家蚕色氨酸羟化酶(TRH)基因的克隆及表达特性分析（英文）

5-羟色胺(5-hydroxytryptamine, 5-HT)是生物界广泛分布的信号分子,涉及动物的重要行为。5-HT是色氨酸羟化酶(Tryptophan hydroxylase, TRH)将L-色氨酸羟化为5-羟-L-色氨酸,5-羟-L-色氨酸随即被多巴脱羧酶(Aromatic L-amino acid decarboxylase, DDC)脱羧而成。TRH作为5-HT合成的限速酶,在无脊椎动物神经调控中具有重要地位。鳞翅目昆虫中TRH的功能研究并不多。在家蚕中克隆了家蚕TRH (Bombyx mori TRH, BmTRH)的cDNA序列1667bp,其中包含1632bp的开放读码框(Openreadingframe,ORF)。人类TPH或者果蝇TRH(Drosophila TRH, DmTRH)与BmTRH有高度相似性,尤其BmTRH和DmTRH之间大多数氨基酸保守说明它们在系统发育上的密切关系并可能有相似功能。基因表达分析显示BmTRH主要表达于头部和中枢神经组织,免疫组织化学和Western blotting结果显示BmTRH只存在于神经组织中,即BmTRH可能仅参与家蚕的神经活动。此外,家蚕DDC(B.moridecarboxylase,BmDDC)和蛋白具有TRH活性的苯丙氨酸羟化酶基因(Phenylalanine hydroxylase, BmPAH)也在中枢神经系统中有表达,暗示家蚕神经系统5-HT的合成与果蝇中不同,可能有两种不同的调控机制。     

五羟色胺和多巴胺与攻击行为的关联研究进展

五羟色胺（5-HT）和多巴胺（DA）是影响攻击行为的重要神经递质。参与这两种神经递质合成和分解、运输及信号转导等过程的物质均可能影响攻击行为,如影响5-HT作用的色氨酸、色氨酸羟化酶、单胺氧化酶、5-羟吲哚乙酸及5-HT转运体和5-HT受体;影响DA作用的多巴胺β羟化酶和儿茶酚胺邻位甲基转移酶以及DA转运体。未来攻击行为研究,应考虑色氨酸自身代谢、受体亚型及其他单胺类和儿茶酚胺类神经递质的影响。将肠道微生物纳入攻击行为研究也是未来研究的新方向。     

针刺对血和脑色氨酸浓度的影响

已知色氨酸是脑内5-羟色胺(5-HT)生物合成的前体,由血液转运入脑,但它在脑内的浓度低于色氨酸羟化酶(Tryptophan Hydroxylase)亲和力所需要的浓度。本文作者已证实,5-HT 能系统的正常功能是实现针刺镇痛的必需条件,针刺过程能激发脑内5-HT 能神经元的活动,使5-HT 生物合成增加,它的代谢产物5-羟吲(?)醋酸(5-HIAA)明显升高。那么,针刺镇痛过程是否也激发血脑色氨酸的转运功能,以保持脑内5-HT 能神经元正常活动的需要。本文针对这问题,在针刺镇痛后,分别测定血和脑色     

家蚕非编码RNA在神经系统中的表达分析

【目的】非编码RNA(non-coding RNA,ncRNA)在家蚕Bombyx mori发育过程中具有重要调控作用。本研究旨在探索ncRNA参与家蚕神经系统发育的分子机理。【方法】采用实时荧光定量PCR技术对22个中等长度的ncRNA及3个ncRNA的邻近编码基因在家蚕幼虫神经系统中的表达水平进行检测。【结果】8个ncRNA(包括1个C/D box snoRNA,4个H/ACA box snoRNA和3个不能归类的ncRNA)在家蚕5龄幼虫神经组织和非神经组织中均有表达,且在胸腹神经中的表达量明显高于头部神经中的表达量。其中,snoRNA Bm-51,Bm-18和Bm-86在胸腹神经中的表达量分别是头部神经中的23,5和4.7倍。进一步研究发现,这3个内含子起源的ncRNA与其宿主基因在家蚕神经系统中的表达趋势一致,宿主基因在胸腹神经中的表达量也明显高于头部神经中的表达量。【结论】本研究筛选到的在家蚕不同神经部位存在差异表达的ncRNA,特别是在胸腹神经中高表达的ncRNA可能协同其邻近编码基因,参与家蚕神经发育或神经活动过程。该结果为研究ncRNA参与家蚕神经系统发育提供了分子依据,为从非编码RNA角度探索鳞翅目害虫防治提供了新的思路。     

