蜜蜂级型分化机理

蜜蜂是整个大自然生态系统中不可或缺的一部分,能有效地为多种植物和农作物授粉。蜜蜂是典型的真社会性昆虫,其生殖劳动分工现象有重要进化意义。而级型分化是导致劳动分工的一个重要因素,蜜蜂级型分化现象的机理研究已成为目前重要的研究热点之一。本文对近年来蜜蜂级型分化机理方面的研究进展进行了综述。国内外很多学者从营养、激素、基因表达、蛋白质和表观遗传等方面对蜜蜂级型分化机理进行了研究。蜂王浆中富含的57 kDa、蜂王幼虫期充足的食物量以及蜂王幼虫期高滴度的保幼激素(JH)和蜕皮激素(MA)等都可促进蜂王卵巢的发育以及诱导蜂王表型产生;而工蜂浆中富含的双香豆酸可诱使工蜂表型的产生。近年研究表明,表皮生长因子受体(Egfr)、胰岛素受体底物基因(Irs)、雷帕霉素基因(Tor)和甲基转移酶3(Dnmt3)等基因均可影响蜂王和工蜂的分化;蛋白质表达谱分析表明,不同时间点的蜂王幼虫和工蜂幼虫表达的差异蛋白质很多;表观遗传分析表明,DNA甲基化、microRNAs以及组蛋白乙酰化均是导致蜂王和工蜂级型分化的因素。此外,发育空间和蜂王浆均可通过调控基因的DNA甲基化水平影响蜜蜂幼虫的级型分化。     

熊蜂级型分化研究进展

熊蜂是众多野生植物及农作物的有效授粉昆虫,具有重要的经济和生态价值。熊蜂复杂的生长发育过程及社会性使其成为社会生物学研究的最佳模式生物之一。社会性昆虫的生殖劳动分工具有重要的进化意义,而级型分化是形成生殖劳动分工的基础。蜜蜂级型分化的研究已取得诸多重要成果,其机理也得到了较为深入的阐释,而熊蜂的社会性研究尚未形成系统,与蜜蜂研究相差甚远。近来的研究表明,饲喂频率或者饲喂总量的差异能够引起熊蜂级型分化的发生。保幼激素和蜕皮激素与熊蜂幼虫的发育紧密联系,在熊蜂级型分化的过程中发挥重要作用。一些参与蜜蜂级型分化的基因,在熊蜂级型间也存在差异表达。此外,群体间的相互作用以及蜂王和工蜂间的竞争也是促进熊蜂级型分化发生的重要因素。本文从营养、激素调控、群体发展及相互作用等方面综述熊蜂级型分化机制,并对未来的研究提出可能方向。     

表观遗传学与蜜蜂级型分化的研究进展

蜜蜂是一种高度社会化的昆虫,一个完整健康的蜂群通常是由蜂王、工蜂和雄蜂组成。尽管蜂王和工蜂的遗传物质相同,但它们在形态特征、行为职能和寿命方面表现出显著的差异。许多研究结果表明,营养因素是造成蜜蜂级型分化现象的主要原因,它可以影响蜂王幼虫和工蜂幼虫体内大量基因和蛋白的差异表达。随着表观遗传学的发展,人们对基因表达的调控机制有了新的认识,它与DNA甲基化、非编码RNA调控和组蛋白乙酰化等密切相关。这也为蜜蜂级型分化的分子机制提供了新的理论。本文就表观遗传学和蜜蜂级型分化的研究进展做一综述。     

蜜蜂卵巢激活研究进展

蜜蜂Apis作为典型的社会性昆虫,最重要的特征就是生殖劳动分工。卵巢激活是蜜蜂发挥生殖能力的重要影响因素。本文对蜜蜂卵巢激活的影响因素、蜜蜂卵巢激活相关的基因表达及microRNA在蜜蜂卵巢激活过程中的可能作用进行了介绍,为研究蜜蜂级型分化和生殖劳动分工的分子机制提供依据。     

社会性昆虫级型和行为分化机制研究进展

社会性的出现是生物演化过程中的重要革新, 理解社会性的演化和调控机制具有重要的理论和实际意义。社会性昆虫的个体间有着明显的级型分化和劳动分工, 这有利于它们适应复杂的环境变化。理解社会性昆虫如何产生不同的形态、行为和生活史特性, 一直是进化和发育生物学的重要目标。随着测序技术的不断更新及生物信息学的快速发展, 已经有众多关于社会性昆虫级型和行为分化机制的研究报道。本文通过整理社会性昆虫研究的已有成果, 从环境因素、生理调控和分子机制等方面对社会性昆虫级型和行为分化机制相关研究进展进行了综述, 并对未来的研究方向做出了展望。根据现有证据, 社会性昆虫所生活的生物环境(食物营养、信息素、表皮碳氢化合物)和非生物环境(温度、气候等)均能直接或间接影响社会性昆虫级型和行为的分化; 保幼激素、蜕皮激素、类胰岛素及生物胺等内分泌激素和神经激素对社会性昆虫的级型和行为分化也有重要的调控作用; 此外, 遗传因素、新基因等DNA序列或基因组结构上的变化以及表观遗传修饰、基因的差异表达等基因调控机制均能不同程度地影响社会性昆虫的行为分化。本文建议加强昆虫纲其他社会性类群如半翅目蚜虫和缨翅目蓟马等的社会性行为及其演化机制的研究, 以加深对社会性昆虫起源及其行为演化的理解和认识。     

