蜜蜂卵黄原蛋白的作用

卵黄蛋白不仅为胚胎发生提供营养物质,它在生物体内还具有其他的生物学功能。昆虫卵黄蛋白是昆虫卵内的营养储备,它的前体主要来源于脂肪体的雌性特异血蛋白——卵黄原蛋白(Vg),它是近年来昆虫生理学和生化学最活跃的领域之一,文章介绍蜜蜂卵黄原蛋白在蜜蜂生殖过程中的作用,以及与蜜蜂社会性生活及寿命的关系。     

昆虫卵黄原蛋白受体的研究进展

昆虫卵黄发生的一个重要过程是卵黄蛋白的摄取,已有的研究表明脂肪体合成的卵黄原蛋白(vitellogenin,Vg)是通过受体介导的内吞作用(receptor mediated endocytosis,RME)被正在发育的卵母细胞所摄取。昆虫卵黄原蛋白受体(vitellogenin receptor,VgR)是介导昆虫卵黄原蛋白胞吞作用主要受体,它属于低密度脂蛋白家族,在结构与特性上具低密度脂蛋白家族的共性。卵黄原蛋白及其受体在昆虫生殖过程中起着重要的作用,本文综述了昆虫VgR的基本特性、分子结构及表达调控等方面的研究进展。     

昆虫卵黄原蛋白受体( VgＲs) 及其主要功能综述

卵黄原蛋白受体(VgRs)属于低密度脂蛋白受体家族成员,具有该家族典型的保守结构域,包括配体结合域,表皮生长因子前体同源域,跨膜域,O-联糖功能域,以及胞质尾域。昆虫VgRs通常具有卵巢特异性,是卵黄原蛋白Vg的专一性胞吞作用受体,可介导Vg进入昆虫卵母细胞,而后沉淀积累形成昆虫生殖必须的卵黄蛋白YP。VgRs介导的胞吞作用是一个动态循环过程,它是卵黄发生的基础,对昆虫卵母细胞发育起着至关重要的作用。近年来的研究表明,VgRs不仅与卵巢激活、卵黄发生与卵子形成密切相关,而且在昆虫信息交流、社会分化、行为构建以及免疫调控等中也起到了至关重要的作用,已成为潜在的害虫控制新靶标。本文首次对昆虫VgRs基因的序列信息,分子结构,系统进化,表达模式以及调控功能等方面进行了综述,旨在为了解VgRs基因的研究进展及前景提供参考,对进一步改进害虫生态控制的策略和措施也具有指导意义。     

蚊虫的卵黄发生及其激素调节

<正> 昆虫卵黄发生的研究是昆虫生理学中最活跃的领域之一,昆虫卵黄发生是指卵黄蛋白的前体-卵黄原蛋白在成熟雌虫的脂肪体合成,分泌到血淋巴中,被发育的卵母细胞选择性摄取沉积为卵黄蛋白,作为胚胎发育的营养来源,这一过程受昆虫激素调节控制(龚和,1979)。研究蚊虫的卵黄发生对于阐明蚊虫的生殖机理和控制繁殖具有重要的实践意义,同时蚊虫卵黄     

蜱类卵黄发生研究进展

蜱是一类特殊的节肢动物,有关其生殖生理的研究远远落后于昆虫。卵黄发生直接影响蜱类的繁殖力,一直是蜱类生理学一个十分活跃的研究领域。目前,对蜱类卵黄发生的研究主要包括卵黄蛋白的纯化与鉴定,卵黄原蛋白的合成与调控,卵母细胞对卵黄原蛋白的摄取以及转变为卵黄蛋白的分子过程。蜱类卵黄发生受激素调控,激素的作用与作用激素的种类在硬蜱和软蜱中表现出较大差别。对蜱类卵黄发生了解得尚少,在许多方面需深入研究。     

