注射促黄体素释放激素类似物和地欧酮诱导大鳍■和长吻■排卵的研究

对于性成熟的大鳍Ｍｙｓｔｕｓｍａｃｒｏｐｔｅｒｕｓ（Ｂｌｅｅｋｅｒ）野生鱼,单独注射多巴胺的抑制剂地欧酮（ＤＯＭ）不能影响血清促性腺激素（ＧＴＨ）水平,也不能诱导排卵;单独注射类似物ＬＨＲＨ－Ａ,虽能使血清ＧＴＨ水平显著升高,但仅产生较低的排卵率;而当ＤＯＭ与ＬＨＲＨ－Ａ结合注射却显著增强ＬＨＲＨ－Ａ促进血清ＧＴＨ水平升高的作用,并诱导出较高的排卵率。对性成熟的长吻ＬｅｉｏｃａｓｉｓｌｏｎｇｉｒｏｓｔｒｉｓＧｕｎｔｈｅｒ野生鱼,使用ＬＨＲＨ－Ａ＋ＤＯＭ作２次注射诱导排卵的效果也与注射ＬＨＲＨ－Ａ加脑垂体这一传统诱导排卵方法相似。Ｌｉｎｐｅ方法（ＬＨＲＨ－Ａ＋ＤＯＭ,作１次或２次注射）避免了采集、保存脑垂体不便给生产带来的麻烦,在科鱼类的人工繁殖中,具有较高的推广价值。     

注射促黄体素释放激素类似物和地欧酮诱导大鳍Hu和长吻Wei排卵？…

对于性成熟的大鳍ＨｕＭｙｓｔｕｓ ｍａｃｒｏｐｔｅｒｕｓ 野生鱼,单独注射多巴胺的抑制剂地欧酮不能影响血清促性腺激素水平,也不能诱导排卵;单独注射类似物ＬＨＲＨ－Ａ,虽能使血清ＧＴＨ水平显著升高,但仅产生较低的排卵率;而当ＤＯＭ与ＬＨＲＨ－Ａ结合注射却显著增强ＬＨＲＨ－Ａ促进血清ＧＴＨ水平升高的作用,并诱导出较高的排卵率。     

诱导大鳍Hu和长吻Wei排卵过程中血清GTH水平的变化

繁殖期从嘉陵江收集性成熟的大鳍Hu和长吻Wei野生亲鱼,用Linpe方法（即LHRH－A加多巴胺D2受体拮抗剂地欧酮）或传统的LHRH－A加脑垂体的方法进行催产,定时取血样,用放射免疫方法测定催产过程中血清GTH水平的变化,进一步证实鲇形目鱼类GTH的分泌受到下丘脑分泌的促性腺激素释放激素GnRH和多巴胺的以重调节;排卵和产卵也是以血清TGH的急剧升高为先导的,而最终能否排卵还有赖于血清GTH峰是否超过“排卵阈值”,尽管催产后的大鳍Hu和长吻Wei雄鱼血清GTH水平也有一个高峰出现,但血清GTH水平升高幅度都大大低于雌鱼,这种现象在硬骨鱼类可能具有普遍性。     

促黄体素释放激素类似物和多巴胺对鲤鱼幼鱼和性成熟雌鱼生长激素分泌的作用

以性腺未发育的５～６月龄幼鲤和１龄性成熟雌鲤为材料,研究年龄对促黄体素释放激素类似物和多巴胺能药物刺激的鲤鱼ＧＨ分泌的影响。结果表明：５～６月龄幼鱼血清基础ＧＨ水平明显低于１龄性成熟鱼;５～６月龄幼鱼对ＬＨＲＨＡ、ＤＡ和ＡＰＯ刺激的ＧＨ分泌的反应性也明显低于１龄性成熟鱼;ＤＡ和ＡＰＯ在５～６月龄幼鱼和１龄性成熟鱼都不能增强ＬＨＲＨＡ对ＧＨ分泌的刺激作用;ＤＯＭ不影响５～６月龄幼鱼和１龄性成熟鱼的血清ＧＨ水平。     

