Ovarian steroids and serotonin neural function

The serotonin neural system originates from ten nuclei in the mid- and hindbrain regions. The cells of the rostral nuclei project to almost every area of the forebrain, including the hypothalamus, limbic regions, basal ganglia, thalamic nuclei, and cortex. The caudal nuclei project to the spinal cord and interact with numerous autonomic and sensory systems. This article reviews much of the available literature from basic research and relevant clinical research that indicates that ovarian steroid hormones, estrogens and progestins, affect the function of the serotonin neural system. Experimental results in nonhuman primates from this laboratory are contrasted with studies in rodents and humans. The sites of action of ovarian hormones on the serotonin neural system include effects within serotonin neurons as well as effects on serotonin afferent neurons and serotonin target neurons. Therefore, information on estrogen and progestin receptor-containing neurons was synthesized with information on serotonin afferent and efferent circuits. The ability of estrogens and progestins to alter the function of the serotonin neural system at various levels provides a cellular mechanism whereby ovarian hormones can impact mood, cognition, pain, and numerous other autonomic functions.     

The morphology of suboesophageal ganglion cells innervating the nervus corporis cardiaci III of the locust

Summary The nervus corporis cardiaci III (NCC III) of the locust Locust migratoria was investigated with intracellular and extracellular cobalt staining techniques in order to elucidate the morphology of neurons within the suboesophageal ganglion, which send axons into this nerve. Six neurons have many features in common with the dorsal, unpaired, median (DUM) neurons of thoracic and abdominal ganglia. Three other cells have cell bodies contralateral to their axons (contralateral neuron 1–3; CN 1–3). Two of these neurons (CN2 and CN3) appear to degenerate after imaginal ecdysis. CN3 innervates pharyngeal dilator muscles via its anterior axon in the NCC III, and a neck muscle via an additional posterior axon within the intersegmental nerve between the suboesophageal and prothoracic ganglia. A large cell with a ventral posterior cell body is located close to the sagittal plane of the ganglion (ventral, posterior, median neuron; VPMN). Staining of the NCC III towards the periphery reveals that the branching pattern of this nerve is extremely variable. It innervates the retrocerebral glandular complex, the antennal heart and pharyngeal dilator muscles, and has a connection to the frontal ganglion.Abbreviations AH antennal heart - AN antennal nerves - AO aorta - AV antennal vessel - CA corpus allatum - CC corpus cardiacum - CN1, CN2, CN3 contralateral neuron 1–3 - DIT dorsal intermediate tract - DMT dorsal median tract - DUM dorsal, unpaired, median - FC frontal connective - FG frontal ganglion - HG hypocerebral ganglion - LDT lateral dorsal tract - LMN, LSN labral motor and sensory nerves - LN+FC common root of labral nerves and frontal connective - LO lateral ocellus - MDT median dorsal tract - MDVR ventral root of mandibular nerve - MVT median ventral tract - NCA I, II nervus corporis allati I, II - NCC I, II, III nervus corporis cardiaci I, III - NR nervus recurrens - NTD nervus tegumentarius dorsalis - N8 nerve 8 of SOG - OE oesophagus - OEN oesophageal nerve - PH pharynx - SOG suboesophageal ganglion - T tentorium - TVN tritocerebral ventral nerve - VLT ventral lateral tract - VIT ventral intermediate tract - VMT ventral median tract - VPMN ventral, posterior, median neuron - 1–7 peripheral nerves of the SOG - 36, 37, 40–45 pharyngeal dilator muscles     

椎体后凸成形术治疗骨质疏松性椎体压缩骨折的临床研究

摘要目的：随着老龄人口的增多,老年骨质疏松性椎体压缩性骨折（Osteoporotic Vertebral Compression Fracture,ovcr）的发病率也逐年增高。本文探讨椎体后凸成形术（PercutaneousKyphoplasty,PKP）对0VCF的疼痛缓解及功能改善等方面的临床疗效,并探讨其发展过程、作用机理及并发症的防治。方法：回顾性分析2007年1月至2011年12月应用PKP治疗的OVCF158例患者,其中男55例,女103例;患者年龄52--87岁,平均68．7岁。对患者术前、术后1日、术后3个月随访时的疼痛（VAs）及功能情况（ODD进行评价,并对以上数据进行配对t检验。结果：全部病例均顺利完成手术,3例出现椎体间隙渗漏,5例渗漏至椎体周缘,2例骨水泥渗漏至椎管内,无神经根和脊髓受压症状。VAS评分评价,术前（7．60±0．95）分,术后1日（1．00±0．74）分,术后三个月（0．20±0．48）分,术后疼痛缓解有统计学意义（P〈0．01）;ODI,术前（84．94±4-36）％,术后1日（20．47±3．61）％,术后三个月（9．85±3．43m,术后功能恢复有统计学意义（P〈0．01）。结论：PKP术后1日患者疼痛及功能较术前均有明显改善,术后3个月较术后1日亦有进一步的改观。术后后续应用治疗骨质疏松药物及康复治疗可改善患者骨质,预防相邻椎体及其他部位骨质骨折,使疗效更加满意。PKP为治疗OVCF提供了一种安全、有效的方法,可以迅速缓解疼痛,改善功能,具有广阔的应用前景。     

