卵巢纤蛋白溶酶原激活因子及其抑制因子的研究

本文综述了近年来作者在研究卵巢纤蛋白溶酶原激活因子(PA)及其抑制因子(PAI)的某些成果。PA是一种高效能蛋白水解酶激活因子,它激活纤蛋白溶酶原成为纤蛋白溶酶,此酶在纤蛋白水解过程中起重要作用。已有证据表明,PA与排卵有关。我们进一步研究发现:(1)在大鼠卵巢体细胞中存在两种PA,即组织型PA(tPA)和尿激酶型PA(uPA);而在卵细胞中只发现tPA;(2)大鼠卵巢tPA明显受促性腺激素和其他激素调节,并在排卵前达到高峰,而uPA没有明显变化;(3)在卵巢体细胞中还发现一种PA的抑制因子(PAI),它与PA结合形成复合体,能部分或完全消除PA活性;(4)只有tPA与大鼠排卵有关;PA和PAI间的相互作用和随激素的波动而引起的动态变化可能对维持卵巢正常生理功能和排卵起重要作用。     

猕猴精浆纤溶酶原激活因子的来源及在精子获能中的作用

我们的前期工作表明,不育症人精液中纤溶酶原激活因子（plasminogen activator;PA）活性明显升高;给成年办和猕猴注射长效睾酮诱发无精过程中,精液PA含量也伴随上升,为进一步查明PA的来源和对精子的作用,原位杂交检测组织型PA（tPA）,尿激酶型PA（uPA）及PA抑制因子－1（PAI-1)泊mRNAs在成年健康猕附睾、前列腺和精囊中的表达。体外培养猕猴精子,培液中加入uPA、tPA及其底物纤溶酶原（plasminogen）,测试PA对精子活力、顶体反应及激活卵子的影响。结果表明,猕猴附睾、前列腺和精囊均表达tPA、uPA和PAI-1 mRNAs。加入uPA能维持精子的活力,使精子产生超激活运动,诱导顶体反应的发生,并使精子获得激活卵子的能力,这说明猕猴精浆PA除来源于睾丸外,可能主要来源于附睾及附性腺;在体外,uPA,而不是tPA,可能诱导精子获能。     

小鼠排卵前后卵巢纤蛋白溶酶原激活因子活性的变化

给幼龄小鼠注射PMSG刺激滤泡生长,随后注射hCG以诱发排卵。在激素处理的不同时间取出卵巢,制备卵巢匀浆液或从卵巢中分离颗粒细胞和卵丘-卵母细胞复合体,并做离体培养。样品中组织型(tPA)和尿激酶型(uPA)纤蛋白溶酶原激活因子经SDS-凝胶电泳分离,用纤蛋白铺盖技术测定。实验结果表明,注射hCG 8h后15％的受试动物排卵,而卵巢匀浆液和颗粒细胞中tPA和uPA活性分别也在hCG注射后4和8h达到高峰。排卵后酶活性下降。卵丘-卵母细胞复合体主要含tPA,注射hCG 12—24h达到高峰。上述资料证明,tPA和uPA都参入小鼠排卵过程。因为排出的卵子中仍含有大量tPA,卵细胞的tPA除参与排卵外,可能对排卵后的一些生理过程也起重要作用。     

人子宫内膜纤蛋白溶酶元激活因子及其抑制因子的分布与调控

人子宫内膜中存在组织型(tPA)及尿激酶型(uPA)两类纤蛋白溶酶元激活因子,其含量在增殖期高于分泌期。本文应用免疫组织化学定位证实uPA及tPA两类抗原存在于子宫内膜的腺体细胞和间质细胞中。应用SDS-PAGE分高蛋白质,继而应用纤蛋白-琼脂糖铺盖技术测得离体培养下间质细胞仅释放tPA,腺体细胞仅释放uPA,但两种细胞均分泌PA的抑制因子(PAI)。培液中加入孕酮,明显抑制PA和刺激PAI生成。雌二醇作用与孕酮相反。某些肽类激素hCG、PRL、GnRH及cAMP作用基本与雌二醇相同。但福司克林(FK)则刺激间质、腺体两种细胞产生tPA及少量uPA,抑制PAI生成。本工作表明人子宫内膜中存在PA及PAI作用相反的酶,受激素调控,其生理意义尚待进一步探讨。     

