瘦素在禽类中的研究进展

瘦素(leptin)是一种主要作用于下丘脑的重要激素,起到调控摄食和能量消耗的作用。另外,国内外越来越多的研究表明,leptin与动物的代谢、发育、繁殖和免疫调节等均有密切的联系。但是上述研究大多在哺乳动物中进行,在禽类中的研究还在起步阶段。现有的研究表明,禽类的leptin及leptin受体的作用与哺乳动物相比都有其特殊性。本文首先分析了禽类leptin及leptin受体的特点,在此基础上,从摄食、生长发育和繁殖三个方面综述了leptin对禽类的作用及可能机制。     

草鱼与鲢鱼肥胖基因克隆与序列分析

肥胖基因产物leptin是调节哺乳动物摄食、能量代谢等生命活动的重要细胞因子。 应用RT-PCR和RACE法获得了草鱼(Ctenopharyngodon idellus)和鲢鱼(Hypophthalmichthys molitrix) leptin基因的全长cDNA序列分别为1 096 bp和1 176 bp,编码173和172个氨基酸。氨基酸序列同源性分析表明,草鱼和鲢鱼的leptin序列与其它鲤科鱼类leptin的同源性较高,而与其他鱼类的leptin同源性很低,但所有鱼类的leptin均含有用于形成二硫键的高度保守的半胱氨酸。系统进化树分析显示,草鱼和鲢鱼leptin与其他鱼类leptin聚于一进化分支。应用PCR和Genome Walker方法,进一步获得了草鱼和鲢鱼leptin基因的内含子和5′侧翼区序列。结果表明,获得的草鱼和鲢鱼leptin基因长度分别为2 129 bp和2 192 bp,含有与其他脊椎动物leptin相似的基因结构（含三个外显子和两个内含子）。本研究为深入研究鱼类肥胖基因结构功能关系与鱼类抗肥胖品系定向遗传选育奠定了良好的基础。     

瘦蛋白对摄食和能量平衡的调节及其在哺乳动物冬眠中的作用

白色脂肪合成和分泌的瘦蛋白(leptin)作用于下丘脑和外周的代谢产热器官,对摄食和能量平衡起调节作用。摄食和能量平衡的失调,如瘦蛋白抵抗,可以导致肥胖等一系列生理疾病。以体内贮存的脂肪为主要能源物质越冬的冬眠哺乳动物,体重的年周期波动幅度巨大,其摄食和能量平衡调节机制可能不同于一般的非冬眠物种,育肥阶段可能存在瘦蛋白抵抗机制。本文总结了瘦蛋白调节摄食和能量平衡的作用机制以及瘦蛋白对冬眠哺乳动物育肥和冬眠的影响,为进一步研究冬眠哺乳动物的能量平衡提供参考。     

Apelin/APJ调节鱼类摄食的研究进展

Apelin是1998年首次从牛胃分泌物中提取出的APJ的内源性配体,Apelin及其受体APJ广泛分布于动物中枢和外周组织中。Apelin通过与受体APJ结合,不仅参与血压调节、痛觉调节、体液平衡和细胞凋亡等多种生理过程,还在动物摄食调控和胃肠道运动调节中发挥重要作用。目前,关于Apelin调控摄食的作用还存在争议。现依据Apelin和APJ在哺乳动物和鱼类的研究进展,阐述Apelin及APJ的结构、组织分布和对动物摄食的调控及其机制,以期为其在鱼类摄食调控方面的研究提供参考。     

Myostatin三维结构模建及分子进化分析

Myostatin(MST)为肌肉生长负调节因子,其功能受抑制可导致肌肉量增加.对MST核酸序列进行序列比对,构建进化树;采用同源模建方法首次模建MST成熟肽生物活性二聚体的四级结构,并预测MST与其受体ActRIIB的相互作用模式.进化树将肌肉生长抑制素基因(MSTN)分成4个亚家族:哺乳动物MSTN,鸟类MSTN以及鱼类MSTN 1和2.MST受纯化选择作用,在不同物种的直系同源基因具有较高的刚源性,其中哺乳动物、鸟类MST C端活性肽氨基酸序列高度保守.表明哺乳动物、鸟类MST的结构、功能类似,且信号传导路径可能一致;而鱼类MST的调控机制可能存在较大差异.MST结构及其表面静电势和疏水氨基酸分布表明静电力和疏水相互作用在MST与其受体结合过程中可能起到十分重要的作用.     