注射促黄体素释放激素类似物和地欧酮诱导大鳍Hu和长吻Wei排卵的研究

对于性成熟的大鳍鲭Mystus macropterus(Bleeker)野生鱼,单独注射多巴胺的抑制剂地欧酮(DOM)不能影响血清促性腺激素(GTH)水平,也不能诱导排卵;单独注射类似物LHRH-A,虽能使血清GTH水平显著升高,但仅产生较低的排卵率;而当DOM与LHRH-A结合注射却显著增强LHRH-A促进血清GTH水平升高的作用,并诱导出较高的排卵率。对性成熟的长吻鲈Leiocassis longirostris Gunther野生鱼,使用LHRH-A＋DOM作2次注射诱导排卵的效果也与注射 LHRH-A加脑垂体这一传统诱导排卵方法相似。Linpe方法(LHRH-A＋DOM,作1次或2次注射)避免了采集、保存脑垂体不便给生产带来的麻烦,在鲩科鱼类的人工繁殖中,具有较高的推广价值。     

不同的下丘脑肽和神经递质对鲤鱼促性腺激素和生长激素分泌活动的影响

以１龄性腺发育中期鲤鱼为材料,采用腹腔（ｉ．ｐ）注射的方法,研究不同的下丘脑肽和神经递质对鲤鱼促性腺激素（ＧｔＨ）和生长激素（ＧＨ）分泌的影响。结果表明：促甲状腺激素释放激素（ＴＲＨ）、Ｌ－多巴（Ｌ－ＤＯＰＡ）、甲基睾酮（ＭＴ）、γ－氨基丁酸（ＧＡＢＡ）、促黄体素释放激素类似物（ＬＨＲＨ－Ａ）和三碘甲状腺原氨酸（Ｔ３）都能显著刺激ＧｔＨ的分泌,但最大效应时间各不相同。ＴＲＨ和ＬＨＲＨ－Ａ能促进ＧＨ的分泌,Ｌ－ＤＯＰＡ、ＭＴ、ＧＡＢＡ对血清ＧＨ水平没有明显影响;Ｔ３则对ＧＨ分泌有一定的抑制作用。这说明鲤鱼ＧｔＨ和ＧＨ的分泌除了受各自的下丘脑释放因子和释放抑制因子的双重神经内分泌调控外,还受多种其它相同和不同调节因子的影响,也反映了鲤鱼ＧｔＨ和ＧＨ分泌的神经内分泌调控的复杂性。     

大鳍促性腺激素分泌调控的研究

用非洲鲶鱼促性腺激素放射免疫测定方法测定了科鱼类样品中的促性腺激素含量。用这种方法和鲤鱼促性腺激素β亚基放射免疫测定法测定大鳍同一批血清样品结果也相当吻合。通过注射促黄体素释放激素类似物和／或多巴胺的Ｄ２受体拮抗剂地欧酮后,定时取样测定血清促性腺激素含量,证明大鳍促性腺激素的释放同时受到下丘脑分泌的促性腺激素释放激素和多巴胺的双重调节。但是,多巴胺只能抑制由促性腺激素释放激素诱导的促性腺激素分泌,而不能直接抑制基础的促性腺激素分泌,这与非洲鲶鱼相似而与金鱼和鲤鱼等鲤科鱼类明显不同。     

大鳍Hu促性腺激素分泌调控的研究

用非洲鲶鱼促性腺激素放射免疫测定方法测定了Ｃｈａｎｇ科鱼类样品中的促性腺激素含量。用这种方法和鲤鱼促性腺激素β－亚基放射免疫测定法测定大鳍Ｈｕ同一批血清样品结果也相当吻合。通过注射促黄体素释放激素类似物和／或多巴胺的Ｄ２受体拮抗剂地欧酮后,定时取样测定血清促性腺激素含量,证明大鳍Ｈｕ促性腺激素的释放同时受到下丘脑分泌的促性腺激素释放激素和多巴胺的双重调节。但是,多巴胺只能抑制由促性腺激素释放激素诱     

LHRH—A2及无机离子促进草鱼脑垂体离体分泌GH的初步研究

用培养瓶（皿）培养法研究ＬＨＲＨ－Ａ２、Ｃａ＾２＋、Ｋ＾＋对草鱼脑垂体器官分泌ＧＨ的影响。结果表明，１ｎｍｏｌ／Ｌ、１０ｎｍｏｌ／Ｌ、１００ｎｍｏｌ／Ｌ和１０００ｎｍｏｌ／Ｌ的ＬＨＲＨ－Ａ２都能显著促进ＧＨ的分泌；随着Ｃａ＾２＋浓度（０．１、１、３ｍｍｏｌ／Ｌ）的增高ＧＨ的分泌增强，在１ｍｏｌ／Ｌ和３ｍｍｏｌ／Ｌ Ｃａ＾２＋条件下的ＧＨ分泌水平显著高于在０．１ｍｍｏｌ／Ｌ Ｃａ＾２＋条件下的ＧＨ分     