吸血昆虫生殖调控的分子机制

吸血昆虫是可以传播病原微生物的一类节肢动物,包括蚊虫、白蛉、蠓、猎蝽、跳蚤等。由于其特殊的吸血习性,它们成为了疟疾、登革热、丝虫病、锥虫病等急性传染性疾病的媒介载体。虫媒疾病具有传播速度快、扩散面积广和危害重等特点,不仅严重危害人类健康,还容易造成巨大的经济损失。由于针对虫媒传染病的药物匮乏以及虫媒病原对化学药物抗性的不断增加,阻断吸血昆虫的生殖成为控制虫媒疾病传播的有效措施。保幼激素(juvenile hormone, JH)和20-羟基蜕皮激素(20-hydroxyecdysone, 20E)在昆虫生殖过程中扮演着重要的角色。JH与胞内受体复合物Met/Tai结合后调控JH/Met靶基因表达,进而促进卵黄发生过程,为昆虫之后的吸血及产卵提供了必要条件;20E胞内受体为EcR/USP组成的异源二聚体,两者结合后激活下游基因表达,诱导卵黄原蛋白(vitellogenin, Vg)合成,为发育的卵巢提供营养。营养信号通路(胰岛素信号通路以及氨基酸介导的雷帕霉素靶蛋白信号通路)同样可以激活Vg合成,促进昆虫生殖;此外,营养信号通路与JH和20E之间可以相互作用共同调控吸血昆虫发育和繁殖。碳水化合物代谢以及脂代谢等能量代谢过程是昆虫生殖过程中主要能量来源,可以满足吸血昆虫生殖发育不同阶段极高的能量需求。研究表明,JH和20E信号通路在能量代谢过程中起着重要的调控作用;微小RNA在蚊虫这一类吸血昆虫中被证明与肠道微生物稳态、血液消化以及脂代谢等生理学过程密切相关,进一步影响了蚊虫卵巢发育。近年来,随着分子生物学及测序技术的革新,吸血昆虫生殖调控机制的研究不断取得新的进展。本文主要阐述了吸血昆虫生殖调控的分子机制研究进展,以期为通过调控吸血昆虫生殖的方法以阻断病原传播提供重要线索。     

半翅目昆虫卵黄原蛋白及其合成调控的研究进展

昆虫卵黄原蛋白（Vitellogenins, Vg）是一种多功能的生殖发育关键调控蛋白，在不同昆虫体内的结构、合成调控及功能不尽相同。随着基因编辑技术的成熟，运用分子手段调控Vg的合成，可减少卵黄发生，降低昆虫的繁殖力，成为有效防治害虫的优势方法之一。因此，Vg及其合成调控的研究受到广泛关注。半翅目害虫是农林业的重点防治对象之一，除直接刺吸为害寄主外，其常传播植物病原体，对农业生产造成了严重危害。半翅目昆虫Vg除在生殖发育中的关键作用外，还与病原菌的传播、寄主免疫等密切相关，可成为分子水平防治半翅目害虫及其继发病害的优势靶标。因此，本文总结了半翅目昆虫Vg的合成方式、合成场所，指明了其结构上蛋白亚基数目的差异，概述了其与昆虫免疫反应、植物防御、病毒传播等有关的研究进展，总结了其合成的保幼激素（包括保幼激素受体Methoprene-tolerant和转录因子Krüppel homolog 1等关键调控因子等）、蜕皮激素和胰岛素信号通路等主要的内分泌激素调控通路，以及以营养信号调控为主的非激素调控通路，为探索半翅目害虫的分子防控手段提供理论依据。     

乏氧微环境、“瓦伯格”效应及上皮间质转化相关性

肿瘤细胞在氧气充足的情况下以糖酵解的方式供能,这一现象称为“瓦伯格”效应,被认为是肿瘤的第七大特征。上皮间质转化（epithelial mesenchymal transition,EMT）是一种重要的细胞过程,参与胚胎发育、伤口愈合及肿瘤的发生等过程中,被认为是恶性肿瘤的重要特征。近年研究表明,“瓦伯格”效应和上皮间质转化的发生均与肿瘤处于乏氧微环境密切相关。乏氧微环境除可直接诱导上皮间质转化发生外,还可诱导肿瘤细胞产生“瓦伯格”效应,进一步促进上皮间质转化的发生。本文就乏氧微环境、“瓦伯格”效应、以及上皮间质转化的相关性的研究进展做一综述,有助于揭示乏氧微环境、肿瘤能量代谢改变以及肿瘤迁移侵袭之间的因果关联。     

