Mark Pickering

Actions of TNF‐α on glutamatergic synaptic transmission in the central nervous system

Increasing attention is being paid to the role of inflammatory and immune molecules in the modulation of central nervous system (CNS) function. Tumour necrosis factor‐α (TNF‐α) is a pro‐inflammatory cytokine, the receptors for which are expressed on neurones and glial cells throughout the CNS. Through the action of its two receptors, it has a broad range of actions on neurones which may be either neuroprotective or neurotoxic. It plays a facilitatory role in glutamate excitotoxicity, both directly and indirectly by inhibiting glial glutamate transporters on astrocytes. Additionally, TNF‐α has direct effects on glutamate transmission, for example increasing expression of AMPA receptors on synapses. TNF‐α also plays a role in synaptic plasticity, inhibiting long‐term potentiation (LTP), a process dependent on p38 mitogen activated kinase (p38 MAP) kinase. In the following review we look at these and other effects of TNF‐α in the CNS.

Activation of TRPV1 Mediates Calcitonin Gene-Related Peptide Release, Which Excites Trigeminal Sensory Neurons and Is Attenuated by a Retargeted Botulinum Toxin with Anti-Nociceptive Potential

Excessive release of inflammatory/pain mediators from peripheral sensory afferents renders nerve endings hyper-responsive, causing central sensitization and chronic pain. Herein, the basal release of proinflammatory calcitonin gene-related peptide (CGRP) was shown to increase the excitability of trigeminal sensory neurons in brainstem slices via CGRP1 receptors because the effect was negated by an antagonist, CGRP8–37. This excitatory action could be prevented by cleaving synaptosomal-associated protein of Mr 25,000 (SNAP-25) with botulinum neurotoxin (BoNT) type A, a potent inhibitor of exocytosis. Strikingly, BoNT/A proved unable to abolish the CGRP1 receptor-mediated effect of capsaicin, a nociceptive TRPV1 stimulant, or its elevation of CGRP release from trigeminal ganglionic neurons (TGNs) in culture. Although the latter was also not susceptible to BoNT/E, apparently attributable to a paucity of its acceptors (glycosylated synaptic vesicle protein 2 A/B), this was overcome by using a recombinant chimera (EA) of BoNT/A and BoNT/E. It bound effectively to the C isoform of SV2 abundantly expressed in TGNs and cleaved SNAP-25, indicating that its /A binding domain (HC) mediated uptake of the active /E protease. The efficacy of /EA is attributable to removal of 26 C-terminal residues from SNAP-25, precluding formation of SDS-resistant SNARE complexes. In contrast, exocytosis could be evoked after deleting nine of the SNAP-25 residues with /A but only on prolonged elevation of [Ca2+]i with capsaicin. This successful targeting of /EA to nociceptive neurons and inhibition of CGRP release in vitro and in situ highlight its potential as a new therapy for sensory dysmodulation and chronic pain.

Pro-inflammatory cytokines and their effects in the dentate gyrus

The older notion of a central nervous system existing in essential isolation from the immune system has changed dramatically in recent years as the body of evidence relating to the interactions between these two systems has grown. Here we address the role of a particular subset of immune modulatory molecules, the pro-inflammatory cytokines, in regulating neuronal function and viability in the dentate gyrus of the hippocampus. These inflammatory mediators are known to be elevated in many neuropathological conditions, such as Alzheimers disease, Parkinsons disease and ischaemic injury that follows stroke. Pro-inflammatory cytokines, such as tumour necrosis factor-alpha (TNF-alpha), interleukin 1-beta (IL-1beta) and interleukin 18 (IL-18), have been shown to regulate neurotoxicity; although, due to the complexity of the cytokine action in neurons and glia, the effect may be either facilitatory or protective, depending on the circumstances. As well as their role in neurotoxicity and neuroprotection, the pro-inflammatory cytokines have also been shown to be potent regulators of synaptic function. In particular, TNF-alpha, IL-1beta and IL-18 have all been shown to inhibit long-term potentiation, a form of neuronal plasticity widely believed to underlie learning and memory, both in the early p38 mitogen activated protein kinase-dependant phase and the later protein synthesis-dependant phase. In this article we address the mechanisms underlying these cytokine effects in the dentate gyrus of the hippocampus.

