Serotonin‐induced phase advances of SCN neuronal firing in vitro: A possible role for 5‐HT5A receptors?

Spontaneous firing rates of neurons in the suprachiasmatic nuclei (SCN) follow a consistent pattern, peaking near the midpoint of the light phase in a 12:12 light/dark schedule, and repeating this brief period of increased activity in subsequent circadian cycles. These carefully timed fluctuations reflect the output signal of the SCN, long recognized as the site of the endogenous biological clock in mammals. In rat hypothalamic slices, bath incubations of 8-OH-DPAT had previously been shown to elicit phase advances when applied at ZT6 (or 6 h following the onset of light), an action that could readily be attributed to 5-HT7 receptor activation. The present studies set out with the simple goal of establishing that the same receptor mechanism was responsible for the phase-shifting actions of 5-HT itself. Surprisingly, the phase advances elicited by 5-HT (0.5 microM, 1 h) at ZT6 were reduced by one 5-HT7 antagonist, ritanserin (10 microM), but not by another, mesulergine (10 microM). Receptor binding studies demonstrated a 25-fold greater affinity of ritanserin for h5-HT5A sites compared to mesulergine (Ki = 71 nM vs. 1,800 nM), an observation suggestive of a 5-HT5A mechanism for 5-HT and consistent with earlier observations of robust labeling of 5-HT5A sites in the SCN. 5-HT generated by the addition of L-tryptophan (10 microM, 1 h) to the slices displayed the same pattern of sensitivity, that is, blockade by ritanserin but not by mesulergine. Rp-cAMPS, a cAMP antagonist, failed to block the phase shifts elicited by 5-HT at a concentration (1 microM) previously shown to be effective against 8-OH-DPAT-induced phase shifts, in keeping with the proposed negative coupling of 5-HT5A receptors to cAMP production. Taken together, these results suggest that activation of both 5-HT5A and 5-HT7 receptors can produce phase advances of the circadian clock in vitro when they occur during mid-subjective day.     

14‐3‐3 Proteins in Pineal Photoneuroendocrine Transduction: How Many Roles?

Recent studies suggest that a common theme links the diverse elements of pineal photoneuroendocrine transduction--regulation via binding to 14-3-3 proteins. The elements include photoreception, neurotransmission, signal transduction and the synthesis of melatonin from tryptophan. We review general aspects of 14-3-3 proteins and their biological function as binding partners, and also focus on their roles in pineal photoneuroendocrine transduction.     

HMGB‐1, TLR4, IL‐1R1, TNF‐α, and IL‐1β: novel epilepsy markers?

Aim: The purpose of this study was to compare HMGB‐1, TLR4, IL‐1β, IL‐1R1, and TNF‐α levels in patients with mild and severe epilepsy with those in a healthy control group. Methods: Children aged 4–17 years, diagnosed with epilepsy for at least three years and with no progressive neurological disease, metabolic disease or infection, were selected for the study. The severe epilepsy group consisted of 28 children with at least one episode a week despite receiving three or more antiepileptic drugs. The mild epilepsy group consisted of 29 children with no seizures in the previous year, receiving only one antiepileptic drug, while 27 healthy children were selected as the control group. HMGB‐1, TLR4, IL‐1R1, TNF‐α and IL‐1β levels were investigated in these three groups. The MRI findings and clinical characteristics of the patients in the epilepsy group were also compared with these markers. Results: HMGB‐1, TLR4, TNF‐α, and IL‐1β levels in the severe epilepsy group were higher than in the control group and the mild epilepsy group (p<0.05), and were higher in the mild epilepsy group than in the control group (p<0.05). IL‐1R1 was also higher in the severe epilepsy group than in the control group (p<0.05). Conclusion: In this first report to identity a possible correlation between HMGB‐1, TLR4, IL‐1β, IL‐1R1, and TNF‐α levels and severity of epilepsy, our data demonstrates that the serum level of these cytokines is higher in cases of drug‐refractory epilepsy.     

Facilitated CA1 hippocampal synaptic plasticity in dystrophin‐deficient mice: Role for GABAA receptors?