家蚕3-羟酰辅酶A脱氢酶基因全长cDNA克隆及其在质型多角体病毒感染家蚕的差异表达

家蚕质型多角体病毒(Bombyx mori cytoplasmic polyhedrosis virus,BmCPV)是家蚕的重要病毒病原之一,往往给养蚕业生产造成极大危害。我们以前的研究运用基因芯片技术在感染质型多角体病毒的家蚕中肠中鉴定出一个差异表达的3-羟酰辅酶A脱氢酶蛋白基因(Bombyx mori3-hydroxyacyl-CoA dehyrogenase protein gene-Bm3HAD)。本研究利用cDNA末端快速扩增技术(RACE)克隆了该基因,其全长cDNA序列为1168bp,包含一个83bp5’端非翻译区序列(5’-UTR)、一个930bp的开放阅读框(ORF)和一个155bp的3’端非翻译区序列(3’-UTR);基因结构分析发现该基因由5个外显子和4个内含子组成。RT-PCR结果显示该基因在家蚕中肠、脂肪体、血液、丝腺及生殖体中均有表达。荧光定量PCR结果表明该基因在BmCPV感染初期为上调表达,随着病毒感染的进展,该基因的表达水平逐渐降低,并转变为下调表达。研究结果为进一步研究BmCPV对家蚕致病的分子机制提供了有益的信息。     

多巴脱羧酶及其与神经类疾病的关联性研究进展

多巴脱羧酶(dopa decarboxylase,DDC)又称作芳香族L-氨基酸脱羧酶,是儿茶酚胺生物合成途径中重要的酶之一,具有多种生物学功能。多巴脱羧酶可分别催化L-3,4-二羟基苯丙氨酸(L-多巴)和L-5-羟色氨酸合成两种神经递质多巴胺和五羟色胺。多巴胺和五羟色胺在脊椎动物和无脊椎动物的生殖、发育、行为和免疫应答过程中均具有重要作用。此外,它还与多种神经类疾病和社会行为有关。多巴脱羧酶一般以二聚体的形式存在于哺乳类和昆虫的多种神经和非神经组织中。本文从多巴脱羧酶的结构、催化机制、与神经类疾病及其攻击性社会行为的关联性研究进展等方面进行了综述。     

模拟微重力效应对果蝇运动及睡眠的影响

本研究旨在探讨利用模拟微重力效应研究微重力对果蝇运动及睡眠影响的可行性.通过研制能够在模拟微重力环境下实时监测果蝇行为的随机定位仪,监测短时间(3 d)模拟微重力处理过程中,及长时间(10 d、20 d、30 d)处理后雄蝇运动和睡眠的变化;选取受影响较显著的短时间处理组,研究模拟微重力效应对生物钟核心基因(period (per)、timeless(tim)、clock (clk)、cycle (cyc)、cryptochrome (cry))、神经递质多巴胺(dopamine,DA)和5-羟色胺(5-hydroxytryptamine,5-HT)关键合成酶(多巴脱羧酶、酪氨酸羟化酶、色氨酸羟化酶)的编码基因ddc、pale和trh表达水平及DA和5-HT含量的影响.结果显示:短时间暴露下,雄蝇夜晚的运动量增加、单位时间运动次数增加、睡眠时间和次数减少、生物钟基因tim、clk、cyc、cry及神经递质合成相关编码基因ddc、pale和trh的表达水平均显著上升;长时间处理后对雄蝇运动和睡眠的影响较小.本研究认为利用模拟微重力效应研究微重力对果蝇运动及睡眠的影响是可行的,相关研究结果对航天医学研究具有借鉴意义.     

