野生鲇鱼生长激素分泌的季节变化及其神经内分泌调控

采用离体垂体碎片灌流孵育系统 ,将处于性腺退化期野生鲇鱼垂体切成约 1mm3 的碎片 ,用M 199冲洗之后放入灌流柱的两层Cytodex -Ⅲ微载体之间 (温度为 19± 1℃ )。每 5分钟收集一管灌流液 ,- 2 5℃贮存待测GH。采用鲤鱼GH放射免疫测定方法 (cGHRIA)测定鲇鱼垂体碎片灌流液以及血清和垂体中的GH含量。结果表明 :促黄体素释放激素类似物 [desGly10 (D Ala6)LHRHethylamide ,LHRH A]不能显著刺激离体垂体碎片基础GH分泌 ,注射LHRH A后不能显著提高血清基础GH水平 ;注射DA能显著提高鲇鱼血清基础GH水平 ,APO能以剂量依赖方式显著刺激垂体碎片基础GH分泌。雌、雄鲇鱼血清GH水平在 6月达到峰值 ,垂体GH水平在 3月和 7月份各出现一个峰值 ,各个季节雌鱼垂体和血清GH水平均显著高于雄鱼。鲇鱼血清和垂体GH水平与生殖周期有密切联系。     

GTPγs对柴胡皂甙(I)刺激胰腺腺泡酶分泌的影响

为了解柴胡皂甙(I)[SA(I)]刺激大鼠胰腺腺泡酶分泌的信号传导通路,研究了GTPγs对SA(I)剌激通透腺泡细胞酶分泌的影响.用SLO通透细胞的同时,加入GTPγs在15min期间能诱发酶分泌,10'mol·L-1GTPγs有最大促泌效应.GTPγs浓度依赖性的增强SA(I)促酶分泌作用,l0-7 mol·L-1 GTPγs导致10-5mol·L-1 SA(I)刺激酶分泌量增加到1.6倍.用SLO预通透腺泡10min后,加入GTPγs使SA(I)刺激酶分泌的量-效曲线左移,SA(I)的EC50从2 0×10-5mol·L-1减小到1 0×10-5mol·L-1.以上结果提示,SA(I)活化受体偶联的G蛋白包括在其刺激酶分泌的信号传导通路中.     

大鼠腺垂体细胞单层培养及其分泌功能的研究

本文报道了大鼠腺垂体细胞单层培养的方法,经胰蛋白酶、DNA酶、胰蛋白酶抑制剂以及EDTA和神经氨酸酶先后处理的腺垂体细胞在24孔塑料培养板上生长良好,功能反应灵敏、稳定。LH分泌与细胞密度(0.25—2.0×10~6个/孔)呈高度相关。培养的细胞对GnRH(10~(-10)—10~(-6)mol/L)及下丘脑正中隆起提取物的反应良好,LH分泌量与刺激物浓度高度相关,最低确效刺激量分别为10~(-10)mol/L和0.00625“当量”。本法可作为下丘脑释放激素生理活性的检测系统,并可用于腺垂体机能调节的生理学、病理生理学和药理学研究。     

大鼠GTH细胞内cAMP的改变对LH分泌的影响

将GTH细胞用FSK(cAMP兴奋剂)或SO22,536(cAMP抑制剂兴奋剂)处理后,用GnRH脉冲刺激,再用ELISA法检测其LH分泌量,并与空白对照组比较。结果表明,FSK能显著提高GTH细胞中cAMP含量,SO22,536能显著降低GTH细胞中cAMP含量,FSK和SO22,536都不会影响GTH细胞的PKC活性,GTH细胞cAMP含量显著影响LH的分泌,LH随着cAMP的升高而升高,随着cAMP的降低而降低。cAMP-PKA是GnRH脉冲刺激所引起LH分泌受体后的信号转导途径。     

