Infant gastrointestinal canthariasis caused by cigarette beetle (Lasioderma serricorne).

Diseases caused by beetle larvae infestation are known as intestinal canthariasis. Canthariasis from the cigarette beetle, Lasioderma serricorne, is quite rare; however, with the accumulation of genetic references, such cases of accidental pseudo-parasitism have been increasingly recognized. Here, we describe a case of asymptomatic gastrointestinal passage of L. serricorne in a 4-year-old male. Larval identification was conducted by PCR-sequencing targeting cytochrome c oxidase subunit 1 using DNA extracted from the larvae. Due to the difficulty of differential identification of beetles using larval morphology, DNA barcoding is essential.

Neurotensinergic Excitation of Dentate Gyrus Granule Cells via Gαq-Coupled Inhibition of TASK-3 Channels.

Neurotensin (NT) is a 13-amino acid peptide and serves as a neuromodulator in the brain. Whereas NT has been implicated in learning and memory, the underlying cellular and molecular mechanisms are ill-defined. Because the dentate gyrus receives profound innervation of fibers containing NT and expresses high density of NT receptors, we examined the effects of NT on the excitability of dentate gyrus granule cells (GCs). Our results showed that NT concentration dependently increased action potential (AP) firing frequency of the GCs by the activation of NTS1 receptors resulting in the depolarization of the GCs. NT-induced enhancement of AP firing frequency was not caused indirectly by releasing glutamate, GABA, acetylcholine, or dopamine, but due to the inhibition of TASK-3 K(+) channels. NT-mediated excitation of the GCs was G protein dependent, but independent of phospholipase C, intracellular Ca(2+) release, and protein kinase C. Immunoprecipitation experiment demonstrates that the activation of NTS1 receptors induced the association of Gαq/11 and TASK-3 channels suggesting a direct coupling of Gαq/11 to TASK-3 channels. Endogenously released NT facilitated the excitability of the GCs contributing to the induction of long-term potentiation at the perforant path-GC synapses. Our results provide a cellular mechanism that helps to explain the roles of NT in learning and memory.

Activation of neurotensin receptor 1 facilitates neuronal excitability and spatial learning and memory in the entorhinal cortex: beneficial actions in an Alzheimer's disease model.

Neurotensin (NT) is a tridecapeptide distributed in the CNS, including the entorhinal cortex (EC), a structure that is crucial for learning and memory and undergoes the earliest pathological alterations in Alzheimer's disease (AD). Whereas NT has been implicated in modulating cognition, the cellular and molecular mechanisms by which NT modifies cognitive processes and the potential therapeutic roles of NT in AD have not been determined. Here we examined the effects of NT on neuronal excitability and spatial learning in the EC, which expresses high density of NT receptors. Brief application of NT induced persistent increases in action potential firing frequency, which could last for at least 1 h. NT-induced facilitation of neuronal excitability was mediated by downregulation of TREK-2 K(+) channels and required the functions of NTS1, phospholipase C, and protein kinase C. Microinjection of NT or NTS1 agonist, PD149163, into the EC increased spatial learning as assessed by the Barnes Maze Test. Activation of NTS1 receptors also induced persistent increases in action potential firing frequency and significantly improved the memory status in APP/PS1 mice, an animal model of AD. Our study identifies a cellular substrate underlying learning and memory and suggests that NTS1 agonists may exert beneficial actions in an animal model of AD.

Maternal administration of the herbal medicine toki-shakuyaku-san promotes fetal growth and placental gene expression in normal mice.

Toki-shakuyaku-san (TSS), an herbal formula based on traditional Chinese medicine, is commonly used in obstetrics. To examine the effects of TSS on the normal mouse fetus and placenta, TSS was administered to normal pregnant mice and their placentas and fetuses were studied. First, the effects of maternal TSS treatment on implantation were investigated. Administration of TSS from gestation day 0.5 (G0.5) to G6.5 showed that litter size was not altered at embryonic day 11.5 (E11.5), but the number of resorbed fetuses was slightly decreased. Then, to investigate effects on fetal and placental growths after implantation, TSS was administered from G5.5. At E14.5, the body weight of fetuses from TSS-treated dams was significantly increased. Gene expression of insulin-like growth factor 2 (Igf2), one of the most important modulators of fetal growth, was significantly increased in the placentas and fetuses of TSS-treated dams. In addition, the expression of particular placental developmental genes and nutrient transporter genes was significantly increased in TSS-treated placentas. At E18.5, after longer-term administration of TSS, fetal and placental weights were not altered, but the expression of the placental developmental and nutrient transporter genes remained elevated compared with controls. These results suggest that maternal TSS treatment in normal mice enhances the expression of Igf2, placental developmental genes and nutrient transporter genes, resulting in increased fetal weight. No obvious changes were observed in the expression of these genes after longer-term maternal TSS treatment.