小鼠围生期应用抗生素可致雄性子鼠血清5-羟色胺水平升高及行为和肠道运动功能改变

本研究旨在探讨围生期母鼠使用抗生素对子代小鼠认知行为、肠道动力和外周血5-羟色胺(5-hydroxytryptamine,5-HT)水平的影响。在孕鼠分娩前一周至分娩后一周持续给予头孢克肟或青霉素处理,用三腔社交偏好实验、自我捋毛试验和高架十字迷宫实验检测4～10周龄子鼠行为学改变,检测子鼠的消化道动力,用ELISA检测血清5-HT水平,用RT-qPCR和Western blot检测子鼠结肠上皮组织钾/钠超极化激活环核苷酸门控通道2 (potassium/sodium hyperpolarization-activated cyclic nucleotide-gated channel 2, HCN2)和色氨酸羟化酶1 (tryptophan hydroxylase 1, TPH1)表达水平。结果显示,与对照组相比,头孢克肟组雌性子鼠社交积极性显著提高,雄性子鼠无显著变化;雄性子鼠的结直肠动力和全肠道动力显著降低,盲肠净质量和相对体重占比显著增加,雌性子鼠无显著变化。与对照组相比,头孢克肟组和青霉素组雄性子鼠血清5-HT含量显著升高,雌性子鼠无显著变化。相比对照组,头孢克肟组子鼠结肠上皮HCN2表达水平显著下调,TPH1表达水平无显著变化。以上结果提示,围生期抗生素暴露可能影响子代神经发育和肠道功能,而且这种影响可能与外周血5-HT的变化相关且具有性别差异性。     

昆虫5-羟色胺及其受体的研究进展

5-羟色胺（5-hydroxytryptamine, 5-HT）是昆虫体内一种重要的生物胺。5-HT在昆虫神经组织和非神经组织中均可合成,它可被5-HT转运体重吸收进入突触前结构中。5-HT通过结合特异性的G蛋白偶联受体在昆虫体内发挥不同的神经调控作用,调节昆虫主要的行为活动,比如取食、生物钟、聚集、学习和记忆等。昆虫体内5-HT受体有5种,分别为5-HT1A,5-HT1B, 5-HT2A,5-HT2B 和5-HT7。其中5-HT1A和5-HT1B偶联胞内cAMP的降低, 5-HT2A和5-HT2B偶联胞内Ca²⁺的释放, 5 HT7偶联胞内cAMP的升高。近年来,昆虫体内5-HT及其受体的研究有了很大的进展,昆虫体内越来越多的5-HT受体被克隆,并进行了功能和药理学性质分析。不同昆虫5 HT受体药理学性质存在差异,将为以5-HT受体为靶标,设计新型特异性杀虫剂提供理论基础。     

家蚕hsp70启动子的克隆及功能研究

该研究通过PCR的方法克隆得到家蚕热激蛋白70基因(Bombyx mori hsp70)的5'侧翼的两个长度分别为538 bp和305 bp的序列hsp70-538和hsp70-305。生物信息分析结果表明这两段序列在TATA序列的上游存在保守的热激元件HSE(heat shock element)CTnGAAnnTTCnAG。采用双荧光报告基因技术研究表明这两段序列在BmN细胞中都表现出热激活性,转基因家蚕实验证明hsp70-305在家蚕个体中也具有热激活性,可以认为这两个片段具有hsp70热激启动子特性。     

Maternal and zygotic control of serotonin biosynthesis are both necessary for Drosophila germband extension.

In the accompanying paper, we report that Drosophila gastrulae genetically depleted for the 5-HT(2Dro) serotonin receptor or for serotonin show abnormal germband extension. In wild-type gastrulae, peaks of both the 5-HT(2Dro) receptor and serotonin coincide precisely with the onset of germband extension. Here, we assessed the genetic requirement for this peak of serotonin. We report the characterisation of the serotonin content of individual Drosophila embryos, progeny from flies heterozygous for mutations in genes that are involved in the serotonin synthesis pathway and include the GTP-cyclohydrolase, tryptophan hydroxylase and DOPA decarboxylase loci. The peak of serotonin synthesis at the beginning of germband extension appears strictly dependent upon the maternal deposition of biopterins, products of GTP-cyclohydrolase and cofactors of tryptophan hydroxylase and upon the zygotic synthesis of both tryptophan hydroxylase and DOPA decarboxylase enzymes. Mutant embryos with an impairment in this peak of serotonin synthesis die with a cuticular organisation which is also observed in embryos deficient for the 5-HT(2Dro) receptor. This characteristic cuticular phenotype is thus the hallmark of desynchronisation of the morphogenetic movements during gastrulation. Together, these findings provide additional support for the notion that serotonin, acting through the 5-HT(2Dro) receptor, is necessary for proper gastrulation.     

