Prokineticin 2 regulates the electrical activity of rat suprachiasmatic nuclei neurons

Neuropeptide signaling plays roles in coordinating cellular activities and maintaining robust oscillations within the mammalian suprachiasmatic nucleus (SCN). Prokineticin2 (PK2) is a signaling molecule from the SCN and involves in the generation of circadian locomotor activity. Prokineticin receptor 2 (PKR2), a receptor for PK2, has been shown to be expressed in the SCN. However, very little is known about the cellular action of PK2 within the SCN. In the present study, we investigated the effect of PK2 on spontaneous firing and miniature inhibitory postsynaptic currents (mIPSCs) using whole cell patch-clamp recording in the SCN slices. PK2 dose-dependently increased spontaneous firing rates in most neurons from the dorsal SCN. PK2 acted postsynaptically to reduce γ-aminobutyric acid (GABA)-ergic function within the SCN, and PK2 reduced the amplitude but not frequency of mIPSCs. Furthermore, PK2 also suppressed exogenous GABA-induced currents. And the inhibitory effect of PK2 required PKC activation in the postsynaptic cells. Our data suggest that PK2 could alter cellular activities within the SCN and may influence behavioral and physiological rhythms.     

Efferent Projections of Prokineticin 2 Expressing Neurons in the Mouse Suprachiasmatic Nucleus

The suprachiasmatic nucleus (SCN) in the hypothalamus is the predominant circadian clock in mammals. To function as a pacemaker, the intrinsic timing signal from the SCN must be transmitted to different brain regions. Prokineticin 2 (PK2) is one of the candidate output molecules from the SCN. In this study, we investigated the efferent projections of PK2-expressing neurons in the SCN through a transgenic reporter approach. Using a bacterial artificial chromosome (BAC) transgenic mouse line, in which the enhanced green fluorescence protein (EGFP) reporter gene expression was driven by the PK2 promoter, we were able to obtain an efferent projections map from the EGFP-expressing neurons in the SCN. Our data revealed that EGFP-expressing neurons in the SCN, hence representing some of the PK2-expressing neurons, projected to many known SCN target areas, including the ventral lateral septum, medial preoptic area, subparaventricular zone, paraventricular nucleus, dorsomedial hypothalamic nucleus, lateral hypothalamic area and paraventricular thalamic nucleus. The efferent projections of PK2-expressing neurons supported the role of PK2 as an output molecule of the SCN.     

刺激中缝背核对视交叉上核光敏神经元单位放电的影响

本实验观察刺激中缝背核对大鼠视交叉上核光敏神经元单位放电的影响,并进行药理学分析。结果表明,刺激ＤＲ能明显抑制ＳＣＮ神经元光诱发放电,这种抑制作用能被单胺氧化酶抑制剂优降宁增强,能被５－ＨＴ合成抑制剂对氯苯丙氨酸减弱,还能被５－ＨＴ受体拮抗剂赛庚啶阻断。结果提示,５－ＨＴ参与了刺激ＤＲ对ＳＣＮ光敏神经元放电的抑制。     

胃伤害性刺激诱导大鼠脑干星形胶质细胞GFAP蛋白表达及其与神经元的关系

研究大鼠在福尔马林诱发胃伤害性刺激时脑干内星形胶质细胞及神经元的变化。应用免疫组织化学三重标记法在脑原位切片同时显示脑干内Fos蛋白,胶质原纤维酸性蛋白（GFAP）,酪氨酸羟化酶（TH）的表达,结果显示：1、在福尔马林诱发胃伤害性刺激后,脑干胶质细胞GFAP表达阳性,并表现出明显的核团或亚核定位特点,在延髓内脏带（MVZ0,中缝大核（RMg),蓝斑（LC）,臂旁外侧核（LPB）,中缝背核（DR）,中脑导水管周围灰质腹外侧区（vlPAG),上丘中灰层（IngSC)等脑区有较多的Fos阳性细胞,而且Fos阳性表达的分布与上述GFAP阳性分布基本一致;2、MVZ,LC,DR,vlPAG等部位有大量Fos及TH双标阳性神经元,周围有密集的GFAP阳性细胞;3、随着刺激后存活时间的变化,GFAP与Fos阳性细胞的反应均经历逐渐升高后又渐降低直至消失的变化。结果表明：上述核团的神经元和星形胶质细胞可能同时参与了内脏痛及其调节过程。     