NMDAR2B tyrosine phosphorylation is involved in thermal nociception.

Previous studies found that the NMDA receptor-mediated signaling regulates thermal nociception, though the underlying molecular mechanism remains unclear. The GluN2B subunit of the NMDA receptor is tyrosine-phosphorylated, Tyr-1472 being the major phosphorylation site. In this study, we have found that homozygous knock-in mice that express a Tyr-1472-Phe mutant of GluN2B display defects in the nociceptive response in the hot plate test. Expression of the neurotensin receptor subtype 2 (NTSR2), which is relevant to the regulation of thermal nociception, is decreased in the amygdala of GluN2B Tyr-1472-Phe knock-in mice. In addition, NTSR2-mediated c-fos induction is impaired in the amygdala of these mice. These data suggest that Tyr-1472 phosphorylation on GluN2B is involved in thermal nociception through regulating the NTSR2 mRNA expression in the amygdala.

The neuropeptide neuromedin U promotes autoantibody-mediated arthritis.

INTRODUCTION: Neuromedin U (NMU) is a neuropeptide with pro-inflammatory activity. The primary goal of this study was to determine if NMU promotes autoantibody-induced arthritis. Additional studies addressed the cellular source of NMU and sought to define the NMU receptor responsible for its pro-inflammatory effects. METHODS: Serum containing arthritogenic autoantibodies from K/BxN mice was used to induce arthritis in mice genetically lacking NMU. Parallel experiments examined whether NMU deficiency impacted the early mast-cell-dependent vascular leak response induced by these autoantibodies. Bone-marrow chimeric mice were generated to determine whether pro-inflammatory NMU is derived from hematopoietic cells or stromal cells. Mice lacking the known NMU receptors singly and in combination were used to determine susceptibility to serum-transferred arthritis and in vitro cellular responses to NMU. RESULTS: NMU-deficient mice developed less severe arthritis than control mice. Vascular leak was not affected by NMU deficiency. NMU expression by bone-marrow-derived cells mediated the pro-arthritogenic effect. Deficiency of all of the known NMU receptors, however, had no impact on arthritis severity and did not affect the ability of NMU to stimulate intracellular calcium flux. CONCLUSIONS: NMU-deficient mice are protected from developing autoantibody-induced inflammatory arthritis. NMU derived from hematopoietic cells, not neurons, promotes the development of autoantibody-induced inflammatory arthritis. This effect is mediated by a receptor other than the currently known NMU receptors.

ß-Lactotensin derived from bovine ß-lactoglobulin exhibits anxiolytic-like activity as an agonist for neurotensin NTS(2) receptor via activation of dopamine D(1) receptor in mice.

ß-Lactotensin (His-Ile-Arg-Leu) is a bioactive peptide derived from bovine milk ß-lactoglobulin, acting as a natural agonist for neurotensin receptors. We found that ß-lactotensin exhibited anxiolytic-like activity in an elevated plus-maze test after its intraperitoneal (i.p.) administration in mice. ß-Lactotensin was also orally active. The anxiolytic-like activity of ß-lactotensin after i.p. administration was blocked by levocabastine, an antagonist for the neurotensin NTS(2) receptor. ß-Lactotensin had anxiolytic-like activity in wild-type but not Ntsr2-knockout mice. ß-Lactotensin increased intracellular Ca(2+) flux in glial cells derived from wild-type mice but not Ntsr2 knockout mice. These results suggest that ß-lactotensin acts as an NTS(2) receptor agonist having anxiolytic-like activity. The anxiolytic-like activity of ß-lactotensin was also blocked by SCH23390 and SKF83566, antagonists for dopamine D(1) receptor, but not by raclopride, an antagonist for D(2) receptor. Taken together, ß-lactotensin may exhibit anxiolytic-like activity via NTS(2) receptor followed by D(1) receptor.