The diaphragm: two physiological muscles in one

To the respiratory physiologist or anatomist the diaphragm muscle is of course the prime mover of tidal air. However, gastrointestinal physiologists are becoming increasingly aware of the value of this muscle in helping to stop gastric contents from refluxing into the oesophagus. The diaphragm should be viewed as two distinct muscles, crural and costal, which act in synchrony throughout respiration. However, the activities of these two muscular regions can diverge during certain events such as swallowing and emesis. In addition, transient crural muscle relaxations herald the onset of spontaneous acid reflux episodes. Studying the motor control of this muscular barrier may help elucidate the mechanism of these episodes. In the rat, the phrenic nerve divides into three branches before entering the diaphragm, and it is possible to sample single neuronal activity from the crural and costal branches. This review will discuss our recent findings with regard to the type of motor axons running in the phrenic nerve of the rat. In addition, we will outline our ongoing search for homologous structures in basal vertebrate groups. In particular, the pipid frogs (e.g. the African clawed frog, Xenopus laevis) possess a muscular band around the oesophagus that appears to be homologous to the mammalian crural diaphragm. This structure does not appear to interact directly with the respiratory apparatus, and could suggest a role for this region of the diaphragm, which was not originally respiratory.

Sacral nerve stimulation increases activation of the primary somatosensory cortex by anal canal stimulation in an experimental model.

Sacral and posterior tibial nerve stimulation may be used to treat faecal incontinence; however, the mechanism of action is unknown. The aim of this study was to establish whether sensory activation of the cerebral cortex by anal canal stimulation was increased by peripheral neuromodulation.

Temporal change in gene expression in the rat dentate gyrus following passive avoidance learning

A learning event initiates a cascade of altered gene expression leading to synaptic remodelling within the hippocampal dentate gyrus, a structure vital to memory formation. To illuminate this transcriptional program of synaptic plasticity we used microarrays to quantify mRNA from the rat dentate gyrus at increasing times following passive avoidance learning. Approximately, 500 known genes were transcriptionally regulated across the 24 h post‐training period. The 0–2 h period saw up‐regulation of genes involved in transcription while genes with a role in synaptic/cytoskeletal structure increased 0–6 h, consistent with structural rearrangements known to occur at these times. The most striking feature was the profound down‐regulation, across all functional groups, 12 h post‐training. Bioinformatics analysis identified the likely transcription factors controlling gene expression in each post‐training period. The role of NFκB, implicated in the early post‐training period was subsequently confirmed with activation and nuclear translocation seen in dentate granule neurons following training. mRNA changes for four genes, LRP3 (0 h), alpha actin (3 h), SNAP25 and NSF (6–12 h), were validated at message and/or protein level and shown to be learning specific. Thus, the memory‐associated transcriptional cascade supports the cardinal periods of synaptic loosening, reorganisation and selection thought to underpin the process of long‐term memory consolidation in the hippocampus.

Interleukin-18 mediated inhibition of LTP in the rat dentate gyrus is attenuated in the presence of mGluR antagonists

Pro-inflammatory cytokines are known to be elevated in several neuropathological states that are associated with learning and memory impairments. We have previously demonstrated the inhibition of long-term potentiation (LTP), a recognised model for memory, in the dentate gyrus region of the rat hippocampus, by interleukin-18. We have also previously shown that the inhibitory effect of TNF-alpha on LTP can be attenuated by inhibitors of metabotropic glutamate receptors (mGluRs). We therefore went on to investigate the effects of the mGluR antagonists MPEP and MTPG on the effect of IL-18 on LTP in the rat dentate gyrus in vitro. Recordings of field excitatory post-synaptic potentials (EPSPs) were made from the medial perforant path of rat hippocampal slices. IL-18 (100 ng/ml) applied for 20 min before-HFS had no significant effect on baseline EPSPs but significantly impaired LTP (IL-18 LTP 116+/-9%, versus control LTP 163+/-6% 1h post-tetanus, P<0.001, n=5). Perfusion of the mGluR5 specific antagonist MPEP (5 microM) for 40 min prior to application of IL-18 had no significant effect on baseline EPSPs but significantly attenuated the inhibitory effect of IL-18 on LTP at 30 min but not 1h (177+/-2% and 138+/-8%, respectively, compared to controls; n=5). Perfusion of the group II mGluR antagonist MTPG (50 microM) for 40 min prior to application of IL-18 had no significant effect on baseline EPSPs but was found to significantly reverse the inhibitory effect of IL-18 on LTP at 1h (164+/-6% compared to IL-18 alone, n=5). This study provides novel evidence of the involvement of mGluRs in the IL-18 mediated inhibition of LTP.