三七皂苷Rg1对tPA和PAI-1活性的调节作用

探讨三七皂苷Rg1对组织型纤溶酶原激活物(tPA)和纤溶酶原激活物抑制物(PAI-1)活性的调节作用。运用发色底物方法测定三七皂苷Rg1在体外和静脉注射对家兔血浆纤溶酶原激活物(tPA)和血浆或血小板释放的纤溶酶原激活物抑制物(PAI-1)水平的影响。结果表明,三七皂苷Rg1在体外呈浓度依赖性明显抑制血浆PAI-1活性,同时提高血浆tPA活性;30和60 mg/kg的三七皂苷Rg1静脉注射显著抑制血浆PAI-1活性,提高血浆tPA活性,同时降低凝血酶激活的血小板所释放的PAI-1水平。本实验提示三七皂苷Rg1能抑制PAI-1活性,同时升高tPA活性可能是其抗血栓作用的分子机制之一。     

促乳素抑制促性腺激素诱导小鼠卵巢的纤蛋白溶酶原激活因子增加和排卵

为进一步研究纤溶酶原激活因子(PA)在排卵中的作用,我们观察了促乳素(PRL)对hCG诱导小鼠卵巢PA增加和排卵的影响。实验结果表明;(1)PRL抑制促性腺激素诱导小鼠排卵。当bCG注射18 h后,在输卵管中发现卵子平均为31.1±6.7,而hCG加PRL组为19.7±4.9;当hCG注射24 h后,输卵管中发现卵子数为32.3±10.8,hCG加PRL组为20.3±5.4;其抑制率分别为36.5％和37％;(2)PRL对排卵的抑制作用是通过抑制促性腺激素对小鼠颗粒细胞(GC)和膜-间质细胞(TIC)PA分泌的结果;(3)在离体实验中PRL也明显抑制促性腺激素对小鼠GC PA分泌的作用。这些结果进一步证实PA在排卵过程中的重要作用。     

血管内皮细胞介导的纤溶作用

血管内皮细胞可合成和释放tPA、uPA和PAI-1,也提供纤溶成份之间相互作用的活性表面,在纤溶的启动和调节中起重要作用。内皮细胞介导的纤溶作用受到神经激素,生长因子、血浆成份、血细胞、血管壁基质和许多外源性物质的调控。     

纤溶酶原激活因子与猕猴精子运动力的关系及其在附睾和附性腺中的表达调节

用11酸睾酮诱导猕猴少精子症和弱精子症及单侧隐睾手术诱导单侧少精子症和弱精子症模型,观察对附睾头、附睾体、附睾尾、前列腺和精囊组织型PA（tPA）、尿激酶型PA（uPA）及抑制因子-1（PAI-1）mRNA表达的影响。原位杂交的结果表明11酸睾酮诱导少精子症和弱精子症,tPA mRNA的表达在附睾头、精囊及前列腺减少,而在附睾体升高,附睾尾表达基本无变化;uPA mRNA的表达在附睾头、附睾体、前列腺减少,而在精囊升高,附睾尾表达基本无变化;PAI-1 mRNA的表达在附睾头、附睾体、精囊下降,而在前列腺升高,附睾尾表达无显著变化。单侧隐睾手术不影响tPA、uPA和PAI-1 mRNA的表达。这些结果提示附睾头和附睾体分泌的uPA可能与精子前向运动能力的获得相关。tPA、uPA和PAI-1 mRNA在猕猴附睾头部和体部、前列腺和精囊中的表达可能受睾酮的调节,但不受睾丸分泌因子及温度的影响,且在不同部位睾酮的调节具不同的特征,而附睾尾tPA、uPA和PAI-1的表达则可能是组成性表达。     

人精子中尿激酶型纤溶酶元激活因子的免疫组织化学定位观察

本文采用免疫组织化学和免疫电镜对正常人精子中尿激酶型纤溶酶元激活因子（ＵＰＡ）的分布进行了定位观察。结果发现尿激酶型纤溶酶元激活因子分布在精子顶部体内外膜和精子头部浆膜上,且精子尾部浆膜上也有阳性着色,提示尾部浆膜上也有尿激酶型纤溶酶元激活因子的存在。推测精子中尿激酶型纤溶酶元激活因子可能与精子的运行、获能、顶体反应及受精有关联。     