Lack of neurotensin type 1 receptor facilitates contextual fear memory depending on the memory strength.

Neurotensin is known to have antipsychotic-like behavioral and neurochemical effects, but its participation in fear memory has not been fully elucidated. Here, we report that a lack of type 1 neurotensin receptor (Ntsr1) increases the behavioral fear response elicited by weak fear memory. Adult Ntsr1-knockout (KO) mice and their wild-type (WT) littermates were compared in contextual fear conditioning. The mice were exposed twice for 3min to the context 24 and 48h after conditioning (first and second exposure, respectively), and freezing response of mice at the exposure was measured to evaluate fear memory. Ntsr1-KO mice showed a higher freezing rate than WT mice at both first and second exposures under the condition where a relatively weak unconditioned stimulus (footshock) was applied and thus elicited a relatively lower freezing rate. The difference in the first exposure between Ntsr1-KO and WT mice disappeared under the condition where a more intense unconditioned stimulus was used. The enhancement of freezing response in Ntsr1-KO mice at second exposure was abolished by propranolol, a beta-adrenergic blocker that suppresses fear memory reconsolidation, and suppressed by MK-801, an NMDA receptor antagonist. These results suggest that Ntsr1 plays inhibitory roles in weak fear memory.

Maternal obesity impairs hippocampal BDNF production and spatial learning performance in young mouse offspring.

Maternal obesity may affect the child's long-term development and health, increasing the risk of diabetes and metabolic syndrome. In addition to the metabolic and endocrine systems, recent reports have indicated that maternal obesity also modulates neural circuit formation in the offspring. However, this not yet been fully investigated. Here, we examined the effect of diet-induced maternal obesity on hippocampal development and function in the mouse offspring. Adult female mice were fed either a normal diet (ND, 4% fat) or a high-fat diet (HFD, 32% fat) before mating and throughout pregnancy and lactation. After weaning, all offspring were fed with a normal diet. We found that HFD offspring showed increased lipid peroxidation in the hippocampus during early postnatal development. HFD offspring had less brain-derived neurotrophic factor (BDNF) in the hippocampus than ND offspring. BDNF has been shown to play crucial roles in neuronal differentiation, plasticity and hippocampus-dependent cognitive functions such as spatial learning and memory. Using retroviral labeling, we demonstrated that dendritic arborization of new hippocampal neurons was impaired in the young HFD offspring. Finally, we evaluated cognitive function in these offspring using hippocampus-dependent behavioral tasks. The Barnes maze test demonstrated that HFD offspring showed impaired acquisition of spatial learning in the young but not adult period. This study, using a mouse model, indicates that diet-induced maternal obesity impairs hippocampal BDNF production and spatial cognitive function in young offspring, possibly due to their metabolic and oxidative changes.

Maternal dietary restriction during lactation influences postnatal growth and behavior in the offspring of mice.

It is well known that maternal nutritional status is important to the development of mammalian offspring. We examined the effect of maternal food restriction during lactation on offspring in mice. From 1 to 21 days after parturition, control dams (CDs) were fed with the standard amounts of daily food consumption, whereas dietary restricted dams (RDs) received 70% of daily food consumption. Although the mean body weight of RDs was not significantly different from that of the CDs, body weight of the offspring from RD (RD offspring) was significantly lower than that of the offspring from CD (CD offspring). The difference was detectable until 10 weeks of age. Body lengths and brain weights of RD offspring at postnatal day 22 were lower than those of the CD offspring. Plasma concentrations of leptin in RD offspring decreased significantly. But plasma concentrations of growth hormone and thyroxin were not different between the two groups. In the open field tests, total distance was significantly decreased in RD offspring compared with CD offspring. In the hole-board test, head dip latency was increased and the number of dips was decreased significantly in RD offspring. In the elevated plus maze test, total distance and risk assessment were significantly decreased in the RD offspring. There was no difference between the two groups in the rota-rod and wire-hang tests. These results suggest that maternal dietary restriction during lactation can affect the growth, locomotor activity and anxiety behavior of offspring, but not motor or neuromuscular function.