酿酒酵母孢子壁结构及其合成相关基因研究进展

细胞壁是酵母细胞区别于哺乳动物细胞的重要特征结构。酵母细胞壁的结构组成、合成、再生等与酵母自身繁殖及环境胁迫压力密切相关。目前,酵母孢子壁的形成机理、调控过程机制及孢子壁合成相关基因的功能尚未研究清楚。本文以酿酒酵母为例,简要描述酵母孢子壁的形成过程,重点阐述孢子壁甘露糖层、葡聚糖层、壳聚糖层和二酪氨酸层的结构组成及其合成相关基因的国内外研究进展,以期为抗真菌药物的新靶点研究提供参考。     

HIF-NOS信号通路对哺乳动物卵巢NO依赖性功能的调控作用

一氧化氮(NO)作为气体明星分子和信号分子,在哺乳动物体内不同的生理调节过程中具有非常重要的作用,尤其是哺乳动物卵巢功能的调控.一氧化氮合酶(NOS)是NO合成的限速酶,是调节NO合成的关键环节,也是NO依赖性功能调控的重要环节.因此,调节NOS转录/合成的信号通路对哺乳动物卵巢NO依赖性功能具有至关重要的调控作用.最近的研究发现,缺氧诱导因子(HIF)作为转录因子,参与许多与缺氧相关靶基因的转录调控,如NOS和血管内皮生长因子(VEGF)等.本文一方面描述了NO合成及其调控的分子机制,另一方面阐明了HIF作为转录因子对NOS的转录调控,从而揭示HIF在NO依赖性卵巢功能调控中的重要作用,同时为进一步研究哺乳动物卵巢功能的调控提供新的研究方向和理论基础.     

哺乳动物不育系20样激酶MST1

哺乳动物不育系20样激酶1(mammalian sterile 20-like kinase 1,Mst1)基因是果蝇Hippo基因在哺乳动物中的同源基因,编码丝氨酸/苏氨酸激酶,主要参与细胞生长、增殖、凋亡以及器官大小等的调控。最近的研究表明,Mst1基因具有抑癌作用,其功能的缺失与肿瘤的发生密切相关。本文就MST1的结构与功能、促凋亡作用机制及其在医学研究中的应用作一简要综述。     

哺乳动物季节性繁殖的内源年生物钟及光敏神经环路研究进展

生活在温带和寒带的哺乳动物在长期的进化过程中形成了季节性繁殖的生活史特征。哺乳动物的繁殖功能主要受到下丘脑-垂体-性腺轴(hypothalamic-pituitary-gonadal axis,HPGA)的调控。视交叉上核(suprachiasmatic nucleus,SCN)能够自发振荡并响应光周期信号的变化,引发褪黑素分泌的改变,并介导下游通路中下丘脑甲状腺激素、Kisspeptin和RF酰胺相关肽(RF amide-related peptide,RFRP)的节律性表达变化,从而调控哺乳动物的季节性繁殖。本文综述了哺乳动物季节性繁殖的内源年生物钟调控,并强调了光敏通路中包括甲状腺激素、Kisspeptin和RFRP在季节性繁殖调控中的重要作用。     

瘦素在哺乳动物体重调节、繁殖和免疫中的作用

瘦素(Leptin) 主要是由白色脂肪细胞分泌的、肥胖基因编码的、分子量为16 KD 的蛋白类激素。其N 端具有信号肽序列, 引导蛋白质进入分泌途径, 信号肽被切除后成为有生物学功能的成熟蛋白质。瘦素在动物的体重调节、发育与生殖、免疫和糖代谢等方面有重要作用。瘦素已经不仅仅是脂肪细胞分泌的蛋白类激素, 而是一个在许多方面发挥作用的神经内分泌调节因子。本文综述了瘦素在哺乳动物体重调节、繁殖和免疫中的作用及其调控机制, 主要包括: 动物血清瘦素浓度的季节性变化; 光周期、温度和食物等环境因子对瘦素浓度的影响; 瘦素与解偶联蛋白(Uncoupling proteins , UCPs) 在能量代谢和产热中的互作; 瘦素与下丘脑神经肽Y (Hypothalamus neuropeptide Y, NPY) 在体重调节和产热作用中的拮抗; 瘦素与甲状腺激素和胰岛素在能量代谢中的互作以及瘦素在生殖和免疫中的作用。     

Duplicated Leptin Receptors in Two Species of Eel Bring New Insights into the Evolution of the Leptin System in Vertebrates