利血平和丘脑下部促黄体素释放激素类似物(LHRH-A)对大鳞副泥鳅促性腺激素细胞的分泌活动和排卵的促进作用

利血平能使神经分泌细胞的儿茶酚胺贮存量减少甚至消耗殆尽,导致多巴胺作为GRIF的作用减弱,从而显著增强LHRH-A促进GtH分泌和诱导排卵的效应。对大鳞副泥鳅,利血平和LHRH-A同时注射或者利血平比LHRH-A提前3小时注射,都能激活GtH细胞,显著增强其分泌活动并诱导排卵。利血平的最低有效剂量为1—5微克/克体重。利血平(25微克/克体重) LHRH-A(0.05微克/克体重)的催产效果和多巴胺拮抗物pimozide(1微克/克体重) LHRH-A(0.05微克/克体重)的催产效果一样,排卵率都达到了100％。     

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.     

Neuroendocrine regulation of ovulation in fishes: basic and applied aspects

This review summarizes the major neuroendocrine mechanisms regulating ovulation, thus providing a basis for understanding the various environmental and hormonal techniques for induction of ovulation of cultured teleosts. The secretion of gonadotrophin-ii(GtH-ii) is stimulated by gonadotrophin-releasing hormone (GnRH), and, although some teleosts have three different forms of GnRH regionally distributed in the brain, in most species investigated, only one form is present in the pituitary and apparently involved in GtH-ii secretion. In nearly all species investigated, dopamine (DA) inhibits GtH-ii secretion by direct actions on gonadotrophs, as well as by inhibition of GnRH release. Sex steroids act at both brain and pituitary levels to regulate GtH-ii secretion through a combination of positive and negative feedback actions; one important positive feedback action is that sex steroids enhance the responsiveness of the pituitary to GnRH and an important negative feedback action is to increase DA turnover, thereby increasing the overall DA inhibitory tone on GtH-ii secretion. The preovulatory surge of release of GtH-ii is stimulated by a surge release of GnRH. A decrease in DA turnover also occurs to disinhibit GnRH and GtH-ii release. Environmental factors including photoperiod, temperature and spawning substrate may cue ovulation and spawning. Social and pheromonal interactions play a very important role in synchronizing preovulatory endocrine changes, ovulation and spawning behaviour in many species. A widely used technique for inducing ovulation of cultured fishes is injection of the combination of a GnRH superactive analogue, to stimulate GtH-ii release, and a DA receptor antagonist, to block the inhibitory actions of DA. This is termed the Linpe technique and has proven particularly useful with those species having synchronous or group synchronous follicular development and a large preovulatory surge of GtH-ii. In other groups of teleosts, particularly those species having asynchronous ovarian development and multiple spawnings over an extended period, treatment with a sustained-release preparation of a GnRH superactive analogue to cause a prolonged, somewhat enhanced release of GtH-ii has proven highly successful in inducing multiple ovulations and spawnings. However, the lack of specific radioimmunoassays for GtH-ii in many of these species has hindered progress, as the precise pattern of GtH-ii release necessary for the recruitment of vitellogenic oocytes into final maturation and ovulation in these multiple spawners remains an intriguing neuroendocrine question     

多马胺能药物对鲇鱼促性腺激素（GtH）分泌活动的影响

以珠江流域鲇鱼（silurus asotus)为实验材料,研究了多巴胺（DA）能药物（DA及其D－2型受体拮抗物 ,DOM）对鲇鱼促性腺激素（GtH)释放的影响,结果表明,在性腺发育的各个时期,单独注射DOM（5ug/g)均不能显著提高鲇鱼血液基础GtH水平,当DOM与LHRH－A联合注射时能显著增强LHRH－A刺激GtH释放的作用;DA只能抑制GnRH诱导的GtH释放,对基础GtH释放无抑制作用,这种生殖内分泌调节方式与鲇形目的革胡子鲇（Clarias gariepinus)和大鳍Hu（Mystus macropterus)相似,而与鲤形目的鲁科（Cyrpindiae)鱼类不同。     

Effects of mammalian gonadotropin-releasing hormone analogue, pimozide, and the combination on plasma gonadotropin levels in different seasons and induction of ovulation in female catfish

In the catfish Heteropneustes fossilis , 0.5μg g-¹ B.W. mGnRH-A alone or the low dose of 0.05 μg g^-1 B.W. in combination with pimozide [a dopamine (DA)-receptor antagonist, 5 or l0μg g^-1 B.W.], caused a preovulatory surge in plasma gonadotropin (GTH) and induced a high rate of ovulation. The ovulatory response of the catfish to the low dose of mGnRH-A when given alone was not effective in the early (July) but was effective in the late spawning season (August). Plasma GTH response to these treatments showed seasonal variations. Pimozide administration potentiated the response to mGnRH-A in a season-dependent manner, being effective only in the prespawning and spawning phases. Pimozide treatment alone did not affect plasma GTH. These observations suggest that the release of GTH from the pituitary is subject to seasonal differences in the sensitivity of the GnRH system and the degree of its modulation by dopamine.     

