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.     

蜜蜂级型分化机理

蜜蜂Apis spp.能有效地为多种植物及农作物授粉, 具有重要的经济和生态价值; 蜜蜂作为高度真社会性昆虫, 已成为社会生物学研究的模式生物。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。近年来, 关于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。营养差异引发蜜蜂幼虫的级型分化。蜂王浆中的主要蛋白组分之一--Royalactin是诱导蜂王发育的关键营养因子, 而脂肪体细胞的表皮生长因子受体介导了Royalactin的这种蜂王诱导作用。DNA甲基化是重要的表观遗传机制之一, 且与个体发育和疾病发生紧密相关, 近来的研究表明DNA甲基化在蜜蜂级型分化过程中发挥重要的调控作用。此外, 越来越多的研究进一步深化了人们对内分泌系统调节级型分化作用的认识。本文从关键营养因子调控、 表观遗传调控和内分泌调节3方面综述蜜蜂级型分化的机理, 并对未来的研究提出可能的方向。     

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.     

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.     

Effect of royal jelly on longevity and memory-related traits of Apis mellifera workers

Royal jelly (RJ) is a key factor for honey bee caste determination. The queen bee is fed with RJ by worker bees throughout her life, while the worker bees eat bee bread themselves. This study was designed to explore the effect of nutrient-rich RJ on longevity and learning and memory abilities of workers of the western honey bee Apis mellifera. The newly emerged worker bees were randomly divided into three groups and were fed 50% sucrose solution containing 0%, 10%, and 20% RJ. We found that worker bees fed with 10% and 20% RJ showed significantly improved longevity and higher proboscis extension response success rate compared to bees fed with 50% sucrose containing 0% RJ. Additionally, bees fed with 20% RJ showed significantly higher level of expression of memory related genes (GluRA and Nmdar1) compared to the control group. Furthermore, expression of the Nmdar1 gene of worker bees fed with 10% RJ was also significantly higher than in the control group. These results indicate that RJ has potential effects on the longevity and learning and memory abilities of A. mellifera.     

感染囊幼病的工蜂咽下腺细胞的超微结构的变化

前言 中华蜜蜂囊幼病是我国养蜂业的一种重要病毒病,发病率很高,有的地区造成大量的幼虫死亡,给我国养蜂生产带来一定的危害,为了对防治病害提供科学的依据,我们首先对该病病原进行了分离、提纯及电子显微镜的研究等工作。发现该病毒对幼虫和成蜂,尤其对工蜂体内各个器官都有程度不同的影响。在幼虫发病期症状特别明显,病幼虫身体松软多水,其表皮容易破裂,当悬挂幼虫时其幼虫末端积聚有透明的液滴,在巢房内幼虫头部尖并变成黑色,头部稍微向上抬起呈船形。死后的幼虫干涸变为褐色的外壳留于巢房内,当感染的幼虫全部封盖后,巢房盖的中央有一小孔,这些异常的变化都是囊幼病的典型症状。幼虫症状虽很明显,但工蜂感染病毒后在外部形态上却没有明显     

Behavior and molecular physiology of nurses of worker and queen larvae in honey bees (Apis mellifera)

In a honey bee colony, worker bees rear a new queen by providing her with a larger cell in which to develop and a large amount of richer food (royal jelly). Royal jelly and worker jelly (fed to developing worker larvae) differ in terms of sugar, vitamin, protein and nucleotide composition. Here we examined whether workers attending queen and worker larvae are separate specialized sub-castes of the nurse bees. We collected nurse bees attending queen larvae (AQL) and worker larvae (AWL) and compared gene expression profiles of hypopharyngeal gland tissues, using Solexa/Illumina digital gene expression tag profiling (DGE). Significant differences in gene expression were found that included a disproportionate number of genes involved in glandular secretion and royal jelly synthesis. However behavioral observations showed that these were not two entirely distinct populations. Nurse workers were observed attending both worker larvae and queen larvae, and there was no evidence of a specialized group of workers that preferentially or exclusively attended developing queens. Nevertheless, AQL attended larvae more frequently compared to AWL, suggesting that nurses sampled attending queen larvae may have been the most active nurses. This study serves as another example of the relationship between differences in gene expression and behavioral specialisation in honey bees.     