Differential occupation of axial morphospace

The postcranial system is composed of the axial and appendicular skeletons. The axial skeleton, which consists of serially repeating segments commonly known as vertebrae, protects and provides leverage for movement of the body. Across the vertebral column, much numerical and morphological diversity can be observed, which is associated with axial regionalization. The present article discusses this basic diversity and the early developmental mechanisms that guide vertebral formation and regionalization. An examination of vertebral numbers across the major vertebrate clades finds that actinopterygian and chondrichthyan fishes tend to increase vertebral number in the caudal region whereas Sarcopterygii increase the number of vertebrae in the precaudal region, although exceptions to each trend exist. Given the different regions of axial morphospace that are occupied by these groups, differential developmental processes control the axial patterning of actinopterygian and sarcopterygian species. It is possible that, among a variety of factors, the differential selective regimes for aquatic versus terrestrial locomotion have led to the differential use of axial morphospace in vertebrates.     

Role for PKC-epsilon in neuronal death induced by oxidative stress

We investigated which isoforms of PKCs can be modulated and what their roles are during l-buthionine-S,R-sulfoximine (BSO)-induced neuronal death. We observed the isoform specific translocation of PKC-epsilon from the soluble fraction to the particulate in cortical neurons treated with 10 mM BSO. The translocation of PKC-epsilon by BSO was blocked by antioxidant trolox, suggesting the PKC-epsilon as a downstream of reactive oxygen species (ROS) elevated by BSO. Trolox inhibited the ROS elevation and the neuronal death in BSO-treated cortical cells. The BSO-induced neuronal death was remarkably inhibited by both the pharmacological inhibition of PKC-epsilon with epsilonV1-2 and the functional blockade for PKC-epsilon through overexpression of PKC-epsilon V1 region, suggesting the detrimental role of PKC-epsilon. These results suggest that PKC-epsilon is the major PKC isoform involved in the pathways triggered by ROS, leading to neuronal death in BSO-treated cortical neurons.     

Bone marrow-derived mesenchymal stem cells already express specific neural proteins before any differentiation

Bone marrow mesenchymal stem cells (MSC) are multipotent cells. To explain their plasticity, we postulated that undifferentiated MSC may express proteins from other tissues such as neuronal tissues. MSC are obtained by two different approaches: plastic adhesion or negative depletion (RosetteSep and magnetic beads CD45/glycophorin A). MSC are evaluated through FACS analysis using a panel of antibodies (SH2, SH3, CD14, CD33, CD34, CD45, etc.). To confirm the multipotentiality in vitro, we have differentiated MSC into adipocytes, chondrocytes, osteocytes, and neuronal/glial cells using specific induction media. We have evaluated neuronal and glial proteins (Nestin, Tuj-I, betaIII Tubulin, tyrosine hydroxylase [TH], MAP-2, and GFAP) by using flow cytometry, Western blots, and RT-PCR. We found that MSC constituently express native immature neuronal proteins such as Nestin and Tuj-1. After only five passages, MSC can already express more mature neuronal or glial proteins, such as TH, MAP-2, and GFAP, without any specific induction. We noticed an increase in the expression of more mature neuronal/glial proteins (TH, MAP-2, and GFAP) after exposure to neural induction medium, thus confirming the differentiation of MSC into neurons and astrocytes. The constitutive expression of Nestin or Tuj-1 by MSC suggests that these cells are "multidifferentiated" cells and thus can retain the ability for neuronal differentiation, enhancing their potentiality to be employed in the treatment of neurological diseases.     