γ-氨基丁酸对小白鼠离体胃标本胃酸分泌的促进效应

为了探索γ-氨基丁酸(GABA)对小白鼠离体胃标本胃酸分泌(GAS)的影响及机制,在体外37℃缓冲液中培育离体、胃腔灌流并维持胃内12 cm水柱压力的全胃标本,用pHS-3型精密酸度计测定灌流液的pH。结果表明：γ-氨基丁酸(GABA)(1～10×10-7mol/L)和巴氯芬(Bac, 0.6～9.6×10-7mol/L)以一种浓度依赖的方式显著地促进胃酸分泌(GAS),而西咪替丁(Cim, 2～20×10-7mol/L)以一种浓度依赖的方式有力地抑制GAS。印防已毒素(Pic, 3×10-7mol/L)不影响基础胃酸分泌(BGAS)和GABA促进GAS的效应,而番氯芬(Phac, 0.6×10-7mol/L)能完全阻断GABA的促进效应。Cim不能完全消除GABA和Bac对GAS的促进效应。以上结果提示,在小鼠中GABA可以通过激活胃中GABAB受体促进离体胃标本的GAS,可能胃壁胆碱能神经元和非神经细胞,如壁细胞及某些内分泌细胞上都存在GABAB受体,GABA可直接或简接地剌激胃壁细胞分泌酸。     

硫辛酸抗再灌期心律失常与外源性自由基所致动作电位异常的作用

用 Langendorff 法灌流大鼠心脏。结扎冠状动脉左前降支10 min,松结再灌3 min。再灌期内对照组心室颤动发生率为100%,正常窦性心律时间缩短至29±56s。给硫辛酸组(6.8×10~(-6)1.7×lO~(-4)mol/L)心室颤动发生率下降至33—50%。正常窦性心律时间延长至97s 以上。用标准微电极技术记录豚鼠乳头肌动作电位(AP)。在黄嘌呤氧化酶(0.004U/ml)与次黄嘌呤(1Oμmol/L)氧自由基发生系统作用后第3min,未给药组 AP 各参数与对照组比较,APA、RP 和 V_(max)分别下降20%(P<0.05),16%(p<0.05)和45%(p<0.01)。给硫辛酸组(3.5×10~(-5)mol/L)AP 各参数的异常明显减轻,与对照组比较,APA,RP 和 V_(max)分别下降9%(p<0.05),9%(P<0.05)和18%(P<0.05)。给药组与未给药组比较,三项指标差别显著。上述结果提示,硫辛酸的自由基清除作用使异常动作电位得到改善,从而降低了心律失常发生率。     

克伦特罗对大鼠肝脏氮代谢及IGF-I水平的影响

目的探讨克伦特罗(CL)影响机体物质代谢的有关肝脏机制.方法利用大鼠离体肝脏灌流技术测定CL对肝脏灌流液中尿素氮水平,肝组织谷丙转氨酶(GPT)活性以及肝脏胰岛素样生长因子I(IGF-I)合成和分泌的影响.结果CL可使大鼠离体肝脏产生的尿素氮浓度下降,并有一定的剂量效应和时间效应.在给药后灌流的1、2、3、4h内1×10-6 mol/L的CL使大鼠肝脏产生的尿素氮分别下降15.02% (P>0.05)、17.97% (P>0.05)、26.76%(P<0.05)和30.08%(P<0.01),1×10-8mol/L的CL具有类似的效应.CL抑制大鼠肝组织中GPT的活性,×10-6mol/L的CL使得肝组织中GPT活性下降24.65%(P<0.05).CL还影响大鼠离体肝脏IGF-I的生成和分泌,×10-6 mol/L CL使大鼠肝组织内IGF-I的含量比对照组升高19.77%(P<0.05),灌流液中IGF-I的水平也呈增加的趋势.结论CL可通过增加对肝脏氮的储留及增强肝脏IGF-1的合成和分泌而促进机体的物质代谢.     