胃肠道伤害性刺激诱导中缝背核触液神经元Fos表达

本文以ＣＢ－ＨＲＰ逆行追踪和原癌基因ｃ－ｆｏｓ表达技术相结合,观察胃肠道伤害性刺激后中缝背核触液神经元Ｆｏｓ的表达。在中缝背核发现三种标记神经元,包括ＣＢ－ＨＲＰ逆行标记神经元（３０８）、Ｆｏｓ阳性神经元（４２）和ＣＢ－ＨＲＰ／Ｆｏｓ双重标记神经元（５）。本研究提示中缝背核含有一些具有双重功能的神经元,它们既在脑－脑脊液神经体液回路中传递信息,又在胃肠道伤害性刺激的中枢传递和功能调控中起一定的作用     

Substance P and neurokinin-1 immunoreactivities in the neural circadian system of the Alaskan northern red-backed vole, Clethrionomys rutilus

The suprachiasmatic nucleus (SCN) of the hypothalamus houses the main mammalian circadian clock. This clock is reset by light-dark cues and stimuli that evoke arousal. Photic information is relayed directly to the SCN via the retinohypothalamic tract (RHT) and indirectly via the geniculohypothalamic tract, which originates from retinally innervated cells of the thalamic intergeniculate leaflet (IGL). In addition, pathways from the dorsal and median raphe (DR and MR) convey arousal state information to the IGL and SCN, respectively. The SCN regulates many physiological events in the body via a network of efferent connections to areas of the brain such as the habenula (Hb) in the epithalamus, subparaventricular zone (SPVZ) of the hypothalamus and locus coeruleus of the brainstem-areas of the brain associated with arousal and behavioral activation. Substance P (SP) and the neurokinin-1 (NK-1) receptor are present in the rat SCN and IGL, and SP acting via the NK-1 receptor alters SCN neuronal activity and resets the circadian clock in this species. However, the distribution and role of SP and NK-1 in the circadian system of other rodent species are largely unknown. Here we use immunohistochemical techniques to map the novel distribution of SP and NK-1 in the hypothalamus, thalamus and brainstem of the Alaskan northern red-backed vole, Clethrionomys rutilus, a species of rodent currently being used in circadian biology research. Interestingly, the pattern of immunoreactivity for SP in the red-backed vole SCN was very different from that seen in many other nocturnal and diurnal rodents.     

大白鼠脚内核的传入性联系

众所周知,肉食动物和大白鼠的脚内核,相当于灵长类的内侧苍白球(Nagy et al.1978;Fox and Schmitz 1944);它们的细胞形态、传入及传出均相同。早期以及近年来的一些研究工作者,虽然在研究其他核团的投射时,联系到一些本核团的传入,但是尚缺乏对本核团传人的系统研究。本实验即是应用辣根过氧化物酶的逆行传递法来研究大白鼠脚内核的传入性联系。     

