几种神经内分泌因子对鲤促性腺激素释放激素（GnRH）释放的调节作 …

用离体静态培育系统进行的初步研究表明,在幼鲤,多巴胺（ＤＡ）显著刺激下丘脑片段和脑垂体碎片释放ＧｎＲＨ,并且是剂量依存的;促甲状腺素释放激素（ＴＲＨ）和γ－氨基酸丁酸（ＧＡＢＡ）对ＧｎＲＨ的释放没有影响。在成鲤,ＤＡ抑制下丘脑片希和脑垂体碎片释放ＧｎＲＨ,而ＴＲＨ和ＧＡＢＡ刺激ＧｎＲＨ的释放;ＤＡ对ＧＡＢＡ刺激的ＧｎＲＨ释放也具有抑制作用;ＴＲＨ和ＧＡＢＡ的协同作用对下丘脑和脑垂体ＧｎＲＨ释放活动     

虎纹蛙促性腺激素释放激素分泌调节的离体研究

利用离体静态孵育系统和放射免疫测定法,研究了性成熟的虎纹蛙雌蛙离体的视前－下丘脑－正中隆起（P－H－ME）片段促性腺激素释放激素（GnRH)的分泌调节。结果表明：γ－氨基丁酸（GABA）对成熟前期蛙离体P－H－ME片段的哺乳类GnRH（mGnRH)的释放有显著的刺激作用;随着GABA作用浓度的增加,刺激作用逐渐增强。100μmol/L的多巴胺（DA）及1μmol/L和10μmol/L的雌二醇(E2）则显著抑制鸡ⅡGnRH(cGnRH-Ⅱ)的释放。10μmol/L和100μmol/L的睾酮（T）以及10μmol/L的E2显著刺激冬眠期蛙P－H－ME片段mGnRH的释放。这些结果表明,GABA,DA及E2和T对虎蚊蛙GnRH的释放有直接的调节作用。     

促性腺激素释放激素及多巴胺对斜带石斑鱼生长激素分泌及其mRNA表达的调控

研究斜带石斑鱼生长激素分泌及其mRNA表达的调控规律对于性别分化的控制、临床药物的选择,以及石斑鱼的增养殖等均具有重要的理论意义和实践意义。本文应用静态孵育系统,采用放射免疫测定法和化学发光液相杂交实验,研究GnRH和DA对斜带石斑鱼GH分泌、GHmRNA合成的调控作用。100nmol／LsGnRH作用斜带石斑鱼脑垂体碎片1也4h,明显促进GH的释放和GHmRNA的合成,并具有时间依存性;10nmol／L～1μmol／LsGnRH作用1h能明显促进斜带石斑鱼脑垂体释放GH,促进GHmRNA的合成,表现出明显的剂量效应。100nmol／L、1μmol／LmGnRH作用1h以一定的剂量依存方式促进GH的释放、促进GHmRNA的合成,但mGnRH的效应比相应剂量的sGnRH的作用弱。APO为DA受体的非选择性激动剂,不同剂量APO对斜带石斑鱼脑垂体碎片的作用结果显示,10nmol／L-1μmol／L APO以剂量依存方式促进斜带石斑鱼脑垂体碎片释放GH、促进GHmRNA的合成：1μmol／LAPO作用12h以上明显促进GH的释放和GHmRNA的合成,并随时间的延长而增加。与sGnRH对斜带石斑鱼GH释放、GHmRNA合成的作用相比,APO的作用较弱。本文研究结果证实GnRH和DA能促进斜带石斑鱼脑垂体GH释放和GHmRNA合成。     