Modulation of Ca2+-currents by sequential and simultaneous activation of adenosine A1 and A2A receptors in striatal projection neurons

D₁- and D₂-types of dopamine receptors are located separately in direct and indirect pathway striatal projection neurons (dSPNs and iSPNs). In comparison, adenosine A₁-type receptors are located in both neuron classes, and adenosine A_2A-type receptors show a preferential expression in iSPNs. Due to their importance for neuronal excitability, Ca²⁺-currents have been used as final effectors to see the function of signaling cascades associated with different G protein-coupled receptors. For example, among many other actions, D₁-type receptors increase, while D₂-type receptors decrease neuronal excitability by either enhancing or reducing, respectively, Ca_V1 Ca²⁺-currents. These actions occur separately in dSPNs and iSPNs. In the case of purinergic signaling, the actions of A₁- and A_2A-receptors have not been compared observing their actions on Ca²⁺-channels of SPNs as final effectors. Our hypotheses are that modulation of Ca²⁺-currents by A₁-receptors occurs in both dSPNs and iSPNs. In contrast, iSPNs would exhibit modulation by both A₁- and A_2A-receptors. We demonstrate that A₁-type receptors reduced Ca²⁺-currents in all SPNs tested. However, A_2A-type receptors enhanced Ca²⁺-currents only in half tested neurons. Intriguingly, to observe the actions of A_2A-type receptors, occupation of A₁-type receptors had to occur first. However, A₁-receptors decreased Ca_V2 Ca²⁺-currents, while A_2A-type receptors enhanced current through Ca_V1 channels. Because these channels have opposing actions on cell discharge, these differences explain in part why iSPNs may be more excitable than dSPNs. It is demonstrated that intrinsic voltage-gated currents expressed in SPNs are effectors of purinergic signaling that therefore play a role in excitability.     

Epigenetic Regulation of Axonal Growth of Drosophila Pacemaker Cells by Histone Acetyltransferase Tip60 Controls Sleep

Tip60 is a histone acetyltransferase (HAT) enzyme that epigenetically regulates genes enriched for neuronal functions through interaction with the amyloid precursor protein (APP) intracellular domain. However, whether Tip60-mediated epigenetic dysregulation affects specific neuronal processes in vivo and contributes to neurodegeneration remains unclear. Here, we show that Tip60 HAT activity mediates axonal growth of the Drosophila pacemaker cells, termed “small ventrolateral neurons” (sLNvs), and their production of the neuropeptide pigment-dispersing factor (PDF) that functions to stabilize Drosophila sleep–wake cycles. Using genetic approaches, we show that loss of Tip60 HAT activity in the presence of the Alzheimer’s disease-associated APP affects PDF expression and causes retraction of the sLNv synaptic arbor required for presynaptic release of PDF. Functional consequence of these effects is evidenced by disruption of the sleep–wake cycle in these flies. Notably, overexpression of Tip60 in conjunction with APP rescues these sleep–wake disturbances by inducing overelaboration of the sLNv synaptic terminals and increasing PDF levels, supporting a neuroprotective role for dTip60 in sLNv growth and function under APP-induced neurodegenerative conditions. Our findings reveal a novel mechanism for Tip60 mediated sleep–wake regulation via control of axonal growth and PDF levels within the sLNv-encompassing neural network and provide insight into epigenetic-based regulation of sleep disturbances observed in neurodegenerative diseases like Alzheimer’s disease.     

Retinopetal neuronal system in the brain of an air-breathing teleost fish,Channa punctata

Summary Retinopetal neurons were visualised in the telencephalon and diencephalon of an air-breathing teleost fish, Channa punctata, following administration of cobaltous lysine to the optic nerve. The labelled perikarya (n=45–50) were always located on the side contralateral to the optic nerve that had received the neuronal tracer. The rostral-most back-filled cell bodies were located in the nucleus olfactoretinalis at the junction between the olfactory bulb and the telencephalon. In the area ventralis telencephali, two groups of telencephaloretinopetal neurons were identified near the ventral margin of the telencephalon. The rostral hypothalamus exhibited retrogradely labelled cells in three discrete areas of the lateral preoptic area, which was bordered medially by the nucleus praeopticus periventricularis and nucleus praeopticus, and laterally by the lateral forebrain bundle. In addition to a dorsal and a ventral group, a third population of neurons was located ventral to the lateral forebrain bundle adjacent to the optic tract. The dorsal group of neurons exhibited extensive collaterals; a few extended laterally towards the lateral forebrain bundle, whereas others ran into the dorsocentral area of the area dorsalis telencephali. A few processes extended via the anterior commissure into the telencephalon ipsilateral to the optic nerve that had been exposed to cobaltous lysine. However, the ventral cell group did not possess collaterals. In the diencephalon, retinopetal cells were visualised in the nucleus opticus dorsolateralis located in the pretectal area; these were the largest retinopetal perikarya of the brain. The caudal-most nucleus that possessed labelled somata was the retinothalamic nucleus; it contained the largest number of retinopetal cells. The limited number of widely distributed neurons in the forebrain, some with extensive collaterals, might participate in functional integration of different brain areas involved in feeding, which in this species is influenced largely by taste, not solely by vision.     

Medial septum glutamatergic neurons control wakefulness through a septo-hypothalamic circuit

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