昆虫DNA甲基化的特点和功能

DNA甲基化为表观遗传修饰的一种主要形式, 对基因表达的调控具有重要作用。近年来随着有关昆虫DNA甲基化的研究和报道增多, 发现昆虫DNA甲基化除了与高等哺乳动物有一定的相似性之外, 还具有独特的特点和功能。本文就昆虫DNA甲基化的主要特点和功能进行了综述, 以期为进一步研究昆虫DNA甲基化提供借鉴和参考。不同昆虫所具有的DNA甲基转移酶种类和性质差异较大, 且昆虫DNA甲基化具有甲基化水平较低、主要发生在基因区等特点, 其功能主要涉及到调节胚胎发育、参与基因组印迹、调控级型和翅型分化、影响性别决定、介入抗药性形成等。     

蜜蜂蜂王与工蜂级型分化研究进展

蜜蜂ApismekiferaL .是典型的社会性昆虫 ,蜂王和工蜂都是由受精卵发育而来的二倍体成蜂 ,但是在形态、生理、行为等方面有明显的差异 ,属于不同的级型。蜂王和工蜂的级型分化的关键时期发生在幼虫的 4龄末至 5龄止。分化是由分化基因调控的 ,幼虫期食物的质和量是分化的外部决定因子。JH对两级型中卵巢的分化有非常重要的调控作用。蜜蜂脑或其它组织中可能有分泌调控CA的咽侧体调节激素 ,它们通过对CA中JH的合成和分泌的调控而参与了分化的调控。章鱼胺等生物胺也参与了分化调控过程。     

本期重点推介

正蜜蜂Apis spp.是具有级型分化的社会性昆虫。揭示其级型分化及调控机理,对认识社会性昆虫的演化形成机制、不同级型的发育和维持机理以及对其更好地加以应用均有重要的参考价值。已有研究表明,蜂王浆的主要蛋白成分———王浆主蛋白(major royal jelly proteins,MRJPs)在蜜蜂的级型分化中具有重要的功能。mrjp8是mrjps家族中较晚发现的一个成员。为了进一步明确mrjp8基因表达与蜜蜂级型分化的关系,福建农林大学蜂学学院李江红等对西方蜜蜂Apis mellifera不同发育龄期工蜂体内,以及成年工蜂、新出房蜂王和雄蜂不同组织中的mrjp8表达水平进行了检测,发现     

蜜蜂级型分化相关生理因子研究进展

蜜蜂Apis melliferaL.是典型的社会性昆虫,蜂群内蜂王和工蜂的级型分化现象吸引了众多研究者的高度关注。蜜蜂级型分化是一个极为复杂的生长发育调节过程,许多重要生理因子参与其中,包括保幼激素、蜕皮激素、胰岛素/胰岛素类似物信号通路等。本文概述了蜜蜂级型分化相关生理因子研究进展:保幼激素决定着蜜蜂级型发育的轨迹并能阻止卵巢发育过程中细胞的程序性死亡;蜕皮激素协同保幼激素发挥调节作用;蜜蜂蜂王与工蜂的躯体大小及相关器官大小的级型特异性差异与胰岛素/胰岛素类似物信号通路密切相关。此外,本文还介绍了蜜蜂级型分化模型,该模型系统描述了上述各生理因子对级型分化的综合作用。     

蜜蜂microRNA的研究进展

MicroRNA (miRNA)是一类长度为18~24 nt的内源性非编码小RNA分子,它能通过与靶标mRNA 分子互补结合抑制蛋白质翻译或导致 mRNA 降解,从而调控靶基因表达。蜜蜂是重要的社会性经济昆虫,一直是国际上热门的研究对象。迄今为止,通过各种生物技术在蜜蜂中发现已鉴定注册的miRNA共有218个,对蜜蜂miRNA的研究表明其在蜜蜂的胚胎发育、级型分化、劳动分工和免疫防御等方面可能具有重要的调控作用。本文就miRNA对蜜蜂蜂王和工蜂级型分化、哺育蜂和采集蜂劳动分工、舞蹈行为、脑部神经功能及免疫防御等方面调控作用的最新研究进展进行了综述,以期为进一步研究miRNA提供借鉴和参考。     

Diet and cell size both affect queen-worker differentiation through DNA methylation in honey bees (Apis mellifera, Apidae)

Background

Young larvae of the honey bee (Apis mellifera) are totipotent; they can become either queens (reproductives) or workers (largely sterile helpers). DNA methylation has been shown to play an important role in this differentiation. In this study, we examine the contributions of diet and cell size to caste differentiation.