肾上腺糖皮质激素对体外培养的人体肝癌细胞的影响电镜观察

本工作的目的系观察肾上腺糖皮质激素对离体培养的人体肝癌细胞(BEL- 7402)引起的形态学表型改变。肝癌细胞经浓度为7.6×10~(-6)的合成糖皮质激素——地塞米松处理48小时显示,体积较对照细胞显著较大,呈扁平多边形。电镜观察到:1)激素处理48小时、浓度为7.6×10~(-7)M及7.5×10~(-6)M的两个剂量组,线粒体偶有增大及融合现象;胞膜下外细胞质区域有短的微管出现。2)处理72小时的两个剂量组,肝癌细胞的微绒毛似有减少;经常见到体积明显增大的线粒体及成片的糖元;胞质内经常出现长的、纵横交错的微管,尤以7.5×10~(-6)M组明显,弥散分布的微丝和张力纤维出现的频率也远高于对照组。本文对肝癌细胞出现的表型变化的意义进行了讨论。     

GABA对大鼠下丘脑正中隆起LHRH释放调节的研究

本研究应用大鼠下丘脑正中隆起(ME),观察 γ-氨基丁酸(GABA)和去甲肾上腺素(NA)对下丘脑促黄体生成激素释放激素(LHRH)神经元末梢分泌作用的影响。结果发现:GABA(10~(-6)mol/L)可显著促进 ME 的 LHRH 和 NA 的释放,即 LHRH 释放量由27.3±2.5pg/100ul 增加至150.4±27.9pg/100μl;NA 释放量由50.9±4.2pg/100μl 增加至105.5±19.1pg/100ul,两者与对照组相比有显著差异(P<0.01)。GABA 这些作用可被受体拮抗剂荷包牡丹碱(Bicuculline)所翻转。当荷包牡丹碱和 GABA(10~(-6)mol/L)同时存在于 ME 的培灌液中,LHRH 的分泌量下降为18.2±1.9pg/100μl,而 NA 分泌量下降为43.9±3.4pg/100μl。在内源性 NA 被利血平耗竭时,LHRH 的释放量仅增加26.5%,而 GABA 能使正常大鼠 LHRH 释放量增加451.9%。本研究提示:GABA 可促进下丘脑 ME 释放 LHRH,这一作用可能通过 NA 中介。     

睾丸酮对离体培养人蜕膜细胞形态的影响

实验选用早孕人工流产蜕膜组织进行体外培养,观察睾丸酮对蜕膜细胞形态的影响并与RU 486加以比较。研究结果提示:(1)睾丸酮(6.9×10~(-5)mol/L)能抑制离体培养人蜕膜细胞的生长发育,但这种抑制作用是暂时和可恢复的且与用药剂量及持续时间有关。(2)睾丸酮对蜕膜细胞形态的影响与RU 486(4.7×10~(-4)mol/L)的作用效果相似。     

Effect of luteinizing hormone releasing hormone pulse characteristics on comparative luteinizing hormone and follicle stimulating hormone secretion from superfused rat anterior pituitary cell cultures

We have shown that 4 ng luteinizing hormone releasing hormone (LHRH) pulses induced significantly greater luteinizing hormone (LH) release from proestrous rat superfused anterior pituitary cells with no cycle related differences in follicle stimulating hormone (FSH). Current studies gave 8 ng LHRH in various pulse regimens to study amplitude, duration and frequency effects on LH and FSH secretion from estrous 0800, proestrous 1500 and proestrous 1900 cells. Regimen 1 gave 8 ng LHRH as a single bolus once/h; regimen 2 divided the 8 ng into 3 equal 'minipulses' given at 4 min intervals to extend duration; regimen 3 gave the 3 'minipulses' at 10 min intervals, thereby further extending duration: regimen 4 was the same as regimen 2, except that the 3 'minipulses' were given at a pulse frequency of 2 h rather than 1 h. In experiment 1, all four regimens were employed at proestrus 1900. FSH was significantly elevated by all 8 ng regimens as compared to 4 ng pulses; further, 8 ng divided into 3 equal 'minipulses' separated by 4 min at 1 and 3 h frequencies (regimens 2 and 4) resulted in FSH secretion that was significantly greater than with either a single 8 ng bolus (regimen 1) or when the 'minipulses' were separated by 10 min (regimen 3). In experiment 2, at proestrus 1500, FSH response to the second pulse of regimen 4 was significantly greater than in regimen 2; LH release was significantly suppressed at pulse 2 compared to regimen 2 accentuating divergent FSH secretion. At estrus 0800, FSH response to the second pulse of regimen 4 was significantly stimulated FSH at proestrus 1900, 1500 and estrus 0800, FSH divergence was most marked at proestrus 1500. These data indicate a potential role for hypothalamic LHRH secretory pattern in inducing divergent gonadotropin secretion in the rat.     