Since its discovery in mammals as a key-hormone in reproduction and metabolism, leptin has been identified in an increasing number of tetrapods and teleosts. Tetrapods possess only one leptin gene, while most teleosts possess two leptin genes, as a result of the teleost third whole genome duplication event (3R). Leptin acts through a specific receptor (LEPR). In the European and Japanese eels, we identified two leptin genes, and for the first time in vertebrates, two LEPR genes. Synteny analyses indicated that eel LEPRa and LEPRb result from teleost 3R. LEPRb seems to have been lost in the teleost lineage shortly after the elopomorph divergence. Quantitative PCRs revealed a wide distribution of leptins and LEPRs in the European eel, including tissues involved in metabolism and reproduction. Noticeably, leptin1 was expressed in fat tissue, while leptin2 in the liver, reflecting subfunctionalization. Four-month fasting had no impact on the expression of leptins and LEPRs in control European eels. This might be related to the remarkable adaptation of silver eel metabolism to long-term fasting throughout the reproductive oceanic migration. In contrast, sexual maturation induced differential increases in the expression of leptins and LEPRs in the BPG-liver axis. Leptin2 was strikingly upregulated in the liver, the central organ of the reproductive metabolic challenge in teleosts. LEPRs were differentially regulated during sexual maturation, which may have contributed to the conservation of the duplicated LEPRs in this species. This suggests an ancient and positive role of the leptin system in the vertebrate reproductive function. This study brings new insights on the evolutionary history of the leptin system in vertebrates. Among extant vertebrates, the eel represents a unique case of duplicated leptins and leptin receptors as a result of 3R.     

Leptin: a possible link between food intake, energy expenditure, and reproductive function

Several regulatory substances participate in the regulation of both food intake/energy metabolism and reproduction in mammals. Most of these neuropeptides originate and act in the central nervous system, mainly at specific hypothalamic areas. Leptin represents a signal integrating all these functions, but originating from the periphery (adipose tissue) and carrying information mainly to central structures. Observations in rodent models of leptin deficiency have suggested that leptin participates in the control of reproduction, in conjunction with that of food intake and energy expenditure. Indeed, leptin administration resulted in the restoration of normal body weight, food intake, and fertility in the ob mouse, lacking circulating leptin. Specific targets of leptin in the hypothalamus are neurons expressing neuropeptide Y, proopiomelanocortin and gonadotropin-releasing hormone, but the presence of leptin receptors in peripheral reproductive structures suggests that leptin might also act at these sites. Human obesity is often associated with reproductive disturbances. The situation in humans is more complex than in the animal models of leptin deficit and the presence of leptin resistance in these subjects is suggested. In conclusion, leptin fits many requirements for a molecule linking the regulation of energy balance and the control of reproduction.     

Leptin and leptin receptor: Analysis of a structure to function relationship in interaction and evolution from humans to fish

Leptin is a circulating protein which regulates dietary intake through binding the leptin receptor. Numerous labs have used known structures and mutagenesis to study this binding process in common animal models (human, mouse and rat). Understanding this binding process in other vertebrate species will allow for a better understanding of leptin and leptin receptor function. The binding site between leptin and leptin receptor is highly conserved in mammals as confirmed through sequence alignments mapped onto structures of both leptin and leptin receptor. More variation in this interaction is found in lizard and frog sequences. Using our models, we show that the avian leptin sequences have far less variation in the binding site than does the leptin receptor. This analysis further suggests that avian leptins are artifactual. In fish, gene duplication events have led to the expression of multiple leptin proteins. These multiple leptin proteins have variation in the regions interacting with leptin receptor. In zebrafish and the Japanese rice fish, we propose that leptin A has a higher binding energy than does B. Differing binding energies are evidence of either divergent functions, different binding confirmations, or other protein partners of leptin B.     

Leptin

Leptin is an adipocyte hormone that signals nutritional status to the central nervous system (CNS) and peripheral organs. Leptin is also synthetized in the placenta and in gastrointestinal tract, although its role in these tissues is not yet clear. Circulating concentrations of leptin exhibit pulsatility and circadian rhythmicity. The levels of plasma leptin vary directly with body mass index and percentage body fat, and leptin contributes to the regulation of body weight. Leptin plasma concentrations are also influenced by metabolic hormones, sex, and body energy requirements. Defects in the leptin signaling pathway result in obesity in animal models. Only a few obese humans have been identified with mutations in the leptin gene or in the leptin receptor; however, most cases of obesity in humans are associated with high leptin levels. Thus, in humans obesity may represent a state of leptin resistance. Minute-to-minute fluctuations in peripheral leptin concentrations influence the activity of the hypothalamic-pituitary-ovarian and hypothalamic-pituitary-adrenal axes, indicating that leptin may be a modulator of reproduction, stress-related endocrine function, and behavior. This suggests potential roles for leptin or its antagonists in the diagnosis, pathophysiology and treatment of several human diseases.     