蜜蜂表皮蛋白apidermin (apd)基因家族3个新成员的特性鉴定及昆虫APD家族序列特征的分析

Apidermin (APD)蛋白家族是一个新的昆虫结构性表皮蛋白家族。本研究结合生物信息学和RT-PCR扩增, 对意大利蜜蜂Apis mellifera ligustica（简称“意蜂”）的apd-1-like, apd-3-like和中华蜜蜂Apis cerena cerena（简称“中蜂”）的apd-2 等3个新的apd基因的结构特征和表达进行了分析, 并分析了昆虫APD蛋白家族的序列特征。结果显示, 在西方蜜蜂Apis mellifera（简称“西蜂”）中, apd基因家族的6个成员串联排列在基因组序列第4号连锁群上, 它们在A. m. ligustica雄蜂头部中的转录水平差异明显, 且其启动子序列所含顺式元件也不同。中蜂apd-2和意蜂apd-1-like都含有3个外显子和2个内含子, 而意蜂apd-3-like则由4个外显子和3个内含子组成。蛋白序列分析结果显示, 目前已知的10条APD蛋白序列N末端均具有相似的信号肽序列, 其成熟蛋白分子量为6.0~37.0 kD, pI为6.2~10.8。其中西蜂的APD1-3、APD-like和东方蜜蜂Apis cerena的APD-2等5条较短的多肽中疏水氨基酸残基达52%~67%, 且Ala含量最为丰富（占25%~34%）; 而丽蝇蛹集金小蜂Nasonia vitripennis的APD 1-3和西蜂APD-1-like, APD-3-like等另外5条APD多肽富含Gly（21%~30%）, 其序列中疏水氨基酸残基含量为35%~41%。多肽序列多重比对和系统进化分析结果显示, APD家族可划分为2个亚家族。亚家族Ⅰ含有西蜂APD 1-3和东方蜜蜂APD-2等4条较短的多肽序列, 其N末端为一个长33 aa的保守基序; 亚家族Ⅱ由另外6条相对较长的多肽序列组成, 其N末端保守基序长50 aa, C末端保守基序长16 aa。本文所描述的APD蛋白家族序列特征有助于以后从其他昆虫中鉴定新的apd基因。     

Adaptive evolution of a key gene affecting queen and worker traits in the honey bee, Apis mellifera

The vitellogenin egg yolk precursor protein represents a well-studied case of social pleiotropy in the model organism Apis mellifera. Vitellogenin is associated with fecundity in queens and plays a major role in controlling division of labour in workers, thereby affecting both individual and colony-level fitness. We studied the molecular evolution of vitellogenin and seven other genes sequenced in a large population panel of Apis mellifera and several closely related species to investigate the role of social pleiotropy on adaptive protein evolution. We found a significant excess of nonsynonymous fixed differences between A. mellifera, A. cerana and A. florea relative to synonymous sites indicating high rates of adaptive evolution at vitellogenin. Indeed, 88% of amino acid changes were fixed by selection in some portions of the gene. Further, vitellogenin exhibited hallmark signatures of selective sweeps in A. mellifera, including a significant skew in the allele frequency spectrum, extreme levels of genetic differentiation and linkage disequilibrium. Finally, replacement polymorphisms in vitellogenin were significantly enriched in parts of the protein involved in binding lipid, establishing a link between the gene's structure, function and effects on fitness. Our case study provides unequivocal evidence of historical and ongoing bouts of adaptive evolution acting on a key socially pleiotropic gene in the honey bee.     

Purification and characterization of honey bee vitellogenin

A protocol has been developed for the purification of vitellogenin from the honey bee, Apis mellifera. Purification allows for the first characterization of a vitellogenin from the large order Hymenoptera. Hymenopteran vitellogenins are unusual among insect vitellogenins in that they contain only one type of apoprotein. The honey bee vitellogenin was isolated from hemolymph of honey bee queens by a combination of density gradient ultracentrifugation, ion-exchange chromatography, and affinity chromatography. The native vitellogenin particle is a very high density glycolipoprotein containing approximately 91% protein, 7% lipid, and 2% carbohydrate. Phospholipid and diacylglycerol are the major lipid components. The equilibrium density (1.28 g/ml) is the same as that for Manduca sexta vitellogenin, which contains a much higher proportion of lipid. The covalently bound carbohydrate moiety of the particle is high in mannose. The amino acid composition of vitellogenin is similar to those of vitellogenins from other insect species. The N-terminal amino acid sequence of the apoprotein was determined, the first such sequence for any insect vitellogenin. When analyzed by sodium dodecyl sulfate (SDS)-gel electrophoresis, A. mellifera vitellogenin resolved into a single band with an apparent Mr of 180,000. Gel filtration under reducing and native conditions yielded estimated Mr values of about 300,000.     