Duchenne muscular dystrophy (DMD) is associated with cognitive deficits that may result from a deficiency in the brain isoform of the cytoskeletal membrane-associated protein, dystrophin. CA1 hippocampal short-term potentiation (STP) of synaptic transmission is increased in dystrophin-deficient mdx mice, which has been attributed to a facilitated activation of NMDA receptors. In this study, extracellular recordings in the hippocampal slice preparation were used first to determine the consequences of this alteration on short-term depression (STD). STD induction was facilitated in mdx as compared with wild-type mice in a control medium. Because brain dystrophin deficiency results in a decreased number of gamma-aminobutyric acid A (GABAA)-receptor clusters, we tested the hypothesis that neuronal disinhibition contributes to the enhanced synaptic plasticity in mdx mice. We found that the GABAA receptor antagonist, bicuculline, increased basal neurotransmission in wild-type, but not in mdx mice and prevented the enhanced STP and STD in the CA1 area of slices from mdx mice. The possibility that altered GABA mechanisms underlie the facilitation of NMDA receptor-dependent synaptic plasticity in mdx mice is discussed.     

μ‐Opioid receptor desensitization: homologous or heterologous?

There is considerable controversy over whether μ‐opioid receptor (MOPr) desensitization is homologous or heterologous and over the mechanisms underlying such desensitization. In different cell types MOPr desensitization has been reported to involve receptor phosphorylation by various kinases, including G‐protein‐coupled receptor kinases (GRKs), second messenger and other kinases as well as perturbation of the MOPr effector pathway by GRK sequestration of G protein βγ subunits or ion channel modulation. Here we report that in brainstem locus coeruleus (LC) neurons prepared from relatively mature rats (5–8 weeks old) rapid MOPr desensitization induced by the high‐efficacy opioid peptides methionine enkephalin and DAMGO was homologous and not heterologous to α₂‐adrenoceptors and somatostatin SST₂ receptors. Given that these receptors all couple through G proteins to the same set of G‐protein inwardly rectifying (GIRK) channels it is unlikely therefore that in mature neurons MOPr desensitization involves G protein βγ subunit sequestration or ion channel modulation. In contrast, in slices from immature animals (less than postnatal day 20), MOPr desensitization was observed to be heterologous and could be downstream of the receptor. Heterologous MOPr desensitization was not dependent on protein kinase C or c‐Jun N‐terminal kinase activity, but the change from heterologous to homologous desensitization with age was correlated with a decrease in the expression levels of GRK2 in the LC and other brain regions. The observation that the mechanisms underlying MOPr desensitization change with neuronal development is important when extrapolating to the mature brain results obtained from experiments on expression systems, cell lines and immature neuronal preparations.     

Different subsets of newborn granule cells: a possible role in epileptogenesis?

Several factors, including epileptic seizures, can strongly stimulate ongoing neurogenesis in the adult hippocampus. Although adult‐born granule cells generated after seizure activity have different physiological properties from their normal counterparts, they integrate into the existing, mature network of the adult hippocampal dentate gyrus. However, the exact role of the neurogenic response during epilepsy and its possible involvement in epileptogenesis have remained elusive. Here, we discuss recent studies shedding new light on the interplay between epilepsy and neurogenesis, and try to explain discrepancies in this literature by proposing seizure severity‐dependent induction of two subsets of newborn cells with different properties. We hypothesise that a low seizure intensity would stimulate neurogenesis to a ‘physiological plasticity’ level and have few pathological consequences. In contrast, a high initial seizure intensity may induce a specific subset of altered and/or ectopically located new granule cells with different electrophysiological properties that could initiate hyperexcitatory recurrent networks that could, in turn, contribute to chronic epilepsy. This hypothesis may clarify previously contradictory data in the literature, and could thereby aid in our understanding of the role of neurogenesis in epileptogenesis, and open up promising avenues for therapeutic intervention.     

Tonic inhibition in principal cells of the amygdala: a central role for α3 subunit-containing GABAA receptors

GABAergic inhibition in the amygdala is essential in regulating fear and anxiety. Although fast "phasic" inhibition arising through the activation of postsynaptic GABA(A) receptors (GABA(A)Rs) has been well described in the amygdala, much less is known about extrasynaptic GABA(A)Rs mediating persistent or tonic inhibition and regulating neuronal excitability. Here, we recorded tonic currents in the basolateral (BLA) nucleus and the lateral (LA) nucleus of the amygdala. While all BLA principal cells expressed a robust GABAergic tonic current, only 70% of LA principal cells showed a tonic current. Immunohistochemical stainings revealed that the α3 GABA(A)R subunit is expressed moderately in the LA and strongly throughout the BLA nucleus, where it is located mostly at extrasynaptic sites. In α3 subunit KO mice, tonic currents are significantly reduced in BLA principal cells yet not in LA principal cells. Moreover, the α3 GABA(A)R-selective benzodiazepine site agonist and anxiolytic compound TP003 increases tonic currents and dampens excitability markedly in wild-type BLA principal cells but fails to do so in α3KO BLA cells. Interneurons of the LA and BLA nuclei also express a tonic current, but TP003-induced potentiation is seen in only a small fraction of these cells, suggesting that primarily other GABA(A)R variants underlie tonic inhibition in this cell type. Together, these studies demonstrate that α3 GABA(A)R-mediated tonic inhibition is a central component of the inhibitory force in the amygdala and that tonically activated α3 GABA(A)Rs present an important target for anxiolytic or fear-reducing compounds.     