睾酮对日本鳗鲡离体下丘脑-脑垂体复合物GtH合成与分泌的影响

用离体孵育的方法研究了睾酮（T）对日本鳗鲡（Anguilla japonica)完整的正丘脑-脑垂体复合物（hypothalamus-pituiary complex,HPC)、分离的下丘脑（hypothalamus,H)加脑垂体（pituitary,P)以及单独的脑垂体（pituitary,P)促性腺激素（GtH)合成与释放的影响,在不加T的孵育液中孵育,HPC组的孵育液及其脑垂体中的GtH含量最高,H P组次之,而P组最低,表明下丘脑通过GnRH直接刺激脑垂体GtH的合成与释放,在加入T的孵育液中孵育,P组的孵育液及脑垂体中的GtH含量显著增加,并且和孵育液中的T呈剂量依存的正反馈作用,当T和H与P一起孵育时,低浓度的T（0.1和1μmol/L)刺激HPC组和H P组的GtH释放,呈现正反馈作用,而高浓度的T（10μmol/L)则抑制HPC组和H P组的GtH释放,表现负反馈作用。这些结果直接证明日本鳗鲡下丘脑对脑垂体GtH分泌的调控以及性类固醇激素（如雄鳗的睾酮）对脑垂体GtH分泌的反馈作用。     

促性腺激素释放激素类似物对长臀wei脑垂体促性腺激素分泌的影响

采用离体灌流孵育技术和促性腺激素的放射免疫测定方法,对长臀wei(Cranoglanis bouderius)脑垂体碎片促性腺激素的分泌进行了研究。结果表明：持续的促性腺激素释放激素类似物(GnRH-A)能显著刺激退化期的长臀wei离体脑垂体碎片促性腺激素(GTH)的分泌,并且长臀wei脑垂体碎片对持续的GnRH-A刺激未表现出脱敏性,该结果与胡子鲇和鲇鱼相似,而与金鱼和鲤科鱼类不同;重复脉冲GnRH-A刺激对长臀wei脑垂体碎片GTH分泌具有促进作用,而且存在剂量依存关系,与鲇鱼和鲤科鱼类相类似。上述结果表明在长臀wei的人工繁殖中可以用持续高浓度GnRH-A刺激对长臀wei进行催熟和催产。     

促性腺激素释放激素类似物对长臀(鱼危)脑垂体促性腺激素分泌的影响

采用离体灌流孵育技术和促性腺激素的放射免疫测定方法,对长臀(鱼危)(Cranoglanis bouderius)脑垂体碎片促性腺激素的分泌进行了研究.结果表明:持续的促性腺激素释放激素类似物(GnRH-A)能显著刺激退化期的长臀(鱼危)离体脑垂体碎片促性腺激素(GTH)的分泌,并且长臀(鱼危)脑垂体碎片对持续的GnRH-A刺激未表现出脱敏性,该结果与胡子鲇和鲇鱼相似,而与金鱼和鲤科鱼类不同;重复脉冲GnRH-A刺激对长臀(鱼危)脑垂体碎片GTH分泌具有促进作用,而且存在剂量依存关系,与鲇鱼和鲤科鱼类相类似.上述结果表明在长臀(鱼危)的人工繁殖中可以用持续高浓度GnRH-A刺激对长臀(鱼危)进行催熟和催产.     

促性腺激素释放激素的结构及其生物学功能

促性腺激素释放激素(GnRH)是下丘脑分泌的十肽激素,是神经、免疫、内分泌三大调节系统互相联系的重要信号分子,对生殖调控具有重要意义.GnRH类似物是近年来应用最广的多肽类激素新药之一.就GnRH及其受体的结构及分布、GnRH在垂体和性腺水平调控生殖的一系列证据、影响GnRH释放的因素等进行了综述,并展望了GnRH研究的发展趋势及应用前景.     

多巴胺能药物对虎纹蛙GnRH和LH分泌活动的影响

利用在体注射实验和放射免疫测定法,研究了多巴胺能药物对性腺处于再发育期虎纹蛙的促性腺激素释放激素（GnRH)及促黄体激素（LH)分泌活动的影响。结果是：多巴胺（DA）及其激素剂阿扑吗啡（APO）可显著降低血浆LH水平;而多巴胺的拮抗剂－地欧酮（DOM）可显著增加垂体LH含量。DA对脑中cGnRH-Ⅱ的合成有抑制作用,而OM对其mGnRH的释放有一定的刺激作用。结果表明：DA可在脑及垂体水平分别抑制虎纹蛙GnRH和LH的释放,DA对LH释放的抑制作用很可能是通过D2受体实现的。     