Female mice target deleted for the neuromedin B receptor have partial resistance to diet-induced obesity.

Previous studies have proposed a role for neuromedin B (NB), a bombesin-like peptide, in the control of body weight homeostasis. However, the nature of this role is unclear. The actions of NB are mediated preferentially by NB-preferring receptors (NBRs). Here we examined the consequences of targeted deletion of NBRs in female mice on body weight homeostasis in mice fed a normolipid diet (ND) or a high-fat diet (HFD) for 13 weeks. Body weight and food ingestion of neuromedin B receptor knockout (NBR-KO) mice fed a normolipid diet showed no difference in relation to wild-type (WT). However, the high-fat diet induced an 8.9- and 4.8-fold increase in body weight of WT and NBR-KO, respectively, compared to their controls maintained with a normolipid diet, even though the mice ingested the same amount of calories, regardless of genotype. Comparing mice fed the high-fat diet, NBR-KO mice accumulated approximately 45% less fat depot mass than WT, exhibited a lower percentage of fat in their carcasses (19.2 vs. 31.3%), and their adipocytes were less hypertrophied. Serum leptin and leptin mRNA in inguinal and perigonadal fat were lower in HFD NBR-KO than HFD WT, and serum adiponectin was similar among HFD groups and unaltered in comparison to ND-fed mice. HFD-fed WT mice developed glucose intolerance but not the HFD-fed NBR-KO mice, although they had similar glycaemia and insulinaemia. NBR-KO and WT mice on the normolipid diet showed no differences in any parameters, except for a trend to lower insulin levels. Therefore, disruption of the neuromedin B receptor pathway did not change body weight homeostasis in female mice fed a normolipid diet; however, it did result in partial resistance to diet-induced obesity.

"Bio-communication" between mother and offspring: lessons from animals and new perspectives for brain science.

Early brain development has a tremendous impact on the success of humans throughout their lives. During early development, neural circuit formation proceeds in a strictly regulated manner. In addition to genetic and epigenetic programs, recent studies using animal models have demonstrated that certain maternal bio-active agents are essential for normal neural development, with deficiencies adversely affecting offspring brain function and behavior. On the basis of these findings, we propose a new viewpoint: that maternal bio-active substances support the development of the fetal and neonatal brain, and the subsequent expression and maintenance of higher brain functions. We term these molecular-based biological conversations between mother and offspring "bio-communications". Based on findings obtained primarily from animal models, we review the effects of maternal substances on the neural developments and functions. Clarifying the regulatory mechanisms of "bio-communications" will help improve understanding of the mechanisms of human brain functioning and neural development. In addition, these findings will be applied to elucidate the mechanisms of developmental disorders and to explore new medical therapies to treat them.

Maternal enrichment affects prenatal hippocampal proliferation and open-field behaviors in female offspring mice.

The maternal environment is thought to be important for fetal brain development. However, the effects of maternal environment are not fully understood. Here, we investigated whether enrichment of the maternal environment can influence prenatal brain development and postnatal behaviors in mice. An enriched environment is a housing condition with several objects such as a running wheel, tube and ladder, which are thought to increase sensory, cognitive and motor stimulation in rodents compared with standard housing conditions. First, we measured the number of BrdU-positive cells in the hippocampal dentate gyrus of fetuses from pregnant dams housed in an enriched environment. Our results revealed that maternal enrichment influences cell proliferation in the hippocampus of female, but not male, fetuses. Second, we used the open-field test to investigate postnatal behaviors in the offspring of dams housed in the enriched environment during pregnancy. We found that maternal enrichment significantly affects the locomotor activity and time spent in the center of the open-field in female, but not male, offspring. These results indicate that maternal enrichment influences prenatal brain development and postnatal behaviors in female offspring.

Diet-induced obesity in female mice leads to peroxidized lipid accumulations and impairment of hippocampal neurogenesis during the early life of their offspring.

