小球藻LEA 家族蛋白Ccor1和Ccor2在抗盐胁迫中的作用

LEA蛋白是与植物抗逆反应相关的一类重要蛋白质,可以在发育的植物胚胎、处于干旱、寒冷、盐胁迫的植物组织中高水平表达。LEA蛋白最早发现于棉花子叶中,随后也在其他高等植物、藻类、真菌、蓝藻以及线虫中被发现。LEA蛋白代表一个庞大的基因家族,早期是根据     

植物胚胎发育晚期丰富蛋白1组的结构与功能

植物胚胎发育晚期丰富蛋白（late embryogenesis abundant proteins,LEA）是植物胚胎发生后期种子中大量积累的一类蛋白质。根据蛋白质的氨基酸基序和保守结构特点,LEA蛋白一般分为6组,其中第1组LEA蛋白（LEA1）含有高度保守的20氨基酸基序。LEA1蛋白在水溶液中主要呈无规则结构,具高亲水性和热稳定性,与植物抗逆功能密切相关。本文就LEA1蛋白的功能和结构等方面的研究做一综述。     

第三组胚胎晚期丰富蛋白lea3基因研究概述

晚期胚胎富集蛋白(late embryogenesis abundant protein,LEA蛋白)是在高等植物胚胎发育晚期大量积累的一类蛋白,根据其结构特点LEA蛋白一般分为6组,其中第3组LEA蛋白(LEA3)含有11个氨基酸串联重复的基元序列,可以形成α-螺旋结构,能在干旱胁迫的环境中保护生物大分子,减轻水份胁迫对植物造成的伤害,与植物抗逆性密切相关。该文就lea3基因及其蛋白的结构、功能、基因表达和应用等进行简要的综述,并对lea3基因及其蛋白今后的研究方向和应用前景进行了展望。     

胚胎发育晚期丰富蛋白(LEA蛋白)与植物抗逆性研究进展

胚胎发育晚期丰富蛋白(LEA蛋白)在自然条件下主要在种子发育晚期大量积累,植物LEA基因也在多种非生物胁迫下诱导表达。植物LEA蛋白是植物应对失水胁迫(包括干旱、盐碱、冷冻等)逆境的一种广泛存在的亲水性应答蛋白,具有很强的热稳定性。本论文就LEA蛋白的结构、分类、功能及抗逆性分子机制进行了概述与总结,为分离新的LEA蛋白成员,进行功能分析以及进一步发掘其潜在应用价值提供参考。     

LEA蛋白研究进展

LEA蛋白(late embriogenesis abundant protein,LEA)是生物体中广泛存在的一类与渗透调节有关的家族蛋白,该蛋白的编码基因在植物种子胚胎发育晚期表达量丰富,而且在环境胁迫如干旱、低温、盐胁迫、ABA、紫外辐射和NaHCO3等条件下LEA基因的mRNA也会大量累积.LEA蛋白显著的理化特性是具有很高的亲水性和热稳定性,即使在煮沸条件下也能保持水溶状态.LEA蛋白在细胞中可以稳定细胞膜结构,作为分子伴侣,具有结合离子和防止氧化等作用,被认为是在胁迫过程中对植物起保护作用的物质之一.针对这些重要特性,分别综述了LEA蛋白的分类、结构、编码基因和表达调节方式及其在植物生长过程中的作用.     

胚胎晚期富集蛋白与生物的干旱胁迫耐受性

胚胎晚期富集蛋白(Late embryogenesis abundant,LEA)是参与生物体抵抗干旱胁迫的一类重要蛋白。LEA蛋白可分为7组。大多数LEA蛋白具有亲水性及热稳定性。LEA蛋白在水溶液中通常为无折叠状态,但脱水胁迫可诱导其转变为α-螺旋。近年来关于LEA蛋白的研究取得了较多进展。研究结果表明LEA蛋白可定位于细胞内的多种细胞器中,且LEA蛋白可能具有多重保护作用,如保护蛋白质及酶活性、或保护细胞的膜结构、或具有抗氧化作用、结合离子或保护DNA等。以下主要介绍了LEA蛋白的功能、二级结构及保护作用机制。     