促性腺激素释放激素类似物对长臀鮠脑垂体促性腺激素分泌的影响

采用离体灌流孵育技术和促性腺激素的放射免疫测定方法,对长臀鮠(Cranoglanis bouderius)脑垂体碎片促性腺激素的分泌进行了研究。结果表明：持续的促性腺激素释放激素类似物(GnRH-A)能显著刺激退化期的长臀鮠离体脑垂体碎片促性腺激素(GTH)的分泌,并且长臀鮠脑垂体碎片对持续的GnRH-A刺激未表现出脱敏性,该结果与胡子鲇和鲇鱼相似,而与金鱼和鲤科鱼类不同;重复脉冲GnRH-A刺激对长臀鮠脑垂体碎片GTH分泌具有促进作用,而且存在剂量依存关系,与鲇鱼和鲤科鱼类相类似。上述结果表明在长臀鮠的人工繁殖中可以用持续高浓度GnRH-A刺激对长臀鮠进行催熟和催产。     

下丘脑外侧区注射TRH对大鼠胃酸分泌的影响

本文采用连续收集胃腔灌流法,观察下丘脑外侧区(LHA)注射促甲状腺激素释放激素(TRH)对大鼠胃酸分泌的影响,并分析TRH在LHA促进胃酸分泌的作用机制。结果表明:(1)LHA注射TRH(1μg)明显地刺激胃酸分泌;(2)预先向LHA注射酚妥拉明(10μg)、美多心安(5μg)及胃泌素抗体1μl(1:640)并不影响TRH的泌酸作用,如预先向LHA注射阿托品(5μg)则可消除TRH的泌酸效应;(3)垂体摘除及肾上腺切除均不影响TRH的泌酸作用;(4)隔下迷走神经切断后,LHA注入TRH的泌酸效应仍然出现,但持续时间显著缩短;腹腔交感神经节摘除后,TRH仍能促进胃酸分泌,但分泌量少而平稳。以上结果提示:LHA是TRH中枢泌酸效应的有关结构之一,其中枢机制是通过胆碱能M受体中介的,腹腔交感神经节和膈下迷走神经是TRH泌酸效应的传出途径。前者引起的泌酸反应出现较早且引起泌酸高峰,但持续时间短;后者则引起低平的持续分泌。     

Effects of GABA(A) receptor modulation on the expression of GnRH gene and GnRH receptor (GnRH-R) gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland of follicular-phase ewes

The effect of prolonged, intermittent infusion of GABA(A) receptor agonist (muscimol) or GABA(A) receptor antagonist (bicuculline) into the third cerebral ventricle on the expression of GnRH gene and GnRH-R gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland was examined in follicular-phase ewes by real-time PCR. The activation or inhibition of GABA(A) receptors in the hypothalamus decreased or increased the expression of GnRH and GnRH-R genes and LH secretion, respectively. The present results indicate that the GABAergic system in the hypothalamus of follicular-phase ewes may suppress, via hypothalamic GABA(A) receptors, the expression of GnRH and GnRH-R genes in this structure. The decrease or increase of GnRH-R mRNA in the anterior pituitary gland and LH secretion in the muscimol- or bicuculline-treated ewes, respectively, is probably a consequence of parallel changes in the release of GnRH from the hypothalamus activating GnRH-R gene expression. It is suggested that GABA acting through the GABA(A) receptor mechanism on the expression of GnRH gene and GnRH-R gene in the hypothalamus may be involved in two processes: the biosynthesis of GnRH and the release of this neurohormone in the hypothalamus.     

长臀（鱼危）脑垂体和血清中促性腺激素的生殖周期变化

鲇形目鱼类在世界养殖鱼类中占有重要的位置.     

Estradiol-17beta triggers luteinizing hormone release in the protandrous black porgy (Acanthopagrus schlegeli Bleeker) through multiple interactions with gonadotropin-releasing hormone control.