Maternal obesity may affect the child's long-term development and health. However, there is little information about the involvement of maternal obesity in the brain development of offspring. Here, we investigated the effects of maternal obesity on the hippocampal formation of offspring. Adult female mice were fed either a normal diet (ND, 4% fat) or a high-fat diet (HFD, 32% fat) 6 wk before mating and throughout pregnancy and the majority of lactation. We found that infants from HFD-fed dams (HFD offspring) showed obesity and hyperlipidemia during suckling. In HFD offspring, lipid peroxidation was promoted in serum and the hippocampal dentate gyrus, where neurogenesis takes place throughout postnatal life. Using a BrdU-pulse labeling study, we showed that malondialdehyde, a product of peroxidized lipids, reduced the proliferation of hippocampal progenitor cells in vitro and that neurogenesis in HFD offspring during postnatal development was similarly lowered relative to the ND animals. These results indicated that maternal obesity impairs hippocampal progenitor cell division and neuronal production in young offspring possibly due to metabolic and oxidative changes.

Maternal supply of BDNF to mouse fetal brain through the placenta.

Gastrointestinal peptides and hormones are known to penetrate through the utero-placental barrier and regulate fetal development. In the present study, we tested permeation of maternal brain-derived neurotrophic factor (BDNF) to fetuses, using BDNF-gene deficient mice and exogenous BDNF administration. At embryonic day 13.5 (E13.5)-14.5, BDNF protein concentrations in the fetal brain of BDNF homozygous null mutant (bdnf (-/-)) were comparable to the levels seen in wild-type fetuses. After E17.5, BDNF protein levels in bdnf (-/-) fetal brain were still detectable but its levels were significantly decreased below those in wild-type brain. When recombinant BDNF protein was injected into pregnant wild-type mice carrying E14.5 embryos, BDNF protein levels in fetal brain were elevated dose-dependently. These findings suggest that maternal BDNF reaches the fetal brain through utero-placental barrier and might contribute to its development.

Ghrelin alters postnatal endocrine secretion and behavior in mouse offspring.

Maternal bioactive substances, such as hormones and neuropeptides, are thought to be essential for fetal development. Recently, ghrelin, a gastrointestinal peptide, has been shown to pass through the rat placenta. The ghrelin receptor, growth hormone secretagogue receptor (GHS-R), has been shown to be expressed in the rat fetal central nervous system, and plasma ghrelin levels are related to birth weight in the rodent and human. In the present study, we report a role of maternal ghrelin in mouse fetal brain development. When ghrelin was administrated to pregnant mice, pups exhibited suppression of exploratory behavior in an open-field (OF) test. Control pups, however, remained for longer periods of time in the center area, correlating with exploratory behavior. Basal corticotropin-releasing hormone (CRH) plasma levels were greater in pups from ghrelin-treated dams, and did not change in response to acute restraint stress. Moreover, reduced growth hormone secretagogue receptor and neuropeptide Y mRNA expression was observed in the hypothalamus at postnatal day 3 and remained until 16 weeks of age. In addition, under physiological condition, increased maternal ghrelin plasma levels following repeated restraint stress to the dam had effect on the increase in fetal plasma acyl ghrelin levels. These results suggest that maternal ghrelin affect fetal plasma ghrelin levels and alters endocrine systems and behaviors of offspring.

Sexually dimorphic gastrin releasing peptide system in the spinal cord controls male reproductive functions.

Neurons in the upper lumbar spinal cord project axons containing gastrin-releasing peptide (GRP) to innervate lower lumbar regions controlling erection and ejaculation. This system is vestigial in female rats and in males with genetic dysfunction of androgen receptors, but in male rats, pharmacological stimulation of spinal GRP receptors restores penile reflexes and ejaculation after castration. GRP offers new avenues for understanding potential therapeutic approaches to masculine reproductive dysfunction.

Neurotensin increases mortality and mast cells reduce neurotensin levels in a mouse model of sepsis.