Effects of pulsatile infusion of luteinizing hormone-releasing hormone on luteinizing hormone secretion and ovarian function in hypophysial stalk-transected beef heifers

Hypothalamic regulation of luteinizing hormone (LH) secretion and ovarian function were investigated in beef heifers by infusing LH-releasing hormone (LHRH) in a pulsatile manner (1 microgram/ml; 1 ml during 1 min every h) into the external jugular vein of 10 hypophysial stalk-transected (HST) animals. The heifers were HST approximately 30 mo earlier. All heifers had increased ovarian size during the LHRH infusion. The maximum ovarian size (16 +/- 2.7 cm3) was greater (P less than 0.01) than the initial ovarian size (8 +/- 1.4 cm3). Ovarian follicular growth occurred in 4 of 10 HST heifers in response to pulsatile LHRH infusion. In 2 heifers, an ovarian follicle developed to preovulatory size, but ovulation occurred in only 1 animal after the frequency of LHRH was increased (1 microgram every 20 min during 8 h). In blood samples obtained at 20-min intervals every 5th day, LH concentrations in peripheral serum remained consistently low (0.9 ng/ml) and nonepisodic in the 10 HST heifers during infusion of vehicle on the day before beginning LHRH. In 7 of 10 HST animals, episodic LH secretion occurred in response to pulsatile infusion of LHRH. In 3 of these long-term HST heifers, however, serum LH remained at basal levels and the isolated pituitary seemingly was unresponsive to pulsatile infusion of LHRH as indicated by sequential patterns of gonadotropin secretion obtained at 5-day intervals. These results indicate that pulsatile infusion of LHRH induces LH release in HST beef heifers.     

Aspects of the neuroendocrine control of ovulation and broodiness in the domestic hen

The neuroendocrine control of ovulation and broodiness in the domestic hen involves complex interactions between hypothalamic neuropeptides, neurotransmitters, and ovarian steroids which regulate the secretion of luteinizing hormone (LH) and prolactin. Nuclear progesterone receptor is localized in many neurons throughout the hypothalamus but is absent from LHRH neurons. Hence, the positive feedback action of progesterone on LH release is not mediated by a genomic mechanism within the LHRH neuron. Precursors of 5-hydroxytryptamine (5HT) and dopamine (DA) inhibit the preovulatory release of LH, while the turnover rates of these neurotransmitters in the anterior hypothalamus decrease when preovulatory levels of LH are at their highest. Further, a population of receptors for 5HT which occurs in the anterior hypothalamus in laying birds is absent in nonlaying, incubating hens. Taken together, these observations suggest that the preovulatory surge of LH is mediated by a transitory decrease in the inhibitory action of 5HT and possibly DA, on the secretion of LHRH. Neurons containing 5HT may play a role in the regulation of prolactin release and, more specifically, in the control of broodiness. Drugs which enhance the function of 5HT neurons stimulate prolactin release while increased prolactin secretion in incubating hens is associated with an increase in the turnover of 5HT in the anterior hypothalamus. No receptors for 5HT were demonstrable in the anterior pituitary gland, showing that the prolactin-releasing activity of 5HT must be mediated by a prolactin-releasing factor (PRF). A candidate for a physiological PRF is vasoactive intestinal polypeptide (VIP).(ABSTRACT TRUNCATED AT 250 WORDS)     

Gonadal stage-dependent effects of gonadal steroids on gonadotropin II secretion in the Atlantic croaker (Micropogonias undulatus).

