胰岛素样生长因子与哺乳动物的胚胎发育

综述了胰岛素样生长因子(IGFs)在胚胎发育过程中的表达特点和对胚胎发育的作用。许多研究表明,IGFs、IGF受体、IGF结合蛋白(IGFBPs)在不同发育阶段的胚胎中具有不同的表达特点,并具有组织特异性。不论是母体来源的、胎儿自身产生的、还是外源性的IGFs都能促进细胞分化和增殖,对胚胎发育有重要作用。     

卵巢中的胰岛素样生长因子系统

本文详细阐述了胰岛素样生长因子（IGFs)系统各个成员的结构及其在卵巢中的表达和作用机制。IGFs是这一系统的中间环节,与IGFs受体作用刺激卵巢细胞中类固醇激素的生产和DNA合成,能够介导和扩大促性腺激素对卵巢功能的作用。IGFs与胰岛素样生长因子结合蛋白（IGFBPs)发生高亲和性结合,卵巢中自由的IGFs的水平受IGFBPs的调节。而IGFBPs蛋白酶能够降低IGFBPs和IGFs的亲和性,从而参与调节IGFs在卵巢中的作用。深入的研究这一系统,对于进一步了解卵巢卵泡生长发育、分化以及闭锁,卵泡细胞的增殖和凋亡的内在机制,以及提高动物的繁殖力有重要意义。     

胰岛素样生长因子-Ⅰ(IGF-Ⅰ)、IGF结合蛋白-2和LH受体mRNA在卵泡闭锁过程中的表达及调节

研究了IGF-Ⅰ、IGF结合蛋白-2(IGFBP-2)和促黄体激素受体(LHR)mRNA在卵泡闭锁过程中的表达及调节.给26日龄大鼠注射15 IU PMSG,经检测,证实PMSG处理48 h后,一些小窦状卵泡的颗粒细胞已发生凋亡;96 h在排卵前卵泡中已可检测到凋亡细胞;120 h大多数的排卵前卵泡中均出现大量的凋亡细胞.48～120 h IGF-Ⅰ主要在窦前卵泡和小窦状卵泡表达;48与96 h,窦前与窦状卵泡的膜细胞均表达高水平的IGFBP-2.在48 h,颗粒细胞中有LHR的强信号,但在96和120 h,颗粒细胞的LHR表达减弱(P＜0.001).表皮生长因子(EGF)和IGF-Ⅰ均抑制窦前和窦状卵泡颗粒细胞凋亡.同时观察到EGF促进IGF-Ⅰ mRNA表达,IGF-Ⅰ刺激排卵前卵泡表达LHR mRNA.上述结果表明,各级卵泡的闭锁可能均受EGF和IGF-Ⅰ相互作用的调节.     

表皮生长因子与哺乳动物生殖的关系

表皮生长因子与哺乳动物生殖的关系岳占碰杨增明（东北农业大学生物工程系哈尔滨１５００３０）关键词表皮生长因子哺乳动物生殖表皮生长因子（ｅｐｉｄｅｒｍａｌｇｒｏｗｔｈｆａｃｔｏｒ,ＥＧＦ）是一种多肽类生长因子,该因子在人和动物各种组织器官生长发育过程中是...     

IGF-Ⅰ及其受体、IGF结合蛋白-2和LH受体mRNA在卵泡中的表达

利用原位杂交和原位DNA－3’末端标记的方法研究了胰岛素样生长因子河（IG－I）、IGF－I受体、IGF结合蛋白－2、和促性腺激素受体的信使核糖核酸（mRNA）在不同生长与闭锁阶段的大鼠卵巢卵泡中表达的变化。结果表明：IGF－I主要在正常生长的初级卵泡、窦前卵泡和小窦状卵泡中表达。在各生长与成熟阶段的卵泡中都检测到IGF－I受体mRNA,闭锁卵泡的IGF－I受体表达降低。窦前与窦状的生长和闭锁卵泡均表达IGFBP－2。促卵泡激素（FSH）受体在窦前和小窦状卵泡的表达水平比其在大卵泡中的高。窦前与小窦状卵泡仅在膜细胞中表达黄体生成素（LH）受体mRNA,大卵泡的膜细胞与颗粒细胞均表达LH受体,在闭锁卵泡中仅在膜细胞中观察到LH受体的信号。综上结果,提示IGF－I,IGF－I受体和FSH受体在窦前和小窦状卵泡中的协同表达对卵泡的早期发育有重要作用。LH受体mRNA特异地在大卵泡的颗粒细胞中表达可能与优势卵泡选择相关。     