Sepsis is a complex, incompletely understood and often fatal disorder, typically accompanied by hypotension, that is considered to represent a dysregulated host response to infection. Neurotensin (NT) is a 13-amino-acid peptide that, among its multiple effects, induces hypotension. We find that intraperitoneal and plasma concentrations of NT are increased in mice after severe cecal ligation and puncture (CLP), a model of sepsis, and that mice treated with a pharmacological antagonist of NT, or NT-deficient mice, show reduced mortality during severe CLP. In mice, mast cells can degrade NT and reduce NT-induced hypotension and CLP-associated mortality, and optimal expression of these effects requires mast cell expression of neurotensin receptor 1 and neurolysin. These findings show that NT contributes to sepsis-related mortality in mice during severe CLP and that mast cells can lower NT concentrations, and suggest that mast cell-dependent reduction in NT levels contributes to the ability of mast cells to enhance survival after CLP.

Heightened amygdala long-term potentiation in neurotensin receptor type-1 knockout mice.

Neurotensin receptor type-1 (Ntsr1) is the main receptor subtype that underlies neurotensin (NT)-mediated modulation of the dopamine (DA) system. Although NT and DA coexist in the basolateral nucleus of the amygdala (BLA), the function of Ntsr1 in the amygdala is not well characterized. In the present study, we utilized Ntsr1 knockout (Ntsr1-KO) mice to examine the role of Ntsr1 in the amygdala. In acute brain slices of Ntsr1-KO mice, synaptic currents elicited in BLA pyramidal neurons by electrical stimulation of the lateral nucleus of the amygdala (LA) were greatly potentiated by tetanic stimulation (BLA-long-term potentiation (LTP)). Such potentiation was not evident in pyramidal neurons of wild-type mice. In the presence of an antagonist of Ntsr1, SR48692, BLA-LTP was consistently observed in the neurons of wild-type mice, suggesting that both inherited deletion and acute pharmacological blockade of Ntsr1 induce BLA-LTP. BLA-LTP in Ntsr1-KO mice was impaired by sulpiride, a DA D(2)-like receptor antagonist. Conversely, quinpirole, a D(2)-like receptor agonist, induced pronounced BLA-LTP in wild-type mice, suggesting the upregulation of D(2)-like receptor activity in Ntsr1-KO mice. The ratio of NMDA receptor-mediated to non-NMDA receptor-mediated synaptic currents in Ntsr1-KO mouse BLA neurons was approximately double that measured in wild-type mouse neurons. Furthermore, quinpirole potentiated NMDA receptor-mediated synaptic currents in the BLA of wild-type mice. These results suggest that, without Ntsr1, synaptic responses from the LA to BLA pyramidal neurons undergo LTP in response to tetanus stimulation through facilitation of D(2)-like receptor-induced activation of NMDA receptors.

Impaired serum thyrotropin response to hypothyroidism in mice with disruption of neuromedin B receptor.

Neuromedin B (NB), a neuropeptide highly concentrated in pituitary, has been proposed to be an inhibitor of thyrotropin (TSH) secretion. Previous study showed that mice with disruption of neuromedin B receptor (NBR-KO) have higher TSH release in response to thyrotropin-releasing hormone (TRH), although TSH seems to have decreased bioactivity. Here we examined in NBR-KO mice the response of TSH to thyroid hormone (TH) deprivation, obtained by methimazole treatment, or excess, obtained by acute and chronic TH administration. In response to hypothyroidism NBR-KO mice exhibited a lower magnitude increase in serum TSH compared to wild-type (WT) mice (1.7 vs. 3.3-times increase compared to euthyroid values, respectively, P<0.001). One hour after a single T4 injection (0.4 microg/100 g BW), WT and NBR-KO hypothyroid mice presented similar degree of serum TSH reduction (54%, P<0.05). However, 3 h after T4 administration, WT mice presented serum TSH similar to hypothyroid baseline, while NBR-KO mice still had decreased serum TSH (30% reduced in comparison to hypothyroid baseline P<0.05). T3 treatment of euthyroid mice for 21 days, with progressively increasing doses, significantly reduced serum TSH similarly in WT and NBR-KO mice. Also, serum T4 exhibited the same degree of suppression in WT and NBR-KO. In conclusion, disruption of neuromedin B receptor did not interfere with the sensitivity of thyroid hormone-mediated suppression of TSH release, but impaired the ability of thyrotroph to increase serum TSH in hypothyroidism, which highlights the importance of NB in modulating the set point of the hypothalamus-pituitary-thyroid axis at hypothyroidism.