Interactions between neuropeptide Y, luteinizing hormone-releasing hormone and estradiol in the control of luteinizing hormone release from cultured ovine pituitary cells

This study used pituitary cells in culture firstly to test the hypothesis that NPY may augment the pituitary LH response to LHRH and secondly to determine whether this interaction is dependent on the presence of estradiol. LHRH (10(-10)-10(-6) M) caused a significant increase in LH secretion from dispersed ovine pituitary cells maintained in culture for six days, a response which was enhanced when cells were pretreated for three days with 4 x 10(-11) M estradiol. NPY 10(-10)-10(-6) M) had no effect on basal LH release from ovine pituitary cells maintained either in the presence or absence of estradiol. NPY (10(-10) and 10(-8) M) also had no effect on LHRH-stimulated LH release either in the presence or absence of estradiol. These results substantiate previous observations that physiologically relevant concentrations of estradiol enhance the LH response to LHRH in cultured ovine pituitary cells. However, in contrast to experiments carried out using rat pituitary cells in culture, the present data provide no evidence to support the hypothesis that NPY alone interacts with LHRH in the control of LH secretion from the ovine pituitary gland.     

Effect of time after castration on secretion of LHRH and LH in the ram

Hypophysial portal blood and peripheral blood were obtained from conscious, unrestrained rams to measure simultaneously the secretion of LHRH and LH in entire rams and rams which had been castrated for 2-15 days (short-term castration) and for 1-6 months (long-term castration). The apparatus for portal blood collection was surgically implanted using a transnasal trans-sphenoidal approach and, 4-5 days later, portal blood and peripheral blood were collected simultaneously at 10-min intervals for 8-9 h from 15 sheep. LHRH was clearly secreted in pulses in all three physiological conditions, but there were marked differences in pulse frequencies, which averaged 1 pulse/2-4 h in entire rams, 1 pulse/70 min in short-term castrated rams and 1 pulse/36 min in long-term castrated rams. In entire and short-term castrated animals, LH profiles were also clearly pulsatile and each LHRH pulse in hypophysial portal blood was associated with an LH pulse in the peripheral blood. In long-term castrated animals, LH pulses were not as well defined, because of the high basal levels and small pulse amplitudes, and the temporal relationship between LHRH and LH pulses was not always clear. These results demonstrate the pulsatile nature of LHRH secretion under the three physiological conditions and suggest that the irregular LH profiles characteristic of long-term castrates are due to an inability of the pituitary gland to transduce accurately the hypothalamic signal. The very high frequency of the LHRH pulses may be one of the major reasons for this, and is probably also responsible for the high rate of LH secretion in the long-term castrated animal.     