Methodology/Principal Findings

We measured the activity and gene expression of one key enzyme involved in methylation, Dnmt3; the rates of methylation in the gene dynactin p62; as well as morphological characteristics of adult bees developed either from larvae fed with worker jelly or royal jelly; and larvae raised in either queen or worker cells. We show that both diet type and cell size contributed to the queen-worker differentiation, and that the two factors affected different methylation sites inside the same gene dynactin p62.

Conclusions/Significance

We confirm previous findings that Dnmt3 plays a critical role in honey bee caste differentiation. Further, we show for the first time that cell size also plays a role in influencing larval development when diet is kept the same.     

Methionine as a methyl donor regulates caste differentiation in the European honey bee (Apis mellifera)

Nutrition contributes to honey bee caste differentiation, but the role of individual nutrients is still unclear. Most essential amino acid contents, except that of methionine (Met), are greater in royal jelly than worker jelly. After ∼3.5 d, the Met content in the latter was slightly greater than in the former. Met is the major raw material used in the synthesis of S-adenosyl-L-methionine, an active methyl donor for DNA methylation, which is an epigenetic driver of caste differentiation. Here, we tested whether Met regulates caste differentiation in honey bees by determining its effects on the caste development of bees receiving four diets: the basic, basic + 0.2% Met, basic + 0.2% Met + 20 mg/kg 5-azacytidine, and basic + 20 mg/kg 5-azacytidine. The presence of Met decreased the adult bee body length and the numbers of ovarioles, indicating that Met may direct the development of female larvae toward worker bees. The upregulated expression of SAMS, Dnmt1, and Dnmt3 caused by Met exposure in 4-d-old larvae indicated that the worker-inductive effects of Met may occur through the promotion of DNA methylation. We investigated the co-effects of Met and glucose on bee development, and found that the effects of an increased glucose level on the number of ovarioles and body length did not strengthen the worker-inductive effects caused by Met. Our results contribute to caste development theory and suggest that Met—as a methyl donor—plays a regulatory, but not decisive, role in caste differentiation.     

Ecdysteroid titer and reproduction in queens and workers of the honey bee and of a stingless bee: loss of ecdysteroid function at increasing levels of sociality?

Evidence from field wasps and bumblebees appoints the endocrine system as a mediator between dominance status and ovarian activity in primitively social Hymenoptera. In this comparative study on ecdysteroid titers in the highly social honey bee, Apis mellifera, and a stingless bee, Melipona quadrifasciata, we focussed on the relationship between the ecdysteroid titer, social conditions (presence or absence of the queen), and ovary activity. In contrast to bumblebees, ecdysteroid titers in honey bee and stingless bee workers were either not altered, or dropped to even lower levels after the queen was removed. We also did not detect differences between virgin queens and mated, egg laying queens. These results suggest that ecdysteroids may have lost most of their reproductive functions - yet gained functions in larval caste differentiation - as higher levels of social organization were attained in the evolution of social insects. The observation that ecdysteroid titers are transiently elevated in young workers adds a new, yet functionally still speculative facet to hormonal regulation in insect societies.     

Recipe for a Busy Bee: MicroRNAs in Honey Bee Caste Determination

Social caste determination in the honey bee is assumed to be determined by the dietary status of the young larvae and translated into physiological and epigenetic changes through nutrient-sensing pathways. We have employed Illumina/Solexa sequencing to examine the small RNA content in the bee larval food, and show that worker jelly is enriched in miRNA complexity and abundance relative to royal jelly. The miRNA levels in worker jelly were 7–215 fold higher than in royal jelly, and both jellies showed dynamic changes in miRNA content during the 4^th to 6^th day of larval development. Adding specific miRNAs to royal jelly elicited significant changes in queen larval mRNA expression and morphological characters of the emerging adult queen bee. We propose that miRNAs in the nurse bee secretions constitute an additional element in the regulatory control of caste determination in the honey bee.     

Epigenetic integration of environmental and genomic signals in honey bees: the critical interplay of nutritional,brain and reproductive networks

The discovery of a family of highly conserved DNA cytosine methylases in honey bees and other insects suggests that, like mammals, invertebrates possess a mechanism for storing epigenetic information that controls heritable states of gene expression. Recent data also show that silencing DNA methylation in young larvae mimics the effects of nutrition on early developmental processes that determine the reproductive fate of honey bee females. We evaluate the impact of these findings on future studies of environmentally-driven phenotypic plasticity in social insects, and discuss how they may help in understanding the nutritional basis of epigenetic reprogramming in humans.     