The effects of honey bee (Apis mellifera L.) queen reproductive potential on colony growth

Reproduction in species of eusocial insects is monopolized by one or a few individuals, while the remaining colony tasks are performed by the worker caste. This reproductive division of labor is exemplified by honey bees (Apis mellifera L.), in which a single, polyandrous queen is the sole colony member that lays fertilized eggs. Previous work has revealed that the developmental fate of honey bee queens is highly plastic, with queens raised from younger worker larvae exhibiting higher measures in several aspects of reproductive potential compared to queens raised from older worker larvae. Here, we investigated the effects of queen reproductive potential (“quality”) on the growth and winter survival of newly established honey bee colonies. We did so by comparing the growth of colonies headed by “high-quality” queens (i.e., those raised from young worker larvae, which are more queen-like morphologically) to those headed by “low-quality” queens (i.e., those raised from older worker larvae, which are more worker-like morphologically). We confirmed that queens reared from young worker larvae were significantly larger in size than queens reared from old worker larvae. We also found a significant positive effect of queen grafting age on a colony’s production of worker comb, drone comb, and stored food (honey and pollen), although we did not find a statistically significant difference in the production of worker and drone brood, worker population, and colony weight. Our results provide evidence that in honey bees, queen developmental plasticity influences several important measures of colony fitness. Thus, the present study supports the idea that a honey bee colony can be viewed (at least in part) as the expanded phenotype of its queen, and thus selection acting predominantly at the colony level can be congruent with that at the individual level.     

Larval juvenile hormone treatment affects pre-adult development,but not adult age at onset of foraging in worker honey bees (Apis mellifera)

Previous research has shown that juvenile hormone (JH) titers increase as adult worker honey bees age and treatments with JH, JH analogs and JH mimics induce precocious foraging. Larvae from genotypes exhibiting faster adult behavioral development had significantly higher levels of juvenile hormone during the 2nd and 3rd larval instar. It is known that highly increased JH during this period causes the totipotent female larvae to differentiate into a queen. We treated third instar larvae with JH to test the hypothesis that this time period may be a developmental critical period for organizational effects of JH on brain and behavior also in the worker caste, such that JH treatment at a lower level than required to produce queens will speed adult behavioral development in workers. Larval JH treatment did not influence adult worker behavioral development. However, it made pre-adult development more queen-like in two ways: treated larvae were capped sooner by adult bees, and emerged from pupation earlier. These results suggest that some aspects of honey bee behavioral development may be relatively insensitive to pre-adult perturbation. These results also suggest JH titer may be connected to cues perceived by the adult bees indicating larval readiness for pupation resulting in adult bee cell capping behavior.     

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。     

mRNA expression and DNA methylation in three key genes involved in caste differentiation in female honeybees(Apis mellifera)

In honeybee(Apis mellifera)colonies,queens and workers are alternative forms of the adult female honeybee that develop from genetically identical zygotes but that depend on differential nourishment.Queens and workers display distinct morphologies,anatomies and behavior,better known as caste differentiation.Despite some basic insights,the exact mechanism responsible for this phenomenon,especially at the molecular level,remains unclear although some progress has been achieved.In this study,we examined mRNA levels of the TOR(target of rapamycin)and Dnmt3(DNA methyltransferase 3)genes,closely related to caste differentiation in honeybees.We also investigated mRNA expression of the S6K(similar to RPS6-p70-protein kinase)gene linked closely to organismal growth and development in queen and worker larvae(1-day and 3-day old).Last,we investigated the methylation status of these three genes in corresponding castes.We found no difference in mRNA expression for the three genes between 1st instar queen and worker larvae;however,3rd instar queen larvae had a higher level of TOR mRNA than worker larvae.Methylation levels of all three genes were lower in queen larvae than worker larvae but the differences were not statistically significant.These findings provide basic data for broadening our understanding of caste differentiation in female honeybees.     

Conservation of nutrients in larval tissue by cannibalizing honey bees

ABSTRACT. ¹⁴C-phenylalanine appeared in royal jelly secreted by worker honey bees ( Apis mellifera , L.) directly after eating ¹⁴-phenyl-alanine labelled larvae. The amount of labelled phenylalanine in royal jelly was associated directly with the volume of jelly produced. Loss of radio-label from the workers, in the form of O₂¹⁴C, increased when royal jelly secretion ended. These patterns show that conservation of nutrients in cannibalized tissue is enhanced when the cannibal bees are producing royal jelly. Specific activity of radiolabel in worker bee hypopharyngeal glands was higher than in thoracic muscle, showing selective movement within the bees of a nutrient acquired by cannibalism.     

Representational Difference Analysis (RDA) reveals differential expression of conserved as well as novel genes during caste-specific development of the honey bee (Apis mellifera L.) ovary

In highly eusocial insects, such as the honey bee, Apis mellifera, the reproductive bias has become embedded in morphological caste differences. These are most expressively denoted in ovary size, with adult queens having large ovaries consisting of 150-200 ovarioles each, while workers typically have only 1-20 ovarioles per ovary. This morphological differentiation is a result of hormonal signals triggered by the diet change in the third larval instar, which eventually generate caste-specific gene expression patterns. To reveal these we produced differential gene expression libraries by Representational Difference Analysis (RDA) for queen and worker ovaries in a developmental stage when cell death is a prominent feature in the ovarioles of workers, whereas all ovarioles are maintained and extend in length in queens. In the queen library, 48% of the gene set represented homologs of known Drosophila genes, whereas in the worker ovary, the largest set (59%) were ESTs evidencing novel genes, not even computationally predicted in the honey bee genome. Differential expression was confirmed by quantitative RT-PCR for a selected gene set, denoting major differences for two queen and two worker library genes. These included two unpredicted genes located in chromosome 11 (Group11.35 and Group11.31, respectively) possibly representing long non-coding RNAs. Being candidates as modulators of ovary development, their expression and functional analysis should be a focal point for future studies.     