We investigated the mechanism of estradiol-17beta (E2) action on stimulation of LH (=gonadotropin II) release in the black porgy fish (Acanthopagrus schlegeli Bleeker) using an in vivo approach and primary cultures of dispersed pituitary cells in vitro. In vivo, E2 but not androgens (testosterone [T] and 11-ketotestosterone [11-KT]) significantly stimulated plasma LH in a dose-dependent manner. Estradiol-17beta also increased brain content of seabream GnRH. GnRH antagonist prevented E2 stimulation of LH release in vivo, indicating that the effect of E2 on LH was mediated by GnRH. In vitro, sex steroids (E2, T, 11-KT) alone had no effect on basal LH release in the cultured pituitary cells, but GnRH significantly stimulated LH release. Estradiol-17beta potentiated GnRH stimulation of LH release, an effect that was inhibited by GnRH antagonist, and 11-KT, but not T, also potentiated GnRH stimulation of LH release. The potentiating effect of 11-KT on GnRH-induced LH release in vitro was stronger than that of E2. These data suggest that E2 triggers LH release in vivo by acting both on GnRH production at the hypothalamus and on GnRH action at the pituitary. In contrast, 11-KT may only stimulate GnRH action at the pituitary. The E2) induction of LH release, through multiple interactions with GnRH control, supports a possible central role of E2in the sex change observed in the protandrous black porgy.     

The involvement of GABA(A) receptors in the control of GnRH and beta-endorphin release, and catecholaminergic activity in the ventromedial-infundibular region of hypothalamus in anestrous ewes.

To examine the role of the GABA(A) receptor mediating systems in the control of gonadotropin-releasing hormone (GnRH) release from the ventromedial-infundibular region (VEN/IN) of anestrous ewes, the extracellular concentrations of GnRH, beta-endorphin, noradrenaline (NE), dopamine (DA), 4-hydroxy-3-methoxy-phenylglycol (MHPG) and 3,4-dihydroxy-phenylacetic acid (DOPAC) were quantified during local stimulation or blockade of GABA(A) receptors with muscimol or bicuculline respectively. In most animals stimulation of GABA(A) receptors significantly attenuates GnRH release with concomitant increase of beta-endorphin and DA release, and MHPG and DOPAC levels. Blockade of the GABA(A) receptors generally did not affect GnRH and NE release but inhibited in most animals beta-endorphin release and decreased dopaminergic activity. These results suggest, that GABA may suppress GnRH release directly by GABA(A) receptor mechanism on the axon terminal of GnRH neurons or indirectly by GABA(A) receptor processes activating beta-endorphin-ergic and dopaminergic neurons in the VEN/NI. On the basis of these results in could not be distinguish between these two events. The decrease in extracellular beta-endorphin and dopamine concentration without evident changes in the GnRH level during GABA(A) receptor blockade may suggest that other neuronal systems are involved in this effect.     

The role of GABA(A) receptors in the neural systems of the medial preoptic area in the control of GnRH release in ewes during follicular phase

To examine the role of gamma-aminobutyric acid (GABA)(A) receptor mediating systems in the control of gonadotropin-releasing hormone (GnRH) release from the medial preoptic area (MPOA) of ewes during the follicular phase of the estrous cycle, the extracellular concentrations of GnRH, beta-endorphin, noradrenaline (NE), dopamine (DA), 4-hydroxy-3-methoxy-phenyl-glycol (MHPG) and 3,4-dihydroxy-phenylacetic acid (DOPAC) were quantified during the local infusion of muscimol and bicuculline (agonist and antagonist of GABA(A) receptors, respectively) to this structure. Stimulation of GABA(A) receptors markedly attenuated GnRH release, increased beta-endorphin release and noradrenergic system activity in the MPOA. The decrease of the luteinizing hormone (LH) concentration in blood plasma and LH pulse amplitude suggests that a GABA(A) receptor agonist in the MPOA also suppresses GnRH release from the GnRH axon terminals in the ventromedial hypothalamus/nucleus infundibularis region (VEN/NI). Blockade of GABA(A) receptors had no evident effect on GnRH/LH secretion but decreased beta-endorphin release and increased the extracellular DOPAC concentration. The suppressive influence of muscimol in the MPOA on GnRH release might be considered a net result of its direct inhibitory effect on GnRH release, indirect inhibitory influence on GnRH release through activation of the beta-endorphinergic system, and facilitation of GnRH neurons by increasing noradrenaline release. The results obtained during bicuculline perfusion on these systems' activity are not sufficiently consistent to provide a clear understanding of the lack of changes in the GnRH/LH release under blockade of GABA(A) receptors. We conclude that the MPOA in ewes during the follicular phase is an important regulatory site where stimulation of GABA(A) receptors both decreases GnRH secretion and increases beta-endorphin release.     

