strength at both physiological and pathological levels, in particular speculating on their involvement in the synaptic plasticity changes observed in the EAE brain.