促性腺激素诱导猕猴排卵周期中卵巢纤溶酶原激活因子与抑制因子的变化

在用 PMSG 和 hUG 诱导猕猴排卵过程中,我们研究了 pA 和它的抑制因子 PAI-1与排卵的关系。实验结果表明,由促性腺激素所诱导出的卵巢 tPA 活性的增加与排卵密切相关,在排卵前达到高峰,而排卵后明显下降;uPA 只在排卵后的颗粒细胞大量出现;PAI-1分泌高峰比 tPA 峰值早出现12—24小时;排卵来临时,tPA 的明显上升导致 PAl-1的空然下降。上述实验结果说明,卵巢中 tPA 和 PAI-1活性的这种平衡性的变化可能在排卵机制和维持卵巢的正常生理功能中起重要作用,而 uPA 或许与黄体形成的调节有某些关系。     

大鼠卵巢细胞分泌纤溶酶原激活因子抑制因子（PAI—1）的...

Rat ovarian cells produce not only plasminogen activator (tPA) but also plasminogen activator inhibitor type 1 (PAI-1), and their coordinated geneexpression induced by gonadotropins are thought to be responsible for follicular rupture. In this study, it was demonstrated that (1) theca-interstitial compartment synthesizes the majority of PAI-1 activity in the ovary before ovulation, the follicular wall may therefore serve as a specific barrier to prevent the secretion of PA into the extrafollicular compartment; (2) Granulosa cells contribute only small amount of ovarian PAI-1 activity, but synthesize most of tissue-type plasminogen activator activity involved in the process leading to ovulation: (3) Since only matured cumulus-oocyte complexes secrete high level of tPA and PAI-1, both tPA and PAI-1 activity in the conditioned medium may be used as reliable markers for evaluating oocyte quality for in vitro fertilization.     

促性腺激素诱导猕猴排卵周期中卵巢纤溶酶...

Changes of plasminogen activator (PA) and its inhibitor (PAI-1) activity and antigen have been investigated during PMSG/hCG induced ovulation in rhesus monkeys. It has been demonstrated that the ovarian tissue type PA (tPA) activity, which reaches maximum prior to ovulation and declines thereafter, is closely related to follicular rupture; significant increases in urokinase type PA (uPA) only occurs in granulosa cells after ovulation. Since the secretory activity of ovarian PAI-1 reaches its peak level 12-24 h earlier than tPA the rapid decrease in PAI-1 activity in the approach of ovulation is correlated with the elevation of tPA activity. It is, therefore, suggested that a counterbalance of tPA and PAI-1 activity within the ovary may play an important role in the ovulation mechanism, whereas uPA may be involved in the regulation of corpus luteum formation.     

tPA Involvement in Ovulation──Studies on Mechanism of Ovulation：Role of Tissue Type Plasminogen Activator

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Tissue-specific and time-coordinated hormone regulation of plasminogen-activator-inhibitor type I and tissue-type plasminogen activator in the rat ovary during gonadotropin-induced ovulation

The plasminogen-activator system provides proteolytic activity in many biological processes. The regulation of plasminogen activation may occur at many levels including the synthesis and secretion of plasminogen activators (PA) and the specific inhibition of PA activity by inhibitors. PA-inhibitor type-1 (PAI-1) is an efficient inhibitor of tissue-type PA (tPA) and urokinase-type PA (uPA) that may therefore be instrumental for the control of plasminogen activation. To investigate if coordinated regulation of PA and PA inhibitors take place in vivo in response to physiological signals, we have examined the regulation of PAI-1 and tPA in the ovary during gonadotropin-induced ovulation. We found that PAI-1, as well as tPA activity and mRNA levels, were coordinately regulated by gonadotropins in a time-dependent and cell-specific manner, such that a surge of PA-activity was obtained just prior to ovulation. Both theca-interstitial and granulosa cells synthesized PAI-1, but their maximal PAI-1 expression occurred at different times during the periovulatory period, ensuring inhibition of proteolytic activity in ovarian extra cellular compartments both before and after ovulation. The coordinated regulation of tPA and PAI-1 in the ovary may fine-tune the peak of PA activity which may be important for the regulation of the ovulatory process.     