大麦HVA1基因和LEA蛋白与植物抗旱性的研究

干旱胁迫下,植物体内会积累多种蛋白以保护细胞免受脱水伤害,其中包括Lea蛋白。LEA蛋白在植物耐寒、耐盐碱、耐干旱性方面起重要作用。大麦HVA1基因编码的蛋白即属于第三组LEA蛋白,国内外学者对该基因的结构与功能进行了深入的研究。根据近年研究结果,本文对LEA蛋白的结构与功能,大麦HVA1基因的表达与调控,大麦HVA1基因高同源性序列的克隆以及转基因植物对HVA1基因抗旱性功能验证等方面进行综述。     

LEA蛋白的分类与功能研究进展

胚胎发育晚期丰富蛋白(late embryogenesis abundant proteins,LEA蛋白)具有广泛的生物学功能,低温、干旱、盐渍及ABA等均可以诱导LEA蛋白的表达,LEA蛋白的显著特点是具有较高的亲水性与热稳定性.根据LEA蛋白结构特征可将其分为不同的家族,研究发现LEA蛋白具有清除活性氧自由基、稳定膜结构和保护酶活性等功能.介绍LEA蛋白的分类依据、功能和基因表达调控等方面研究的进展.     

柠条锦鸡儿CkLEA4基因克隆及表达分析

LEA蛋白是一种与植物抗逆相关的胚胎发育晚期丰富蛋白。该研究从已构建的柠条锦鸡儿干旱胁迫抑制削减杂交文库中筛选到1条LEA蛋白编码基因的部分序列,用RACE技术扩增得到该基因cDNA全长并对其进行了克隆。测序表明该基因cDNA长870bp,其中开放阅读框长510bp,编码169个氨基酸,推测蛋白分子量为17.03kD,等电点为9.3,是一种亲水蛋白。序列比对和系统进化分析表明,该基因属于LEA4基因家族成员,命名为CkLEA4。实时荧光定量PCR检测发现,CkLEA4基因在干旱、ABA和NaCl处理下均受到不同程度的诱导,说明CkLEA4基因可能与柠条锦鸡儿响应逆境胁迫有关。     

小麦TaLEA1基因的表达特征及抗逆功能验证

我国土壤盐碱化日益严重,对我国的粮食安全造成了严重威胁,因此耐盐基因挖掘对作物耐盐育种非常重要。许多研究表明胚胎发育晚期丰富蛋白(LEA)在植物应对非生物胁迫中发挥积极作用。本研究以小麦TaLEA1基因为研究对象,分析了其表达蛋白的理化性质及基因表达模式,并通过在拟南芥中过表达,分析Ta LEA1基因的抗逆功能。结果表明,TaLEA1基因的表达蛋白属于第3组LEA蛋白,是稳定的亲水蛋白,富含α-螺旋、β-转角等结构。Ta LEA1基因在小麦根、茎、叶、花、种子等不同组织中均有表达,盐胁迫条件诱导其高表达。在拟南芥中过表达TaLEA1基因,显著提高了盐胁迫下转基因拟南芥的种子萌发率、根长及盐和旱胁迫下的叶绿素含量。本研究结果为LEA基因抗逆机理的研究和耐盐基因的挖掘提供了重要信息。     

Role for dopamine in malonate-induced damage in vivo in striatum and in vitro in mesencephalic cultures