Involvement of gonadal steroids in the control of gonadotropin II (GTH II) (homologous to LH) secretion was investigated in the Atlantic croaker (Micropogonias undulatus) using gonadectomy (Gx) and steroid replacement paradigms. Gonadectomy in males and females during the late gonadal recrudescence phase elicited significant increases in the gonadotropin response to stimulation by an LHRH analog (LHRHa), without altering basal GTH II secretion. Slow-release silicone elastomer implants of testosterone or estradiol significantly inhibited LHRHa-induced GTH II secretion in gonad-intact and Gx males, and in Gx females, whereas 5alpha-dihydrotestosterone, a nonaromatizable androgen, was ineffective. Pretreatment of fish with an aromatase inhibitor, 1,4, 6-androstatrien-3,17-dione, 2 days before the administration of testosterone implants, completely blocked the negative effect of testosterone on LHRHa-induced GTH II secretion in males, but only partially restored it in females. This suggests that the negative feedback of testosterone in males is primarily mediated by its conversion to estradiol at the level of the hypothalamus and/or pituitary gland, while in females the androgen may also exert a direct inhibitory effect on GTH II secretion, probably mediated via an androgen receptor. In addition, estradiol and testosterone exerted positive effects on basal and LHRHa-induced GTH II secretion during the early-recrudescence phase of the gonadal cycle. The steroids switched to a negative effect on LHRHa-induced GTH II secretion once the fish had fully developed gonads, possibly as a mechanism that prevents a precocious surge in GTH II secretion and final gamete maturation until gametogenesis is complete and the environmental conditions are appropriate for spawning.     

Dissociation of copulation from ovulation in pregnant rabbits

Experiments were designed to determine why copulation in the pregnant rabbit does not terminate pregnancy while treatment with ovulatory doses of luteinizing hormone (LH) human chorionic gonadotropin (hCG) or luteinizing hormone-releasing hormone (LHRH) is known to do so. Pregnant rabbits (Day 8) were mated or were injected with hCG (25 IU/doe) or LHRH (1, 10 micrograms/kg). Serial blood samples were collected over the next 72 h and analyzed for content of LH, follicle-stimulating hormone (FSH) and progesterone. At sacrifice, uteri and ovaries from these animals were examined for viability of the embryos and for signs of recent ovulation. Injection of hCG or LHRH into pregnant animals led to ovulation and to patterns of LH, FSH and progesterone secretion like those which precede ovulation in estrous rabbits. However, mating the pregnant does did not lead to ovulation or to any changes in the circulating hormones. To investigate whether the elevated levels of progesterone during pregnancy were responsible for the dissociation of coitus from ovulation, nonpregnant rabbits were injected with progesterone (2 mg/kg) and then mated or injected with hCG or LHRH. In virtually every respect, the numbers of ovulations and the patterns of hormone secretion in the progesterone-treated, nonpregnant rabbits mimicked those observed in the 8-day pregnant animals; injection of hCG or LHRH caused ovulation and hormonal surges while hCG caused ovulation only. Mating did not lead to ovulation or any change in blood levels of LH, FSH or progesterone. Taken together, the results show that the elevated circulating levels of progesterone, characteristic of pregnancy, are probably responsible for the dissociation of copulation from gonadotropin release in pregnant rabbits.     

A possible role for progesterone in the preovulatory gonadotropin surge through modulation of LHRH degrading activity

The preovulatory surge of gonadotropins is triggered by estradiol and enhanced to its full magnitude by progesterone. Progesterone may exert this effect through several mechanisms. One of the mechanisms is through the ability of progesterone to induce an increase in the hypothalamic content and release of LHRH. The purpose of this study was to determine if progesterone might not act through yet another mechanism and facilitate LHRH release of the proestrous gonadotropin surge through modulation of luteinizing hormone releasing hormone (LHRH) degrading activity. Sixty-day-old Sprague-Dawley rats were ovariectomized; 14 days later, the estradiol-progesterone milieu of proestrous was mimicked in these animals through the use of estradiol containing silastic implants and subcutaneous progesterone injections. The LHRH degrading activity of the hypothalamus, pituitary and serum were monitored subsequently at preselected time points. In the hypothalamus, estradiol alone was capable of inducing significant increase in degrading activity; progesterone alone had no effect; however, progesterone subsequent to estradiol priming suppressed the increase induced by estradiol alone. In the pituitary, neither estradiol alone nor progesterone alone nor progesterone subsequent to estradiol priming had any significant effect on degrading activity. In the serum, estradiol induced a rapid and significant increase in activity; progesterone alone suppressed activity; progesterone subsequent to estradiol priming induced a similar but more rapid suppression. Therefore, the overall tendency was for estradiol to stimulate and progesterone to suppress LHRH degrading activity in the tissues studied. The results of this study indicate that progesterone has the capacity to suppress LHRH degrading activity and may be one of the mechanisms capable of increasing the availability of LHRH to the anterior pituitary gland thereby facilitating the preovulatory gonadotropin surges.