哺乳动物卵巢中生殖干细胞的研究历史与进展

对于出生后的哺乳动物卵巢中是否存在生殖干细胞以维持卵泡的更新一直争议不断,现就该领域的研究历史及最新进展进行综述.     

IGF系统的生物学功能及其与肿瘤的关系

胰岛素样生长因子（insulin-like growth factor,IGF)是体内重要的生长因子。它对组织细胞的增殖。分化,凋亡,机体的生长发育及肿瘤的发生发展起重要的调节作用。IGF系统的组成包括;IGF-Ⅰ,IGF-Ⅱ,IGF-ⅠR,IGF-ⅡR,IGFBP家族,IGF促增殖,促生长的活性主要由IGF-IR介导;IGF-ⅡR的主要作用是清除游离IGF-Ⅱ,调节IGF-Ⅱ的水平,IGFBP1-6是IGFs活性的调节因子。近年的研究表明它们也有不依赖IGF的生物活性。     

雌性哺乳动物生殖干细胞：在争议中前进

100多年以来,雌性哺乳动物出生后是否存在生殖干细胞的争议尚无定论．2004年,研究人员从出生后的小鼠卵巢中发现并分离到雌性生殖干细胞(female germline stem cells,FGSCs),挑战了存在近半个世纪的理论：哺乳动物出生后不会对卵母细胞库进行更新．随后很多研究不仅指出哺乳动物出生后卵巢中新生成的卵母细胞源自FGSCs,而且发现如果将FGSCs移植回受体卵巢,它们能够产生功能性的卵母细胞并由此得到健康的后代．可是,有的研究小组重复实验或者精心设计实验,却未得到相同的结果,甚至得出相反的结果．最近,有研究者从育龄女性卵巢中分离到了在体内外都能够分化出功能性卵母细胞的FGSCs,不过这些卵母细胞的受精能力还有待证实．本文回顾了哺乳动物FGSCs的研究历程,并对这一存在已久的争论以及FGSCs研究方向和将来的运用前景展开了评述．     

二花脸和大白猪的脂肪组织中GH—R、IGF—1和IGF—IR基因表达的发育性变化

分别于出生当天、3、2 0、30、4 5、90、12 0、180日龄随机屠宰二花脸公、母猪各 4头 (30日龄仅有公猪 ) ,于 2 0、30、90、12 0、180日龄随机屠宰大白猪公猪 4头 ,采集背部皮下脂肪组织。用RT PCR方法 ,以 18SrRNA作内标 ,定量分析脂肪组织中生长激素受体 (GH R)、胰岛素样生长因子 1(IGF 1)及胰岛素样生长因子Ⅰ型受体 (IGF ⅠR)基因表达的发育性变化 ,并进行品种和性别间比较。结果表明 :脂肪组织中GH RmRNA的表达有明显的发育性变化及品种差异 ,二花脸母猪GH RmRNA水平出生时较低 ,4 5日龄达到高峰 ,之后维持稳定 ;二花脸公猪GH RmRNA水平在出生时较高 ,至 4 5日龄达到最高值 ,之后显著下降 ,但总体上没有性别差异 ;大白猪公猪GH RmRNA水平极显著低于二花脸公猪 (P <0 0 1)。脂肪组织中IGF 1mRNA的表达有明显的发育性变化及性别和品种差异 ,二花脸母猪显著低于公猪 (P <0 0 5 ) ,大白猪公猪极显著低于二花脸公猪 (P <0 0 1) ;脂肪组织中IGF ⅠRmRNA的表达有明显的发育性变化 ,但在总体上没有明显的性别和品种差异。结果提示 :猪脂肪组织中GH R、IGF 1和IGF ⅠR的基因表达有特定的发育模式 ,IGF 1基因表达的品种差异可能正是两品种猪脂肪沉积规律不同的主要原因之一。     

The circadian timing system and reproduction in mammals.