Role of the 5-HT7 Receptor in the Central Nervous System: from Current Status to Future Perspectives

Pharmacological and genetic tools targeting the 5-hydroxytryptamine (5-HT)7 receptor in preclinical animal models have implicated this receptor in diverse (patho)physiological processes of the central nervous system (CNS). Some data obtained with 5-HT7 receptor knockout mice, selective antagonists, and, to a lesser extent, agonists, however, are quite contradictory. In this review, we not only discuss in detail the role of the 5-HT7 receptor in the CNS but also propose some hypothetical models, which could explain the observed inconsistencies. These models are based on two novel concepts within the field of G protein-coupled receptors (GPCR), namely biphasic signaling and G protein-independent signaling, which both have been shown to be mediated by GPCR dimerization. This led us to suggest that the 5-HT7 receptor could reside in different dimeric contexts and initiate different signaling pathways, depending on the neuronal circuitry and/or brain region. In conclusion, we highlight GPCR dimerization and G protein-independent signaling as two promising future directions in 5-HT7 receptor research, which ultimately might lead to the development of more efficient dimer- and/or pathway-specific therapeutics.     

Neuron-specific modulation by serotonin of regenerative outgrowth and intracellular calcium within the CNS of Helisoma trivolvis

We have investigated the cell-specific effect of serotonin (5-HT) on regenerating neurons within the adult central nervous system of the pond snail, Helisoma trivolvis. In culture, 5-HT arrests outgrowth of buccal neurons B19 but not neurons B5 (Haydon, McCobb, and Kater, 1984). After axotomy, neurons within the Helisoma nervous system typically exhibit profuse regenerative outgrowth. This study, on neurons within the CNS, shows that 5-HT selectively inhibits the outgrowth of specific identified neurons, and also causes significant elevations in intracellular calcium concentrations as measured by the calcium indicator dye, Fura-2. The outgrowth of neurons B19 and C1 was selectively inhibited when ganglia were incubated in 5 X 10(-5) M 5-HT. The outgrowth of buccal neurons B5, however, was not affected. Moreover, 5-HT caused significant transient elevations of calcium concentrations in neurons B19 over 30 minutes, but neurons B5 did not show any increases in calcium concentrations with the addition of 5-HT. These results suggest that the effect of 5-HT upon outgrowth of regenerating neurons may be due to an increase in the intracellular calcium concentration.     

Cell-Autonomous Gβ Signaling Defines Neuron-Specific Steady State Serotonin Synthesis in Caenorhabditis elegans

Heterotrimeric G proteins regulate a vast array of cellular functions via specific intracellular effectors. Accumulating pharmacological and biochemical studies implicate Gβ subunits as signaling molecules interacting directly with a wide range of effectors to modulate downstream cellular responses, in addition to their role in regulating Gα subunit activities. However, the native biological roles of Gβ-mediated signaling pathways in vivo have been characterized only in a few cases. Here, we identified a Gβ GPB-1 signaling pathway operating in specific serotonergic neurons to the define steady state serotonin (5-HT) synthesis, through a genetic screen for 5-HT synthesis mutants in Caenorhabditis elegans. We found that signaling through cell autonomous GPB-1 to the OCR-2 TRPV channel defines the baseline expression of 5-HT synthesis enzyme tryptophan hydroxylase tph-1 in ADF chemosensory neurons. This Gβ signaling pathway is not essential for establishing the serotonergic cell fates and is mechanistically separated from stress-induced tph-1 upregulation. We identified that ADF-produced 5-HT controls specific innate rhythmic behaviors. These results revealed a Gβ-mediated signaling operating in differentiated cells to specify intrinsic functional properties, and indicate that baseline TPH expression is not a default generic serotonergic fate, but is programmed in a cell-specific manner in the mature nervous system. Cell-specific regulation of TPH expression could be a general principle for tailored steady state 5-HT synthesis in functionally distinct neurons and their regulation of innate behavior.     