Regulation of tissue-type plasminogen activator and plasminogen activator inhibitor type-1 in cultured rat Sertoli and Leydig cells

New data are provided to show that (i) rat Sertoli cells produce two types of plasminogen activators, tissue type (tPA) and urokinase type (uPA), and a plasminogen activator inhibitor type-1 (PAI-1); (ii) both tPA (but not uPA) and PAI-1 secretion in the culture are modified by FSH, forskolin, dbcAMP, GnRH, PMA and growth factors (EGF and FGF), but not by hCG and androstenedione (△4); (iii) in vitro secretion of tPA and PA-PAI-1 complexes of Sertoli cells are greatly enhanced by presence of Leydig cells which produce negligible tPA but measurable PAI-1 activity;(iv) combination culture of Sertoli and Leydig cells remarkably increases FSH-induced PAI-1 activity and decreases hCG- and forskolin-induced inhibitor activity as compared with that of two cell types cultured alone. These data suggest that rat Sertoli cells, similar to ovarian granulosa cells, are capable of secreting both tPA and uPA, as well as PAI-1. The interaction of Sertoli cells and Leydig cells is essential for the cells to response to     

Biphasic regulation of tissue plasminogen activator activity in ischemic rat brain and in cultured neural cells: essential role of astrocyte-derived plasminogen activator inhibitor-1

In brain, the serine protease tissue plasminogen activator (tPA) and its endogenous inhibitor plasminogen activator inhibitor-1 (PAI-1) have been implicated in the regulation of various neurophysiological and pathological responses. In this study, we investigated the differential role of neurons and astrocytes in the regulation of tPA/PAI-1 activity in ischemic brain. The activity of tPA peaked transiently and then decreased in cortex and striatum along with delayed induction of PAI-1 in the inflammatory stage after MCAO/reperfusion injury. In cultured primary cells, glutamate stimulation increased tPA activity in neurons but not in other cells such as microglia and astrocytes. With LPS stimulation, a model of neuroinflammatory insults, robust PAI-1 induction was observed in astrocytes but not in neurons and microglia. The upregulation of PAI-1 by LPS in astrocytes was also verified by RT-PCR analysis as well as PAI-1 promoter reporter assay. Lastly, we checked the effects of hypoxia on tPA/PAI-1 activity. Hypoxia increased tPA release from neurons without effects on microglia, while the activity of tPA in astrocyte was decreased consistent with increased PAI-1 activity in astrocyte. Taken together, the results from the present study suggest that neurons are the major source of tPA and that the glutamate-induced stimulated release is mainly governed by neurons in the acute phase. In contrast, the massive up-regulation of PAI-1 in astrocytes during subchronic and chronic inflammatory conditions, leads to decreased tPA activity in the later stages of MCAO. Differential regulation of tPA and PAI-1 in neurons, astrocytes and microglia suggest more attention is required to understand the role of local tPA activity in the vicinity of individual cell types.     

Expression of plasminogen activator and plasminogen activator inhibitor mRNA in human fibroblasts grown on different substrates

mRNA levels for urokinase type plasminogen activator (uPA), tissue type plasminogen activator (tPA), plasminogen activator inhibitor-1 (PAI-1) and plasminogen activator inhibitor-2 (PAI-2) were examined in human diploid (neonatal foreskin) fibroblasts grown in 200-ml microcarrier suspension culture. Four different substrates were used. These included gelatin-coated polystyrene plastic, DEAE-dextran, glass-coated polystyrene plastic and uncoated polystyrene plastic. Our previous studies have shown that culture fluids from diploid fibroblasts grown on DEAE-dextran contained higher levels of plasminogen-dependent fibrinolytic activity than culture fluids from the same cells grown on other substrates. The increased plasminogen activator activity was due largely to elevated amounts of tPA (In Vitro Cell. Develop. Biol. 22: 575–582, 1986). The present study shows that there is a corresponding elevation of tPA mRNA in diploid fibroblasts cultured on DEAE-dextran relative to the other substrates. There does not appear to be any difference in uPA mRNA or in mRNA for PAI-1 or PAI-2 produced by the same cells on the four substrates. These data suggest that the influence of the substrate on plasminogen activator production is mediated at the genetic level.     