Germ cell cluster formation and cell death are alternatives in caste-specific differentiation of the larval honey bee ovary

Summary

Caste-specific differentiation of the female honey bee gonad takes place in the fifth larval instar. In queen larvae most ovarioles exhibit almost simultaneous formation of numerous germ cell clusters within the first 20 h after the last larval molt. Ultrastructurally distinctive fusomal cytoplasm connects these cystocytes. Germ cell differentiation is accompanied by morphological changes in somatic components of the ovarioles, the follicle and the terminal filament cells. Subsequently, queen ovarioles elongate and differentiate basal stalks that coalesce in a basal calyx. A second round of mitotic activity was found to occur in the late prepupal and early pupal queen ovary. This round may elevate germ cell numbers composing each cluster to levels observed in follicles of adult honey bee queens. In contrast, germ cell cluster formation does not occur in most of the 120–160 ovarioles of the larval worker ovary, but instead many cells in such ovarioles show signs of impending degeneration, such as large autophagic bodies. DNA extracted from worker ovaries did not reveal nucleosomal laddering, and ultrastructurally, chromatin in germ cell nuclei appeared intact. In the 4–7 surviving ovarioles of the small worker ovary, germ cell clusters were found with ultrastructural characteristics identical to those in queen ovarioles. The temporal window during which divergence in developmental pathways of the larval ovaries initiates shortly after the last larval molt coincides with caste-specific differences in juvenile hormone titer which have long been considered critical to caste-specific morphogenesis.     

Zinc nutrition increases the antioxidant defenses of honey bees

Is the typical zinc (Zn) content of honey and pollen sufficient to meet the nutritional requirements of honey bees? To answer this question, and find the optimal dietary Zn levels for honey bees, we investigated the effects of varying dietary Zn levels on both captive worker bees and free‐flying honey bees, Apis mellifera ligustica Spinola (Hymenoptera: Apidae). We fed captive workers and free‐flying honey bees with 50% (wt/wt) sucrose solutions with Zn levels of either 0, 15, 30, 45, 60, or 75 mg kg^?1 diet and measured their Cu/Zn‐SOD activity, the mean survival time of captive bees, the Cu/Zn‐SOD activity of larvae, and the Zn concentration of royal jelly. Captive workers provided with 30 mg kg^?1 dietary Zn had higher Cu/Zn‐SOD activity and mean survival time than the control. Dietary Zn levels from 60 to 75 mg kg^?1 significantly increased the Zn content of royal jelly provided by colonies and the Cu/Zn‐SOD activity of larvae. Honey or pollen with a Zn content of <30 mg kg^?1 was insufficient to satisfy the maintenance nutritional requirements of bees that were not raising larvae. It therefore seems advisable to supply supplementary Zn to non‐brooding colonies when the Zn content of honey or pollen is <30 mg kg^?1. Honey or pollen with a Zn content of 60 mg kg^?1 was sufficient to satisfy the nutritional requirements for royal jelly production and to improve the health of larvae. It may therefore also be advisable to provide supplementary Zn to colonies with larvae when the Zn content of honey or pollen is <60 mg kg^?1.     

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.     

Caste-specific gene expression in the stingless bee <Emphasis Type="Italic">Melipona quadrifasciata</Emphasis> – Are there common patterns in highly eusocial bees?

Summary. Caste polyphenism is a multifaceted phenomenon, most evident in the marked differences in reproductive capacity and longevity between queens and workers. The mechanisms underlying caste differentiation and division of labor are mainly addressed in the honey bee, and recently have been studied at the molecular level. Yet, generalizations drawn from studies on this model organism require validation by comparative studies. We choose Melipona quadrifasciata, a sister-group species to honey bees, to investigate differences in gene expression between newly emerged adult queens and workers. RNA extracts were subjected to a differential display protocol (DDRT-PCR). The putative differentially expressed genes, for which annotation was available, were validated by RT-PCR and hybridization. Differential expression was observed for myosin, projectin, kettin, cytochrome P450, Rab11 and Sas10. Except for kettin, all of these were overexpressed in the worker caste. Projectin and kettin could play roles in caste-specific flight muscle organization. The putative Rab11 and Sas10 homolog genes could be involved in fertility-related cell signaling and in longevity-related gene silencing, respectively. Cytochrome P450 overexpression in Melipona workers corroborates similar findings in the honey bee, thus indicating a common function in the social insect caste syndrome.Received 9 January 2003; revised 10 March 2004; accepted 2 April 2004.