Circadian systems in a wide variety of organisms all appear to include three basic components: 1) biological oscillators that maintain a self-sustained circadian periodicity in the absence of environmental time cues; 2) input pathways that convey environmental information, especially light cues, that can entrain the circadian oscillations to local time; and 3) output pathways that drive overt circadian rhythms, such as the rhythms of locomotor activity and a variety of endocrine rhythms. In mammals, the circadian system is employed in the regulation of reproductive physiology and behavior in two very important ways. 1) In some species, there is a strong circadian component in the timing of ovulation and reproductive behavior, ensuring that these events will occur at a time when the animal is most likely to encounter a potential mate. 2) Many mammals exhibit seasonal reproductive rhythms that are largely under photoperiod regulation; in these species, the circadian system and the pineal gland are crucial components of the mechanism that is used to measure day length. The rhythm of pineal melatonin secretion is driven by a neural pathway that includes the circadian oscillator(s) in the suprachiasmatic nuclei. Melatonin is secreted at night in all mammals, and the duration of each nocturnal episode of melatonin secretion is inversely related to day length. The pineal melatonin rhythm appears to serve as an internal signal that represents day length and that is capable of regulating a variety of seasonal variations in physiology and behavior.     

Climate change and seasonal reproduction in mammals

Seasonal reproduction is common among mammals at all latitudes, even in the deep tropics. This paper (i) discusses the neuroendocrine pathways via which foraging conditions and predictive cues such as photoperiod enforce seasonality, (ii) considers the kinds of seasonal challenges mammals actually face in natural habitats, and (iii) uses the information thus generated to suggest how seasonal reproduction might be influenced by global climate change. Food availability and ambient temperature determine energy balance, and variation in energy balance is the ultimate cause of seasonal breeding in all mammals and the proximate cause in many. Photoperiodic cueing is common among long-lived mammals from the highest latitudes down to the mid-tropics. It is much less common in shorter lived mammals at all latitudes. An unknown predictive cue triggers reproduction in some desert and dry grassland species when it rains. The available information suggests that as our climate changes the small rodents of the world may adapt rather easily but the longer lived mammals whose reproduction is regulated by photoperiod may not do so well. A major gap in our knowledge concerns the tropics; that is where most species live and where we have the least understanding of how reproduction is regulated by environmental factors.     

Production,reproduction and size in mammals

It is argued that birth rate, turnover rate and production/biomass ratios (P/B) are equivalent in stable populations. It is then shown from field data on 21 mammal species that production scales as a 2/3 power of body mass, suggesting that size rather than life history characteristics explain most interspecific variation. The relationship simolifies calculations of annual production in populations and energy flow through communities.     

Seasonal breeding in female mammals

Study of the causation of seasonal breeding can be subdivided into a consideration of external or ecological, and internal or physiological, factors. Of the ecological ones, the role of day–length has been most extensively studied. Subjecting appropriate animals to different photoperiods should give fresh insight into mechanisms of the central nervous system. Alterations in day–length may produce changes in the C.N.S. and pituitary quite quickly, say within 24 to 48 hours. But there is still uncertainty about such basic problems as the relative significance of abrupt and gradual changes in day–length for the alteration of gonadal activity; and the existence of an annual endogenous physiological rhythm which may provoke the gonads into activity at the appropriate time. In addition, for some small rodents physical environmental factors apparently are not always equally efficient in stopping breeding in the winter, and it may be that length of breeding season is also influenced by biotic factors, such as the phase of a population cycle. Susceptibility to the effects of short photoperiods ("winter") may be to some extent genetically controlled. Possibly then genotypes allowing winter breeding may be favoured at some, but not other, phases of population cycles.     