Modulation of luteinizing hormone pulse amplitude by the frequency of luteinizing hormone-releasing hormone stimulation and by testosterone in castrated, hypothalamic-lesioned male rats

The frequency of spontaneous luteinizing hormone (LH) pulses is thought to be a direct result of the frequency of luteinizing hormone-releasing hormone (LHRH) pulses from the hypothalamus. By contrast, the amplitude of spontaneous LH pulses may be controlled by several factors other than the amplitude of LHRH pulses. We tested two hypotheses: 1) that LH pulse amplitude is determined in part by the frequency of LHRH pulses of constant magnitude, and 2) that testosterone (T) exerts a direct feedback effect on the pituitary gland to regulate LH pulse amplitude. Gonadal feedback was eliminated by castrating adult male rats (n = 20). Endogenous LHRH secretion was eliminated by lesioning the medial basal hypothalamus. Serum LH levels (0.19 +/- 0.04 ng/ml RP-2, mean +/- SEM) and T levels (0.15 +/- 0.02 ng/ml), measured several weeks after hypothalamic lesioning, confirmed the hypogonadotropic hypogonadal state of the animals. During a 8-h period, unanesthetized, unrestrained animals were injected with 40-ng pulses of LHRH via catheters into the jugular vein, and blood samples for LH measurement were drawn at 10-min intervals. The LHRH pulse interval was 20 min during the first 4 h in all animals. The pulse interval was doubled to 40 min in half of the animals (n = 10) during the next 4 hours; in the other 10 animals, the pulse interval was maintained constant at 20 min throughout the study. Within both of these groups, one-half of the animals (n = 5) were infused with T to achieve a physiological level of T in serum (2.46 +/- 0.36 ng/ml at 4 h), while the other half received vehicle.(ABSTRACT TRUNCATED AT 250 WORDS)     

Superfused pituitary cell cultures: comparative responsiveness of cells derived from various stages of the estrous cycle to LHRH stimulation administered as short duration pulses

We have reinvestigated the question of maintenance of differential LHRH sensitivity in culture and further investigated the role of pulsatile LHRH in the in vitro release of pulsatile LH and FSH at different stages of the estrous cycle. Pituitaries were collected on each day of the 4 day cycle at 0800. In addition, pituitaries were also collected at 1500 and 1900 on proestrous. The cells were dispersed and exposed 48 hrs later to short duration 4 ng LHRH pulses; this dose was optimized for LH release and was applied at a frequency of 1 pulse/60 min. In terms of absolute magnitude of LH response, observed responsiveness was ranked in the following order: proestrous 1900 greater than estrous 0800 greater than diestrous 1 0800 greater than proestrous 1500 greater than diestrous 2 0800. Responsiveness was significantly greater at proestrous 1900 (p greater than 0.01), estrous 0800 (p greater than 0.05) and diestrous 1 0800 (p greater than 0.05) when compared to either of the other stages tested. The heightened LHRH sensitivity of proestrous was therefore maintained in cell culture indicating that the system should be valid for conducting studies on the control of gonadotropin secretion during this period. FSH did not respond in pulsatile manner to the LHRH levels employed further substantiating recent evidence that LHRH seems to function somehow less directly in FSH as compared to LH secretion.     

The induction of divergent gonadotropin secretion in vitro by variations in luteinizing hormone releasing hormone pulse regimen

The effects of luteinizing hormone releasing hormone (LHRH) pulse amplitude, duration, and frequency on divergent gonadotropin secretion were examined using superfused anterior pituitary cells from selected stages of the rat estrous cycle. Cells were stimulated with one of five LHRH regimens. With low-amplitude LHRH pulses (regimen 1) in the presence of potentially estrogenic phenol red, LH response in pituitary cells from proestrus 1900, estrus 0800, and diestrus 1,0800 were all significantly larger (P less than 0.05) than the other stages tested. In the absence of phenol red, responsiveness at proestrus 1900 was significantly larger than proestrus 0800, proestrus 1500, and estrus 0800 (P less than 0.01, 0.05, and 0.05, respectively); other cycle stages tested were smaller. No significant differences were observed between cycle stages for follicle-stimulating hormone (FSH) secretion in the presence or absence of phenol red. Because pituitary cells at proestrus 1900 were the most responsive to low-amplitude 4 ng LHRH pulses, they were also used to study the effects of LHRH pulses of increased amplitude or duration and decreased frequency. Increasing the amplitude (regimen 2) or the duration (regimens 3 to 5) increased FSH secretion; this effect was greatest with regimens 3 and 5. When regimens 3 and 5 were studied in pituitary cells obtained at proestrus 1500, FSH was significantly increased by both regimes, but most by regimen 5; furthermore, LH release was significantly reduced. When regimens 3 and 5 were studied in pituitary cells obtained at estrus 0800, FSH release was elevated most significantly by regimen 5. Thus, variations in LHRH pulse regimen were found to be capable of inducing significant divergence in FSH release from superfused anterior pituitary cells derived from specific stages of the estrous cycle.     