The vitellogenin of the honey bee,Apis mellifera: structural analysis of the cDNA and expression studies

The cDNA of Apis mellifera vitellogenin was cloned and sequenced. It is 5440 bp long and contains an ORF of 1770 amino acids (including a putative signal peptide of 16 residues). The deduced amino acid sequence shows significant similarity with other hymenopteran vitellogenins (58% with Pimpla nipponica and 54% with Athalia rosae). The alignment with 19 insect vitellogenins shows a high number of conserved motifs; for example, close to the C-terminus there is a GL/ICG motif followed by nine cysteines, as occurs in all hymenopteran species, and, as in other insect vitellogenins, a DGXR motif is located 18 residues upstream the GL/ICG motif. Phylogenetic analysis of vitellogenin sequences available in insects gave a tree that is congruent with the currently accepted insect phylogenetic schemes. Using two fragments of the vitellogenin cDNA as probes, we analyzed by Northern blot the sex- and caste-specific patterns of vitellogenin expression in pupae and adults of A. mellifera. In queens, vitellogenin mRNA was first detected in mid-late pupal stage, whereas in workers it was first detected in late pupal stage. Vitellogenin mRNA was also observed in drones, although it was first detected not in pupae but in freshly molted adults.     

Variation in endocrine signaling underlies variation in social life history

Variation in endocrine pathways can be a major mechanism underlying life-history evolution. Yet it is unclear whether this insight, derived primarily from solitary species, explains the origins of complex life-history traits in highly social taxa. Thus, we here document and study variation in social life-history syndromes of female fecundity, behavior, and life span in selectively bred honeybee (Apis mellifera) strains. Associated variation in endocrine signaling was uncovered by RNA interference (RNAi) silencing of the juvenile hormone (JH) suppressor gene vitellogenin. High versus low endocrine reactivity in response to vitellogenin knockdown consistently correlated with rapid social behavioral ontogeny and short life span versus slow social behavioral ontogeny and long life span. Variation in JH reactivity, furthermore, was a function of variation in fecundity (ovary size and follicle development). A JH-mediated pleiotropy of female life-history traits, including fecundity, behavior, and life span, characterizes the distantly related solitary insect Drosophila. For the first time, we document a similar regulatory principle in a highly social species where most females are alloparental helpers (workers) that seldom reproduce. We conclude that variation in endocrine pathways of solitary origin can underlie variation and evolvability of complex social life-history traits.     

The Gene vitellogenin Has Multiple Coordinating Effects on Social Organization

Temporal division of labor and foraging specialization are key characteristics of honeybee social organization. Worker honeybees (Apis mellifera) initiate foraging for food around their third week of life and often specialize in collecting pollen or nectar before they die. Variation in these fundamental social traits correlates with variation in worker reproductive physiology. However, the genetic and hormonal mechanisms that mediate the control of social organization are not understood and remain a central question in social insect biology. Here we demonstrate that a yolk precursor gene, vitellogenin, affects a complex suite of social traits. Vitellogenin is a major reproductive protein in insects in general and a proposed endocrine factor in honeybees. We show by use of RNA interference (RNAi) that vitellogenin gene activity paces onset of foraging behavior, primes bees for specialized foraging tasks, and influences worker longevity. These findings support the view that the worker specializations that characterize hymenopteran sociality evolved through co-option of reproductive regulatory pathways. Further, they demonstrate for the first time how coordinated control of multiple social life-history traits can originate via the pleiotropic effects of a single gene that affects multiple physiological processes.     