Making a queen: an epigenetic analysis of the robustness of the honeybee (Apis mellifera) queen developmental pathway

Specialized castes are considered a key reason for the evolutionary and ecological success of the social insect lifestyle. The most essential caste distinction is between the fertile queen and the sterile workers. Honeybee (Apis mellifera) workers and queens are not genetically distinct, rather these different phenotypes are the result of epigenetically regulated divergent developmental pathways. This is an important phenomenon in understanding the evolution of social insect societies. Here, we studied the genomic regulation of the worker and queen developmental pathways, and the robustness of the pathways by transplanting eggs or young larvae to queen cells. Queens could be successfully reared from worker larvae transplanted up to 3 days age, but queens reared from older worker larvae had decreased queen body size and weight compared with queens from transplanted eggs. Gene expression analysis showed that queens raised from worker larvae differed from queens raised from eggs in the expression of genes involved in the immune system, caste differentiation, body development and longevity. DNA methylation levels were also higher in 3‐day‐old queen larvae raised from worker larvae compared with that raised from transplanted eggs identifying a possible mechanism stabilizing the two developmental paths. We propose that environmental (nutrition and space) changes induced by the commercial rearing practice result in a suboptimal queen phenotype via epigenetic processes, which may potentially contribute to the evolution of queen–worker dimorphism. This also has potentially contributed to the global increase in honeybee colony failure rates.     

Regulation of oogenesis in honey bee workers via programed cell death

Reproductive division of labour characterises eusociality. Currently little is known about the mechanisms that underlie the ‘sterility’ of the worker caste, but queen pheromone plays a major role in regulating the reproductive state. Here we investigate oogenesis in the young adult honey bee worker ovary in the presence of queen pheromone and in its absence. When queen pheromone is absent, workers can activate their ovaries and have well-developed follicles. When queen pheromone is present, even though workers have non-activated ovaries, they continually produce oocytes which are aborted at an early stage. Therefore, irrespective of the presence of the queen, the young adult worker ovary contains oocytes. By this means young workers retain reproductive plasticity. The degeneration of the germ cells in the ovarioles of workers in the presence of queen pheromone has the morphological hallmarks of programmed cell death. Therefore the mechanistic basis of ‘worker sterility’ relies in part on the regulation of oogenesis via programmed cell death. Our results suggest that honey bees have co-opted a highly conserved checkpoint at mid-oogenesis to regulate the fertility of the worker caste.     

The role of exogenous JH I,JH III and Anti-JH (precocene II) on queen induction of 4.5-day-old worker honey bee larvae

Worker larvae at an age of 4½ days were fed one of several mixtures of reconstituted royal jelly adjusted to a refractive index of 1.3825 and supplemented with JH I, JH III or Anti-JH (precocene II). In addition, juvenile hormone was topically applied to larvae of the same age. It was readily apparent that caste induction is concentration-dependent and that 4?-day-old worker larvae can still develop into queens under laboratory conditions, providing that they have not stopped feeding or can be induced to commence feeding again. These findings are contrary to the general belief that queen induction is not possible after a socalled sensitive period of 3–3½ days. Queens resulted only from honey bee larvae exposed to royal jelly containing 1 μg of JH I. In addition, oral application at this concentration resulted in the only case in which the normal mean weights of worker honey bees were exceeded. All other concentrations of juvenile hormone were not sufficient to initiate queen induction, although its lower concentration may have influenced the production of intercastes.Precocene II did not play a role in queen induction and it also did not interfere with the growth of developing larvae or adults. In addition, the lack of malformations in honey bees treated with precocene II indicates that the use of such a compound as a control agent in insect populations will probably not be detrimental to honey bee larvae that are at least 4½ days old. However, large doses of precocene will quickly kill most 3½-day-old honey bee larvae.The evidence presented here clearly indicates that caste determination is regulated by the endocrine system in honey bee larvae. Food intake in honey bee larvae may well be regulated by the endocrine system. Thus, an apparently inhibited corpus allatum (C.A.) could be reactivated by food intake coupled with juvenile hormone. The food intake restriction that worker larvae normally encounter in the hive probably results in a cessation of C.A. activity. The increase in food intake by queen larvae, on the other hand, carries an increase in growth and accompanying morphological changes necessary for queen development. This concept may also explain the development of intercastes encountered in in vitro studies. Only those larvae that follow a normal food intake sequence, i.e. moderate during the first 3–4 days or so, will develop into queens. Conversely, those larvae that take in too much food during the early portion of development may achieve incomplete development of the neurosecretory system and, thus, develop into intercastes.