Brain expression of Cre recombinase driven by pancreas‐specific promoters

Cre‐loxP technology enables specific examination of the function and development of individual nuclei in the complex brain network. However, for most brain regions, the utilization of this technique has been hindered by the lack of mouse lines with Cre expression restricted to these regions. Here, we identified brain expressions of three transgenic Cre lines previously thought to be pancreas‐specific. Cre expression driven by the rat‐insulin promoter (Rip‐Cre) was found mainly in the arcuate nucleus, and to a lesser degree in other hypothalamic regions. Cre expression driven by the neurogenin 3 promoter (Ngn3‐Cre mice) was found in the ventromedial hypothalamus. Cre expression driven by the pancreas‐duodenum homeobox 1 promoter (Pdx1‐Cre) was found in several hypothalamic nuclei, the dorsal raphe and inferior olivary nuclei. Interestingly, Pdx1‐Cre mediated deletion of vesicular GABA transporter led to postnatal growth retardation while Ngn3‐Cre mediated deletion had no effects, suggesting a role for Pdx1‐Cre neurons, but not pancreas, in the regulation of postnatal growth. These results demonstrate the potential for these Cre lines to study the function and development of brain neurons. genesis 48:628–634, 2010. © 2010 Wiley‐Liss, Inc.     

Heterogeneous Expression of Transketolase in Rat Brain

Abstract: Transketolase (TK; EC 2.2.1.1) is a key pentose phosphate shunt enzyme that plays an important role in the production of reducing equivalents and pentose sugars. TK activity declines in the brains of patients with Alzheimer's disease or Wernicke-Korsakoff syndrome, as well as in thiamine-deficient rats. Understanding the role of TK in the pathophysiology of these neurodegenerative conditions requires knowledge of its regional, cellular, and subcellular distribution within the brain. The current study employed in situ hybridization and immunocytochemistry to examine the distribution of TK mRNA and its encoded protein in adult rat brain. TK mRNA and protein were widely distributed throughout the brain. However, they were enriched in selective perikarya in the piriform cortex, nucleus of the diagonal band, red nucleus, dorsal raphe, pontine nucleus, locus coeruleus, trapezoid, inferior olive, and several cranial nerve nuclei. Lower expression of TK mRNA and protein occurred in layer V of cortex, olfactory tubercle, ventral pallidum, medial septal nucleus, hippocampus, thalamic and hypothalamic nuclei, mammillary body, central gray, and the substantia nigra. TK immunoreactivity also occurred in the nuclei of ubiquitously distributed glial cells, as well as ependymal cells. The heterogeneous distribution of TK may reflect a variety of metabolic activities among different brain regions but does not provide a simple molecular explanation for selective cell death in either thiamine deficiency or other conditions where TK is reduced.     

Locomotor activity after various radiofrequency lesions of the limbic midbrain area in the rat evidence for a particular role of the ventral mesencephalic tegmentum

Radiofrequency lesions were made in each structure of the Limbic Midbrain Area (LMA) : Gudden nuclei, raphe nuclei, mesencephalic ventral tegmentum (VMT), and locomotor activity was measured in a circular corridor 10 and 30 days after surgery. The first hour of exploration, the nocturnal basal activity and the diurnal basal activity were distinguished. During the exploratory phase the Gudden nuclei and VMT lesions induced hyperactivity, while dorsal raphe lesions provoked significant hypoactivity; during the light period VMT lesions and, to a less extent, dorsal Gudden nucleus lesions provoked hyperactivity. From these results it is assumed that the VMT represents a specific part of the LMA, where lesions provoked the most important activity disturbances.     

Arginine8-vasopressin affects catecholamine metabolism in specific brain nuclei

Following the i.c.v. administration of arginine⁸-vasopressin (30 ng in 1 μl saline) to rats that had been injected i.p with α-MPT 30 min prior to the administration of the peptide catecholamine metabolism was altered in a restricted number of brain nuclei. Noradrenaline disappearance was accelerated as compared to saline treated controls in the dorsal septal nucleus, the anterior hypothalamic nucleus, the medial forebrain bundle, the parafascicular nucleus, the dorsal raphe nucleus, the locus coeruleus, the nucleus tractus solitarii and the Al-region. In the supraoptic nucleus and the nucleus ruber a decreased noradrenaline disappearnce was observed after the administration of the peptide. Dopamine disappearance was accelerated in the caudate nucleus, the median eminence, the dorsal raphe nucleus and the A8-region. These results support the view that vasopressin is participating in the regulation of a variety of physiological processes by modulating neurotransmission in specific brain nuclei.     