The physiological costs of reproduction in small mammals

Life-history trade-offs between components of fitness arise because reproduction entails both gains and costs. Costs of reproduction can be divided into ecological and physiological costs. The latter have been rarely studied yet are probably a dominant component of the effect. A deeper understanding of life-history evolution will only come about once these physiological costs are better understood. Physiological costs may be direct or indirect. Direct costs include the energy and nutrient demands of the reproductive event, and the morphological changes that are necessary to facilitate achieving these demands. Indirect costs may be optional 'compensatory costs' whereby the animal chooses to reduce investment in some other aspect of its physiology to maximize the input of resource to reproduction. Such costs may be distinguished from consequential costs that are an inescapable consequence of the reproductive event. In small mammals, the direct costs of reproduction involve increased energy, protein and calcium demands during pregnancy, but most particularly during lactation. Organ remodelling is necessary to achieve the high demands of lactation and involves growth of the alimentary tract and associated organs such as the liver and pancreas. Compensatory indirect costs include reductions in thermogenesis, immune function and physical activity. Obligatory consequential costs include hyperthermia, bone loss, disruption of sleep patterns and oxidative stress. This is unlikely to be a complete list. Our knowledge of these physiological costs is currently at best described as rudimentary. For some, we do not even know whether they are compensatory or obligatory. For almost all of them, we have no idea of exact mechanisms or how these costs translate into fitness trade-offs.     

Applications of microsurgery to reproduction in domestic and exotic mammals

Microsurgery and embryo transfer of mammalian embryos have many possible uses for propagation of domestic and endangered species. Techniques and applications of embryo splitting, chimeric cloning, and production of fetal-placental chimeras are discussed, with an emphasis on interspecies transfers.     

Aspects of central and peripheral regulation of reproduction in mammals

To increase our knowledge concerning the central and peripheral regulation of reproduction in mammals a series of studies were performed. In the first experiment, we found that exogenous leptin altered the activity of the hypothalmo-pituitary-gonadotropic axis in sheep during insufficient feeding. The action of leptin appears to be mediated by changes in GnRH and LH secretion as well as NPY immunoreactivity. The aim of the second experiment was to investigate the role of the adipoinsular axis hormones during pregnancy in rats. The elevated levels of plasma leptin as wells as the increased mRNAs expression of the leptin receptors in placenta indicate the significant role of the hormone in fetal growth and development. On the other hand, a decrease in leptin receptors mRNA content within hypothalamus and pituitary together with unchanged plasma insulin level may suggest that during rat pregnancy leptin resistance was developed in the hypothalamus, pituitary and pancreatic islets. The third experiment was carried out to establish the role of opioids and glucocorticoids in the regulation of the hypothalmo-pituitary-gonadal axis in ewes during natural or synchronized estrous cycle. Prolonged treatment with progesterone resulted in significant changes in plasma levels of Met-enkephalin, cortisol and steroids and altered the expression of proenkephalin mRNA in the hypothalamus, pituitary, ovary and adrenals. Injections of Met-enkephalin or naltrexone (blocker of opioid receptors) modulated the progesterone influence in tested tissues. The data clearly suggest that opioids are involved in the regulation of the estrous cycle at the hypothalamo-pituitary-gonadal/adrenal axes.     

M6P/IGF2R imprinting evolution in mammals

Imprinted gene identification in animals has been limited to eutherian mammals, suggesting a significant role for intrauterine fetal development in the evolution of imprinting. We report herein that M6P/IGF2R is not imprinted in monotremes and does not encode for a receptor that binds IGF2. In contrast, M6P/IGF2R is imprinted in a didelphid marsupial, the opossum, but it strikingly lacks the differentially methylated CpG island in intron 2 postulated to be involved in imprint control. Thus, invasive placentation and gestational fetal growth are not required for imprinted genes to evolve. Unless there was convergent evolution of M6P/ IGF2R imprinting and receptor IGF2 binding in marsupials and eutherians, our results also demonstrate that these two functions evolved in a mammalian clade exclusive of monotremes.