Leptin presence in plasma, liver and fat bodies in the lizard Podarcis sicula: fluctuations throughout the reproductive cycle.

Leptin is a 16 kDa peptide produced by adipocytes in response to increasing fat stores and signals to the brain to stop eating and increase energy expenditure. Recent studies point out that the role of leptin is much broader and includes the regulation of reproduction. The lizard, Podarcis sicula, is an oviparous species characterized, at this latitude, by a seasonal reproductive cycle. Since in Podarcis sicula the recovery of the gonadal function coincides with the recovery of metabolic activity, we have hypothesized that leptin might be involved in the regulation of the reproductive function in this species. We have identified an immunoreactive band in the plasma of the female of Podarcis sicula, which comigrated with recombinant mouse leptin and cross reacted with polyclonal antibodies against mouse leptin. A RIA method developed by Linco (St. Louis, MO) was utilized to measure leptin concentration in plasma, liver and fat bodies of Podarcis sicula throughout the reproductive cycle. The antibody used in this kit (Linco's Multi-Species Leptin Radioimmunoassay kit) was produced in the guinea pig against human leptin but displays crossreactivity to leptin molecules of many species. The level of leptin in the plasma of Podarcis sicula was in the same range as that of mammals. Leptin levels in plasma, liver and fat bodies fluctuated during the reproductive cycle, in a way consistent with its possible role in reproduction.     

The stanniocalcin family of proteins

Stannniocalcin (STC) is a polypeptide hormone that was originally identified in bony fishes as a systemic regulator of mineral metabolism, and is best known for its regulatory effects on calcium/phosphate transport by the gills, gut and kidneys. The mammalian homolog to fish STC was discovered in 1995 and has resulted in progressively growing interest ever since as to its possible role in humans. Moreover, new discoveries in the mammalian STC field are resulting in significant reappraisals as to its role in fishes. Perhaps the most significant of these has been the discovery of a second gene encoding stanniocalcin-related protein, or STC-2, first in mammals and subsequently in fish. This review covers the comparative endocrinology of the STCs in fishes and mammals from the perspectives of structure, function and regulation. It then delves into some of the newer aspects of STC-1/STC-2 biology that have been uncovered using both classical and transgenic approaches. Of these, one of the most intriguing discoveries relates to the receptor-mediated sequestration of STC by target cell organelles. The functions of other newly discovered mammalian and fish STC variants are also discussed, as is the recent discovery of STC-related homologs in invertebrates. Based on our current state of knowledge, it is apparent that STC has an ancient lineage and that the STC family of proteins is proving to have significant roles in metabolism, reproduction and development.     

Production of recombinant leptin and its effects on food intake in rainbow trout (Oncorhynchus mykiss)

Leptin is a key factor for the regulation of food intake and energy homeostasis in mammals, but information regarding its role in teleosts is still limited. There are large differences between mammalian and teleost leptin at both gene and protein levels, and in order to characterize the function of leptin in fish, preparation of species-specific leptin is therefore a key step. In this study, full-length cDNA coding for rainbow trout leptin was identified. In spite of low amino acid sequence similarity with other animals, leptin is highly conserved between trout and salmon (98.7%). Based on the cDNA, we produced pure recombinant trout leptin (rt-leptin) in E. coli, with a final yield of 20 mg/L culture medium. We then examined the effects of intraperitoneal (IP) injection of rt-leptin on feeding behavior and gene expression of hypothalamic NPY and POMCs (POMC A1, A2 and B) in a short-term (8 h) experiment. The rt-leptin suppressed food intake and led to transient reduction of NPY mRNA levels, while the expression of POMCs A1 and A2, was elevated compared with vehicle-injected controls. These results for rainbow trout are the first that describe a physiological role of leptin using a species-specific orthologue in teleosts, and they suggest that leptin suppresses food intake mediated by hypothalamic regulation. This anorexic effect is similar to that observed in mammals and frogs and supports that the neuroendocrine pathways that control feeding by leptin are ancient and have been conserved through evolution.