Regional distribution and cellular expression of tryptophan hydroxylase messenger RNA in postmortem human brainstem and pineal gland

The characterization and cellular localization of tryptophan hydroxylase mRNA in the human brainstem and pineal gland were investigated by using northern blot analysis and in situ hybridization histochemistry. Northern analysis of human pineal gland revealed the presence of two mRNA species that were absent in RNA isolated from human raphe. In situ hybridization experiments revealed very dense hybridization signal corresponding to tryptophan hydroxylase mRNA in cells throughout the pineal gland. In contrast, tryptophan hydroxylase mRNA was heterogeneously distributed in neurons in the dorsal and median raphe nuclei. Within the dorsal raphe, the ventrolateral and interfascicular subnuclei contained the greatest number of tryptophan hydroxylase mRNA-positive neurons. Also, the cellular concentration of tryptophan hydroxylase mRNA varied widely within the dorsal and median raphe. Comparison of the cellular concentration of tryptophan hydroxylase mRNA between the pineal gland and the raphe nuclei revealed an 11- and 46-fold greater average grain density of tryptophan hydroxylase mRNA positive cells in the pineal gland compared with the dorsal and median raphe, respectively. These findings are the first to demonstrate the cellular localization of tryptophan hydroxylase mRNA in the human brain and pineal gland as well as heterogeneity in the cellular concentration within and between these tissues.     

Developmental changes in the brain-stem serotonergic nuclei of teleost fish and neural plasticity

Summary 1. During early ontogeny, the serotonergic neurons in the brain stem of the three-spined stickleback shows a temporal and spatial developmental pattern that closely resembles that of amniotes.2. However, in the adult fish, only the midline nuclei of the rostral group (dorsal and median raphe nuclei) and the dorsal lateral tegmental nucleus are consistently serotonin-immunoreactive (5-HTir), whereas the groups of the upper and lower rhombencephalon (raphe pontis, raphe magnus, and raphe pallidus/obscurus nuclei) are variable and, when present, contain relatively small numbers of 5-HTir neurons.3. Using specific antisera against tryptophan 5-hydroxylase and aromaticl-amino acid decarboxylase, we have shown that the lateral B9 group and the groups of the upper and lower rhombencephalon are consistently present in adult sticklebacks. The results are discussed in relation to other known instances of neurotransmitter plasticity or transient neurotransmitter expression in teleost fish.4. While there are several instances of transient expression of neurotransmitter markers by discrete neuronal populations, there is so far no evidence of changes from one neurotransmitter phenotype to another in the brain of teleost fish. However, there are indications of plasticity of expression of catecholamines and indoleamines, and their respective synthesizing enzymes, as reflected in age-dependent changes and variation between individuals of different physiological status.5. As the brain grows continuously in teleost fish, and new neurons are added from proliferative regions, synaptic connections may be expected to undergo remodeling in all brain regions throughout life. Thus, the teleostean brain may be considered a suitable model for experimental studies of different aspects of neural plasticity.     

Caudal Brainstem Raphe Nuclei: Neural Substrate for their Involvement in the Expression of Some Biological Rhythms

Nucleus raphe pallidus (RPa) lies ventrally in the caudal brainstem, where it is coextensive rostrally with the nucleus raphe magnus (RMg) and caudally with the nucleus raphe obscurus (ROb). Retrograde neuronal tracing studies of our laboratory, carried out in rats and presented elsewhere, with fluorogold, true-blue or fast-blue, iontophoretically injected or by crystalline deposit, along the RPa extent, displayed many labeled pericaria at the preoptic area (POA), as well as lateral (LH) and dorsomedial (DMH) hypothalamus; paraventricular nucleus (PVN) and dorsal (DR) and median (MnR) raphe nuclei among others structures. In addition, RPa, which projects to the intermediolateral column, has been demonstrated to bear relation to many of the somatic-visceral functions also reported for POA. Iontophoretic injections of PHA-L, an anterograde tracer, in the POA subnuclei, presented terminal and varicose labeled fibers in RPa, as well as in the RMg, ROb, paraventricular thalamic (PVA), PVN and supraoptic nucleus (SO), LH, subparaventricular zone (sPVZ) and locus coeruleus (LC). Interestingly, POA, PVA, PVN, LH and SO have been described as retino- and suprachiasmatic-recipients. Taken together, these neuronal connections between brainstem raphe nuclei and POA, the similarity of functions to which they are related, as well as connections with other retino-suprachiasmatic-recipient structures, suggest that these caudal brainstem raphe nuclei could be part of the output system for the expression of some biological rhythms.     