Luteinizing hormone secretion from the quail pituitary in vitro

An enzymatically dispersed pituitary preparation from Japanese quail (Coturnix coturnix) was used to study the dynamics of gonadotropin release. After an 18-h incubation, the cells were challenged with different luteinizing hormone-releasing hormones (LHRH) for 90 min. Using pituitary cells from mature males, mammalian and chicken LHRH I (Gln8-LHRH) had approximately equal luteinizing hormone (LH)-releasing activity whereas chicken LHRH II (His5, Trp7, Tyr8-LHRH) was 8-9 times more potent. The LHRH agonist (Trp6, Pro9-NEt-LHRH) had 15 times greater potency than chicken LHRH I. Pre-incubation with an LHRH antagonist (D-Phe2, D-Trp6-LHRH) significantly suppressed LH release. Acid extracts of median eminence released LH from pituitary cells, extracts from short-day and long-day males had equal activity, while tissue extracts from castrated males had significantly greater LH-releasing activity. Pituitary cells from sexually immature males released LH in response to chicken LHRH I in a similar profile to cells from mature males. These data indicate that the quail LHRH receptor in the male recognizes several different molecular species of LHRH and the response to LHRH is comparable between short- and long-day males. Pituitary cells from ovulating females were variably sensitive to LHRH peptides, possibly due to changes in pituitary sensitivity during the ovulatory cycle. Pituitary cells from immature females did not release LH in response to chicken LHRH I. However, pituitary cells from immature females photostimulated for 1 wk displayed a response to chicken LHRH I and II similar to that of pituitary cells from males.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulation of the secretion of luteinizing hormone by ginsenoside-Rb1 in male rats

Ginsenoside-Rb1 is one of the pharmacologically active components of ginseng, the dry root of Panax ginseng C. A. Meyer (Araliaceae), a well-known traditional Chinese medicine. Ginseng enhanced mounting behaviour of male rats and increased sperm counts in rabbit testes. Some experimental results suggested no sex hormone-like function in ginseng but probably gonadotropin-like action. The present study was to explore the effect of ginsenoside-Rb1 on the secretion of luteinizing hormone (LH) both in vivo and in vitro. Male rats were orchidectomized (Orch) for 2 weeks or subjected to swim training for 1 week before catheterization via the right jugular vein. They were intravenously injected with ginsenoside-Rb1 (10 microg/kg) or saline at 15 min prior to a challenge of gonadotropin-releasing hormone (GnRH) or 10 min-swim. Blood samples were collected at several time intervals following intravenous injection of ginsenoside-Rb1. In the in vitro experiment, male rats were decapitated and their anterior pituitary gland (APs) were either bisceted or enzymatically dispersed. The hemi-APs were preincubated with Locke's medium at 37 degrees C for 90 min and then incubated with Locke's medium containing ginsenoside-Rb1 (10(-7) - 10(-4) M) for 30 min. The dispersed AP cells (1 x 1(5) cells per well) were primed with dihydrotestosterone (DHT, 10(-8) M) for 3 days, and then challenged with ginsenoside-Rbl (10(-6) and 10(-5) M, n = 8) for 3 h. The concentrations of LH or testosterone in samples were measured by radioimmunoassays. Administration of ginsenoside-Rb1 did not alter the levels of plasma LH in both intact and Orch rats but significantly increased plasma LH concentration at the termination of the 10 min swimming exercise. Administration of ginsenoside-Rb1 resulted in a lower testosterone response to GnRH challenge or swimming exercise as compared with saline-treated rats. Ginsenoside-Rb1 dose-dependently increased the release of LH from both hemi-AP tissues and the DHT-primed dispersed AP cells in vitro. These results suggest that ginsenoside-Rb1 increases LH secretion by acting directly on rat AP cells.     