Inhibition by L-Prolyl-L-Leucyl-Glycinamide (PLG) of Alpha-melanocyte stimulating hormone release from hypothalamic slices

Release of -MSH from male rat hypothalamic slices was studied using a sensitive bioassay (1–2 pg). Addition of 60 mM KC1 to superfusion medium resulted in a twofold increase in -MSH release compared to spontaneous release. Both spontaneous and potassium- induced release were inhibited in a dose-response manner by the tripeptide Pro-Leu-Gly-NH₂ (PLG, or MIF-1); 0.04 μg to 1 μg PLG inhibited the -MSH release but the lowest dose demonstrated a greater inhibitory effect; high concentrations of PLG, on the other hand, did not modify either spontaneous or potassium-evoked -MSH release from the slices. Contrarily, DA did not modify either spontaneous or potassium- induced -MSH release at any of the doses tested. These findings demonstrate that the inhibitory behavior of PLG and DA in the central nervous system (CNS) differs from their behavior towards -MSH release in the pituitary. This suggests differences in the regulation of -MSH release from the pituitary and the CNS.     

The role of amino acid neurotransmitters in the regulation of pituitary gonadotropin release in fish.

Both glutamate and gamma-aminobutyric acid (GABA) are involved in pituitary hormone release in fish. Glutamate serves 2 purposes, both as a neurotransmitter and as a precursor for GABA synthesis. Glutamate can be catabolized to GABA by the actions of 2 distinct but related enzymes, glutamate decarboxylase 65 (GAD65) and GAD67. They derive from 2 different genes that likely arose from an early gene duplication prior to the emergence of teleosts more than 400 million years ago. There is good evidence for the involvement of GABA in luteinizing hormone (LH) release in fish. The mechanism of GABA action to stimulate LH release appears to be a combination of effects on GnRH release, potentiation of gonadotropin hormone-releasing hormone (GnRH) action, and in some cases directly at the LH cell. These actions appear to be dependent on such factors as sex or sex steroid levels, and there may also be species differences. Nevertheless, the stimulatory effects of GABA on LH are present in at least 4 fish species. In contrast, convincing data for the inhibitory effects of GABA on LH release have only been observed in 1 fish species. The sites and mechanisms of action of amino acid neurotransmitters on LH release have yet to be fully characterized. Both 130N-methyl-D-aspartic acid (NMDA) and S-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) type glutamate receptors are likely to have important roles. We suggest that it is a receptor similar to the GABA(A) type which mediates the effects of GABA on LH release in fish, at least partially acting on the GnRH neuron, but likely directly acting at the gonadotroph as well. GABA may also be involved in regulating the release of other pituitary hormones in fish, namely follicle stimulating hormone (FSH = GTH-I), prolactin, and growth hormone. Based on the findings described in this review, a working model for the involvement of glutamate and GABA in the regulation of LH release in teleost fish is proposed.     

Nociceptin stimulates thyrotropin secretion in rats

Effects of nociceptin on thyrotropin (TSH) and thyrotropin-releasing hormone (TRH) secretion in rats were studied. Nociceptin (150 microgram/kg) was injected intravenously and rats were serially decapitated after the injection. The effects of nociceptin on TRH release from the hypothalamus and TSH release from the anterior pituitary in vitro were also investigated. TRH and thyroid hormones were measured by individual radioimmunoassays. TSH was determined by enzyme immunoassay. TRH contents in the hypothalamus decreased significantly after nociceptin injection, whereas plasma TRH concentrations showed no changes. Plasma TSH concentrations increased significantly in a dose-related manner. The TRH release from the hypothalamus was enhanced significantly in a dose-related manner with the addition of nociceptin. The TSH release from the anterior pituitary in vitro was not affected by the addition of nociceptin. The plasma thyroxine and 3,3',5-triiodothyronine levels did not change significantly after nociceptin administration. The inactivation of TRH by plasma or hypothalamus in vitro after nociceptin injection did not differ from that of controls. The findings suggest that nociceptin acts on the hypothalamus to stimulate TRH and TSH secretion.