Kinetic analysis of the interactions between plasminogen activator inhibitor 1 and both urokinase and tissue plasminogen activator

Plasminogen activator inhibitor 1 (PAI-1) was purified from medium conditioned by cultured bovine aortic endothelial cells by successive chromatography on concanavalin A Sepharose, Sephacryl S-200, Blue B agarose, and Bio-Gel P-60. As shown previously for conditioned media (C. M. Hekman and D. J. Loskutoff (1985) J. Biol. Chem. 260, 11581-11587) the purified PAI-1 preparation contained latent inhibitory activity which could be stimulated 9.4-fold by sodium dodecyl sulfate and 45-fold by guanidine-HCl. The specific activity of the preparation following treatment with 0.1% sodium dodecyl sulfate was 2.5 X 10(3) IU/mg. The reaction between purified, guanidine-activated PAI-1 and both urokinase and tissue plasminogen activator (tPA) was studied. The second-order rate constants (pH 7.2, 35 degrees C) for the interaction between guanidine-activated PAI-1 and urokinase (UK), and one- and two-chain tPA are 1.6 X 10(8), 4.0 X 10(7), and 1.5 X 10(8) M-1 S-1, respectively. The presence of CNBr fibrinogen fragments had no affect on the rate constants of either one- or two-chain tPA. Steady-state kinetic analysis of the effect of PAI-1 on the rate of plasminogen activation revealed that the initial UK/PAI-1 interaction can be competed with plasminogen suggesting that the UK/PAI-1 interaction may involve a competitive type of inhibition. In contrast, the initial tPA/PAI-1 interaction can be competed only partially with plasminogen, suggesting that the tPA/PAI-1 interaction may involve a mixed type of inhibition. The results indicate that PAI-1 interacts more rapidly with UK and tPA than any PAI reported to date and suggest that PAI-1 is the primary physiological inhibitor of single-chain tPA. Moreover, the interaction of PAI-1 with tPA differs from its interaction with UK, and may involve two sites on the tPA molecule.     

Insulin-like growth factor-binding protein-5 activates plasminogen by interaction with tissue plasminogen activator, independently of its ability to bind to plasminogen activator inhibitor-1, insulin-like growth factor-I, or heparin

Transgenic mice expressing IGFBP-5 in the mammary gland exhibit increased cell death and plasmin generation. Because IGFBP-5 has been reported to bind to plasminogen activator inhibitor-1 (PAI-1), we determined the effects of this interaction in HC11 cells. PAI-1 prevented plasmin generation from plasminogen and inhibited cleavage of focal adhesions, expression of caspase 3, and cell death. IGFBP-5 could in turn prevent the effects of PAI-1. IGFBP-5 mutants with reduced affinity for IGF-I (N-term) or deficient in heparin binding (HEP- and C-term E and F) were also effective. This was surprising because IGFBP-5 reportedly interacts with PAI-1 via its heparin-binding domain. Biosensor analysis confirmed that, although wild-type IGFBP-5 and N-term both bound to PAI-1, the C-term E had greatly decreased interaction with PAI-1. This suggests that IGFBP-5 does not antagonize the actions of PAI-1 by a direct molecular interaction. In a cell-free system, using tissue plasminogen activator (tPA) and urokinase plasminogen activator (uPA) to activate plasminogen, PAI-1 inhibited plasmin generation induced by both activators, whereas IGFBP-5 prevented the effects of PAI-1 on tPA but not uPA. Furthermore, we noted that IGFBP-5 activated plasminogen to a greater extent than could be explained solely by inhibition of PAI-1, suggesting that IGFBP-5 could directly activate tPA. Indeed, IGFBP-5 and the C-term E and F were all able to enhance the activity of tPA but not uPA. These data demonstrate that IGFBP-5 can enhance the activity of tPA and that this can result in cell death induced by cleavage of focal adhesions. Thus IGFBP-5 can induce cell death by both sequestering IGF-I and enhancing plasmin generation.