Substrate regulation of serotonin and dopamine synthesis in <Emphasis Type="Italic">Drosophila</Emphasis>

In Drosophila melanogaster, serotonin (5-hydroxytryptamine, 5-HT) is required for both very early non-neuronal developmental events, and in the CNS as a neurotransmitter to modulate behavior. 5-HT is synthesized, at least in part, by the actions of Drosophila tryptophan-phenylalanine hydroxylase (DTPH), a dual function enzyme that hydroxylates both phenylalanine and tryptophan. DTPH is expressed in numerous tissues as well as dopaminergic and serotonergic neurons, but it does not necessarily function as both enzymes in these tissues. Deficiencies in DTPH could affect the production of dopamine and serotonin, and thus dopaminergic and serotonergic signaling pathways. In this paper, we show that DTPH exhibits differential hydroxylase activity based solely on substrate. When DTPH uses phenylalanine as a substrate, regulatory control (end product inhibition, decreased PAH activity following phosphorylation, catecholamine inhibition) is observed that is not seen when the enzyme uses tryptophan as a substrate. These studies suggest that regulation of DTPH enzymatic activity occurs, at least in part, through the actions of its substrate.     

Role of tyrosine, DOPA and decarboxylase enzymes in the synthesis of monoamines in the brain of the locust

The metabolic transformation of tyrosine (TYR) by the decarboxylase and hydroxylase enzymes was investigated in the central nervous system of the locust, Locusta migratoria. It has been demonstrated that the key amino acids, 3,4-dihydroxyphenylalanine (DOPA), 5-hydroxytryptophan (5HTP) and tyrosine are decarboxylated in all part of central nervous system. DOPA and 5HTP decarboxylase activities show parallel changes in the different ganglia, but the rank order of the activity of TYR decarboxylase is different. Enzyme purification has revealed that the molecular weights of TYR decarboxylase and DOPA/5HTP decarboxylase are 370,000 and 112,000, respectively. The decarboxylation of DOPA by DOPA/5HTP decarboxylase is stimulated, whereas the decarboxylation of DOPA by TYR decarboxylase is inhibited in the presence of the cofactor pyridoxal-5'-phosphate. TYR hydroxylase could not be detected and 3H-TYR is found to be metabolised to tyramine (TA), but not to DOPA. The haemolymph contains a significant concentration of DOPA (120 pmol/100 microl haemolymph), and the ganglia incorporates DOPA from the haemolymph by a high affinity uptake process (K(M)=12 microM and V(max)=24 pmol per ganglion/10 min). Our results suggest that no tyrosine hydroxylase is present in the locust CNS and the DOPA uptake into the ganglia by a high affinity uptake process as well as the DOPA decarboxylase enzyme may be responsible for the regulation of the ganglionic dopamine (DA) level. Two types of decarboxylases exist, one of them decarboxylating DOPA and 5HTP (DOPA/5HTP decarboxylase), other decarboxylating TYR (TYR decarboxylase). The DOPA/5HTP decarboxylase enzyme present in the insect brain may correspond to the 5HTP/DOPA decarboxylase in vertebrate brain, whereas TYR decarboxylase is characteristic only for the insect brain.     

A sleep-promoting role for the Drosophila serotonin receptor 1A

BACKGROUND: Although sleep is an important process essential for life, its regulation is poorly understood. The recently developed Drosophila model for sleep provides a powerful system to genetically and pharmacologically identify molecules that regulate sleep. Serotonin is an important neurotransmitter known to affect many behaviors, but its role in sleep remains controversial. RESULTS: We generated or obtained flies with genetically altered expression of each of three Drosophila serotonin receptor subtypes (d5-HT1A, d5-HT1B, and d5-HT2) and assayed them for baseline sleep phenotypes. The data indicated a sleep-regulating role for the d5-HT1A receptor. d5-HT1A mutant flies had short and fragmented sleep, which was rescued by expressing the receptor in adult mushroom bodies, a structure associated with learning and memory in Drosophila. Neither the d5-HT2 receptor nor the d5-HT1B receptor, which was previously implicated in circadian regulation, had any effect on baseline sleep, indicating that serotonin affects sleep and circadian rhythms through distinct receptors. Elevating serotonin levels, either pharmacologically or genetically, enhanced sleep in wild-type flies. In addition, serotonin promoted sleep in some short-sleep mutants, suggesting that it can compensate for some sleep deficits. CONCLUSIONS: These data show that serotonin promotes baseline sleep in Drosophila. They also link the regulation of sleep behavior by serotonin to a specific receptor in a distinct region of the fly brain.