The gene vitellogenin has multiple coordinating effects on social organization

Temporal division of labor and foraging specialization are key characteristics of honeybee social organization. Worker honeybees (Apis mellifera) initiate foraging for food around their third week of life and often specialize in collecting pollen or nectar before they die. Variation in these fundamental social traits correlates with variation in worker reproductive physiology. However, the genetic and hormonal mechanisms that mediate the control of social organization are not understood and remain a central question in social insect biology. Here we demonstrate that a yolk precursor gene, vitellogenin, affects a complex suite of social traits. Vitellogenin is a major reproductive protein in insects in general and a proposed endocrine factor in honeybees. We show by use of RNA interference (RNAi) that vitellogenin gene activity paces onset of foraging behavior, primes bees for specialized foraging tasks, and influences worker longevity. These findings support the view that the worker specializations that characterize hymenopteran sociality evolved through co-option of reproductive regulatory pathways. Further, they demonstrate for the first time how coordinated control of multiple social life-history traits can originate via the pleiotropic effects of a single gene that affects multiple physiological processes.     

Differential expression of immune genes of adult honey bee (Apis mellifera) after inoculated by Nosema ceranae

Nosema ceranae is a microsporidium parasite infecting adult honey bees (Apis mellifera) and is known to affects at both the individual and colony level. In this study, the expression levels were measured for four antimicrobial peptide encoding genes that are associated with bee humoral immunity (defensin, abaecin, apidaecin, and hymenoptaecin), eater gene which is a transmembrane protein involved cellular immunity and gene encoding female-specific protein (vitellogenin) in honey bees when inoculated by N. ceranae. The results showed that four of these genes, defensin, abaecin, apidaecin and hymenoptaecin were significantly down-regulated 3 and 6days after inoculations. Additionally, antimicrobial peptide expressions did not significantly differ between control and inoculated bees after 12days post inoculation. Moreover, our results revealed that the mRNA levels of eater and vitellogenin did not differ significantly following N. ceranae inoculation. Therefore, in this study we reaffirmed that N. ceranae infection induces host immunosuppression.     

The regulatory anatomy of honeybee lifespan

Honeybee workers (Apis mellifera) may be classified as either short-lived summer bees or long-lived winter bees in temperate zones. The protein status appears to be a major determinant of honeybee lifespan, and the lipoprotein vitellogenin seems to play a crucial role. Here, we give a review of the role of the vitellogenin in honeybee workers, and present a data-driven mathematical model describing the dynamics of this representative protein in the individual bee as a function of its task profile under various regimes. The results support the hypothesis that vitellogenin is a true storage protein that is utilized for various metabolic purposes including the synthesis of brood food. Except for workers having been foragers for many days, they also suggest that the previous life histories of workers do not constrain them from becoming winter bees as long as they get ample food and time to build up their protein reserves before wintering. The results also indicate that it may not be necessary to introduce the ovary as a storage organ for vitellogenin in order to generate normal winter bees. The insights gained from these results are then discussed in a broader gerontological and life history context. Remarkably similar features concerning regulation of ageing in Caenorhabditis elegans, Drosophila melanogaster and honeybees are pointed out and discussed. Furthermore, we show that in contrast to the "mutation accumulation" and the "antagonistic pleiotropy" evolutionary theories of ageing, the "disposable soma" theory is capable of explaining the bimodal longevity distribution of honeybees when interpreted in a group selection context. Finally, by showing that depletion of nutrient stores can be actively controlled by pathways connected to regulation of ageing, we strengthen the claim that age-based division of labour, with performance of risky tasks delayed until late in life by workers with depleted nutrient stores, may have evolved as an energy-saving mechanism in insect colonies.     

Vitellogenin expression in queen ovaries and in larvae of both sexes of Apis mellifera

In the honeybee, Apis mellifera, vitellogenin (Vg) expression has been detected in the ovary of queens, but not in that of workers. In addition, larvae of both sexes produce Vg in significant amounts, which suggest that Vg serves for functions additional to oocyte growth and energy supply to the embryo. In vivo hormone treatment experiments suggest that the decrease of 20-hydroxyecdysone concentration occurring in previtellogenic phases allows Vg production. Southern analysis indicates that the Vg gene is present as a single copy in the honeybee genome.