Caudal Brainstem Raphe Nuclei: Neural Substrate for their Involvement in the Expression of Some Biological Rhythms

Nucleus raphe pallidus (RPa) lies ventrally in the caudal brainstem, where it is coextensive rostrally with the nucleus raphe magnus (RMg) and caudally with the nucleus raphe obscurus (ROb). Retrograde neuronal tracing studies of our laboratory, carried out in rats and presented elsewhere, with fluorogold, true-blue or fast-blue, iontophoretically injected or by crystalline deposit, along the RPa extent, displayed many labeled pericaria at the preoptic area (POA), as well as lateral (LH) and dorsomedial (DMH) hypothalamus; paraventricular nucleus (PVN) and dorsal (DR) and median (MnR) raphe nuclei among others structures. In addition, RPa, which projects to the intermediolateral column, has been demonstrated to bear relation to many of the somatic-visceral functions also reported for POA. Iontophoretic injections of PHA-L, an anterograde tracer, in the POA subnuclei, presented terminal and varicose labeled fibers in RPa, as well as in the RMg, ROb, paraventricular thalamic (PVA), PVN and supraoptic nucleus (SO), LH, subparaventricular zone (sPVZ) and locus coeruleus (LC). Interestingly, POA, PVA, PVN, LH and SO have been described as retino- and suprachiasmatic-recipients. Taken together, these neuronal connections between brainstem raphe nuclei and POA, the similarity of functions to which they are related, as well as connections with other retino-suprachiasmatic-recipient structures, suggest that these caudal brainstem raphe nuclei could be part of the output system for the expression of some biological rhythms.     

Expression mapping of cytotoxic T-lymphocyte antigen-2α gene transcripts in mouse brain

Cytotoxic T-lymphocyte antigen-2alpha (CTLA-2alpha), an inhibitor peptide homologous to the proregion of mouse cathepsin L, was originally discovered and expressed in mouse-activated T-cells and mast cells. Expressed recombinant CTLA-2alpha is shown to exhibit selective inhibition to cathepsin L-like cysteine proteinases. However, its in vivo targets in mammalian tissues are yet to be identified. We carried out in situ hybridization studies to examine the expression pattern of CTLA-2alpha mRNA and determine the specific cell types synthesizing CTLA-2alpha in the mouse brain. CTLA-2alpha mRNA was detected in various neuronal populations within the telencephalon in cerebral cortices, olfactory system, septum, basal ganglia, amygdala and highest levels were observed in the hippocampus. Within the diencephalon high density of positive cells was found in mediodorsal and lateral posterior thalamic nuclei and medial habenular nucleus (MHb). In the hypothalamus, high density of CTLA-2alpha mRNA labeling was seen in the suprachiasmatic nucleus (Sch), optic tract, arcuate nucleus, and median eminence. The fasciculus retroflexus and its termination in the mesencephalic interpeduncular nucleus were also densely labeled. Other mesencephalic expression sites were the superior colliculus, periaqueductal gray, paramedian raphe nucleus, and inferior colliculus. In the rhombencephalon, strong labeling was detected in the pontine, vestibular, and reticular nuclei. Intense expression was also noted within cerebellar cortex in Purkinje neurons and at a moderate level in granule cell layer, stellate, and basket cells. A possible function of this novel inhibitor peptide in relation to learning, memory, and diseases is discussed.