Defects in mitochondrial energy metabolism have been implicated in the pathology of several neurodegenerative disorders. In addition, the reactive metabolites generated from the metabolism and oxidation of the neurotransmitter dopamine (DA) are thought to contribute to the damage to neurons of the basal ganglia. We have previously demonstrated that infusions of the metabolic inhibitor malonate into the striata of mice or rats produce degeneration of DA nerve terminals. In the present studies, we demonstrate that an intrastriatal infusion of malonate induces a substantial increase in DA efflux in awake, behaving mice as measured by in vivo microdialysis. Furthermore, pretreatment of mice with tetrabenazine (TBZ) or the TBZ analogue Ro 4-1284 (Ro-4), compounds that reversibly inhibit the vesicular storage of DA, attenuates the malonate-induced DA efflux as well as the damage to DA nerve terminals. Consistent with these findings, the damage to both DA and GABA neurons in mesencephalic cultures by malonate exposure was attenuated by pretreatment with TBZ or Ro-4. Treatment with these compounds did not affect the formation of free radicals or the inhibition of oxidative phosphorylation resulting from malonate exposure alone. Our data suggest that DA plays an important role in the neurotoxicity produced by malonate. These findings provide direct evidence that inhibition of succinate dehydrogenase causes an increase in extracellular DA levels and indicate that bioenergetic defects may contribute to the pathogenesis of chronic neurodegenerative diseases through a mechanism involving DA.     

Scurvy in capybaras bred in captivity in Argentine

In order to determine if the absence of vitamin C in the diet of capybaras (Hydrochoerus hydrochaeris) causes scurvy, a group of seven young individuals were fed food pellets without ascorbic acid, while another group of eight individuals received the same food with 1 g of ascorbic acid per animal per day. Animals in the first group developed signs of scurvy-like gingivitis, breaking of the incisors and death of one animal. Clinical signs appeared between 25 and 104 days from the beginning of the trial in all individuals. Growth rates of individuals deprived of vitamin C was considerably less than those observed in the control group. Deficiency of ascorbic acid had a severe effect on reproduction of another population of captive capybaras. We found that the decrease in ascorbic acid content in the diet affected pregnancy, especially during the first stages. The results obtained suggest that it is necessary to supply a suitable quantity of vitamin C in the diet of this species in captivity.     

Changes in lactate dehydrogenase activity in chicken tissues in hyperthyreosis in ontogenesis

The lactate dehydrogenase activity in reactions of lactate oxidation and synthesis was studied in subfractions of the chicken brain, heart and liver at the embryonal, early postembryonal and adult stages of development after thyroxine administration. It has been shown that during embryogenesis thyroxine predominantly enhanced the rate of lactate oxidation in the mitochondrial tissues. A marked increase in the lactate synthesis was found in cytoplasm of the adult chicken tissues. Specificity of enzyme activity alterations was detected in the chicken brain during ontogenesis after thyroxine administration.     

SSTR5 ablation in islet results in alterations in glucose homeostasis in mice

Somatostatin (SST) peptide is a potent inhibitor of insulin secretion and its effect is mediated via somatostatin receptor 5 (SSTR5) in the endocrine pancreas. To investigate the consequences of gene ablation of SSTR5 in the mouse pancreas, we have generated a mouse model in which the SSTR5 gene was specifically knocked down in the pancreatic beta cells (betaSSTR5Kd) using the Cre-lox system. Immunohistochemistry analysis showed that SSTR5 gene expression was absent in beta cells at three months of age. At the time of gene ablation, betaSSTR5Kd mice demonstrated glucose intolerance with lack of insulin response and significantly reduced serum insulin levels. Insulin tolerance test demonstrated a significant increase of insulin clearance in vivo at the same age. In vitro studies demonstrated an absence of response to SST-28 stimulation in the betaSSTR5Kd mouse islet, which was associated with a significantly reduced SST expression level in betaSSTR5Kd mice pancreata. In addition, betaSSTR5Kd mice had significantly reduced serum glucose levels and increased serum insulin levels at 12 months of age. Glucose tolerance test at an older age also indicated a persistently higher insulin level in betaSSTR5Kd mice. Further studies of betaSSTR5Kd mice had revealed elevated serum C-peptide levels at both 3 and 12 months of age, suggesting that these mice are capable of producing and releasing insulin to the periphery. These results support the hypothesis that SSTR5 plays a pivotal role in the regulation of insulin secretion in the mouse pancreas.