Mkl Transcription Cofactors Regulate Structural Plasticity in Hippocampal Neurons

Expressed throughout the central nervous system, the myocardin-related, megakaryoblastic acute leukemia 1 and 2 (Mkl1/2) are transcriptional cofactors that can be found tethered in the cytoplasm to monomeric actin but on synaptic activation translocate to the nucleus and associate with transcription factors such as serum response factor (SRF) to regulate expression of structural genes. This implies a potential role for Mkls in linking synaptic activity, through gene-expression control, to neuronal structural plasticity. Here, we present evidence that Mkls, particularly Mkl2, are powerful regulators of neuronal structure in vitro. Moreover, using the passive avoidance-conditioning paradigm, we identify learning-associated alterations of neuronal Mkl expression that appear to contribute to 2 phases of gene regulation during memory consolidation in the hippocampus. Gene regulation immediately after learning includes Egr2 and may be facilitated by downregulation of Mkls likely releasing ternary complex factor-regulated SRF activity. The second transcriptional phase occurs later at the 3-h postavoidance time point when Mkl accumulates in the nucleus of hippocampal neurons and there is enhanced transcription of Mkl-dependent structural genes that may contribute to the elaboration of new, memory-associated synapses known to appear over the subsequent 3-h period.

CX3CL1 is up-regulated in the rat hippocampus during memory-associated synaptic plasticity

Several cytokines and chemokines are now known to play normal physiological roles in the brain where they act as key regulators of communication between neurons, glia, and microglia. In particular, cytokines and chemokines can affect cardinal cellular and molecular processes of hippocampal-dependent long-term memory consolidation including synaptic plasticity, synaptic scaling and neurogenesis. The chemokine, CX3CL1 (fractalkine), has been shown to modulate synaptic transmission and long-term potentiation (LTP) in the CA1 pyramidal cell layer of the hippocampus. Here, we confirm widespread expression of CX3CL1 on mature neurons in the adult rat hippocampus. We report an up-regulation in CX3CL1 protein expression in the CA1, CA3 and dentate gyrus (DG) of the rat hippocampus 2 h after spatial learning in the water maze task. Moreover, the same temporal increase in CX3CL1 was evident following LTP-inducing theta-burst stimulation in the DG. At physiologically relevant concentrations, CX3CL1 inhibited LTP maintenance in the DG. This attenuation in dentate LTP was lost in the presence of GABAA receptor/chloride channel antagonism. CX3CL1 also had opposing actions on glutamate-mediated rise in intracellular calcium in hippocampal organotypic slice cultures in the presence and absence of GABAA receptor/chloride channel blockade. Using primary dissociated hippocampal cultures, we established that CX3CL1 reduces glutamate-mediated intracellular calcium rises in both neurons and glia in a dose dependent manner. In conclusion, CX3CL1 is up-regulated in the hippocampus during a brief temporal window following spatial learning the purpose of which may be to regulate glutamate-mediated neurotransmission tone. Our data supports a possible role for this chemokine in the protective plasticity process of synaptic scaling.

Hippocampal region-specific regulation of NF-κB may contribute to learning-associated synaptic reorganisation

Activity of the transcription factor NF-kappaB is required for memory formation, but the identity and function of the genes it may regulate in this context remain obscure. Here, we comprehensively characterise NF-kappaB throughout the rat hippocampus following passive avoidance training and report significant subregion-specific increased activity across the dorsoventral axis 3h post-learning. Moreover, putative NF-kappaB binding motifs predominated in structural genes previously shown to regulate 3h following avoidance conditioning, the protein products of which may be involved in the subsequent synaptic remodelling required for consolidation. Finally, we assessed the influence of NF-kappaB-mediated transcription on neuritic structure and report that inhibition of NF-kappaB significantly decreases growth and branching of primary hippocampal neurons. These results suggest that NF-kappaB activity following hippocampal learning may contribute to consolidation-associated synaptic reorganisation.