IGF‐I neuroprotection in the immature brain after hypoxia‐ischemia,involvement of Akt and GSK3β?

Insulin-like growth factor I (IGF-I) is a neurotrophic factor that promotes neuronal growth, differentiation and survival. Neuroprotective effects of IGF-I have previously been shown in adult and juvenile rat models of brain injury. We wanted to investigate the neuroprotective effect of IGF-I after hypoxia-ischemia (HI) in 7-day-old neonatal rats and the mechanisms of IGF-I actions in vivo. We also wanted to study effects of HI and/or IGF-I on the serine/threonine kinases Akt and glycogen synthase kinase 3beta (GSK3beta) in the phophatidylinositol-3 kinase (PI3K) pathway. Immediately after HI, phosphorylated Akt (pAkt) and phosphorylated GSK3beta (pGSK3beta) immunoreactivity was lost in the ipsilateral and reduced in the contralateral hemisphere. After 45 min, pAkt levels were restored to control values, whereas pGSK3beta remained low 4 h after HI. Administration of IGF-I (50 microg i.c.v.) after HI resulted in a 40% reduction in brain damage (loss of microtubule-associated protein) compared with vehicle-treated animals. IGF-I treatment without HI was shown to increase pAkt whereas pGSK3beta decreased in the cytosol, but increased in the nuclear fraction. IGF-I treatment after HI increased pAkt in the cytosol and pGSK3beta in both the cytosol and the nuclear fraction in the ipsilateral hemisphere compared with vehicle-treated rats, concomitant with a reduced caspase-3- and caspase-9-like activity. In conclusion, IGF-I induces activation of Akt during recovery after HI which, in combination with inactivation of GSK3beta, may explain the attenuated activation of caspases and reduction of injury in the immature brain.     

Rostrolateral prefrontal cortex: Domain‐general or domain‐sensitive?

The ability to jointly consider several structured mental representations, or relations, is fundamental to human cognition. Prior studies have consistently linked this capacity for relational integration to rostrolateral prefrontal cortex (RLPFC). Here, we sought to test two competing hypotheses: (1) RLPFC processes relations in a domain-general manner, interacting with different brain regions as a function of the type of lower-level relations that must be integrated; or (2) A dorsal-ventral gradient exists within RLPFC, such that relational integration in the visuospatial domain involves relatively more dorsal RLPFC than integration in the semantic domain. To this end, we examined patterns of fMRI activation and functional connectivity during performance of visuospatial and semantic variants of a relational matching task. Across the two task variants, the regions that were most strongly engaged during relational comparison were left RLPFC and left intraparietal sulcus (IPS). Within left RLPFC, there was considerable overlap in activation for the semantic and visuospatial tasks. However, visuospatial task activation peaks were located dorsally to the semantic task peaks. In addition, RLPFC exhibited differential functional connectivity on the two tasks, interacting with different brain regions as a function of the type of relations being compared. While neurons throughout RLPFC may share the function of integrating diverse inputs, individual RLPFC neurons may have privileged access to particular representations depending on their anatomical inputs, organized along a dorsal-ventral gradient. Thus, RLPFC is well-positioned as a locus of abstraction from concrete, domain-specific details to the general principles and rules that enable higher-level cognition.     

A role for taste receptors in (neuro)endocrinology?

The sense of taste is positioned at the forefront when it comes to the interaction of our body with foodborne chemicals. However, the role of our taste system, and in particular its associated taste receptors, is not limited to driving food preferences leading to ingestion or rejection before other organs take over responsibility for nutrient digestion, absorption and metabolic regulation. Taste sensory elements do much more. On the one hand, extra‐oral taste receptors from the brain to the gut continue to sense nutrients and noxious substances after ingestion and, on the other hand, the nutritional state feeds back on the taste system. This intricate regulatory network is orchestrated by endocrine factors that are secreted in response to taste receptor signalling and, in turn regulate the taste receptor cells themselves. The present review summarises current knowledge on the endocrine regulation of the taste perceptual system and the release of hunger/satiety regulating factors by gastrointestinal taste receptors. Furthermore, the regulation of blood glucose levels via the activation of pancreatic sweet taste receptors and subsequent insulin secretion, as well as the influence of bitter compounds on thyroid hormone release, is addressed. Finally, the central effects of tastants are discussed briefly.