Norepinephrine-stimulated in vitro release of luteinizing hormone-releasing hormone (LHRH) from median eminence tissue is facilitated by inhibition of LHRH-degrading activity in hens

We and others have previously reported the existence of hypothalamic and anterior pituitary (AP) enzymes that degrade luteinizing hormone (LH)-releasing hormone (LHRH). We have further characterized these LHRH-degrading activities (LHRH-DA) and in addition assessed the role of LHRH-DA in LHRH release from median eminence (ME) tissue in vitro. Major LHRH-DA components were separated and their molecular weights were estimated by gel filtration chromatography. The role of LHRH-DA in LHRH release was determined by release studies from isolated ME, in the presence and absence of N-tosyl L-phenylalanine chloromethyl ketone (TPCK) and/or norepinephrine (NEpi). Degradation and in vitro release studies were performed by using LHRH analogs with amino acid substitutions at their 5-6 bond. Biological activity of these analogs was assessed by measuring in vitro LH release from dispersed anterior pituitary cells. LHRH-DA was determined by high-performance liquid chromatography; LH and LHRH were measured by radioimmunoassay. Separation of LHRH-DA by gel filtration chromatography yielded two major enzymatic activities: a Tyr5-Gly6 cleaving endopeptidase and a post-proline cleaving enzyme. Although LHRH-DA from AP and ME produced identical degradation fragments, the former had 3-fold greater specific activity than the latter. LHRH moieties with a Tyr5-Gly6 bond substitution were more resistant to enzymatic degradation and had greater biological activity than LHRH moieties with a Tyr5-Gly6 bond. TPCK decreased LHRH-DA and increased NEpi-stimulated in vitro release of LHRH from isolated ME.(ABSTRACT TRUNCATED AT 250 WORDS)     

Further evidence that prolactin does not affect gonadotropin release at pituitary level

In a primary monolayer cell culture of the anterior pituitary from mature male rats the effects of exogenous rPrl (rPrl exog.) and endogenously secreted rPrl (rPrl endog.) on basal and LHRH stimulated LH secretion were investigated. In pilot studies basal Prl- and LH secretion as well as influence of various LHRH concentrations (10(-1)-10(+3) ng/ml) on Prl- and LH release were observed. The influence of exogenous rPrl was studied at various concentrations (50-500 ng/ml) and with preincubation periods of 2 hrs and 6 hrs before starting LHRH stimulation. The dopamine agonist bromocriptine and the dopamine antagonist sulpirid were preferentially used to prove physiologic function of the cell system presented. Basal LH secretion started after a delay of 3 hrs, whereas basal Prl secretion began immediately showing a linear rise for 9 hrs. LHRH stimulation resulted in a non-linear dose and time dependent LH secretion. LHRH showed no influence on endogenous Prl (rPrl endog.) secretion of the mammotroph cells. Exogenous Prl (rPrl exog.) did not affect spontaneous Prl release excluding ultra short loop inhibition in this cell system. Furthermore, exogenous Prl had no effect on either basal or LHRH stimulated LH secretion even after a preincubation period of up to 6 hrs and at concentrations generally observed for prolactin secreting tumors. Bromocriptine suppressed endogenous Prl release and did not affect LH secretion. Sulpirid had no influence on either Prl or LH secretion.(ABSTRACT TRUNCATED AT 250 WORDS)