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。     

A Strong Immune Response in Young Adult Honeybees Masks Their Increased Susceptibility to Infection Compared to Older Bees

Honeybees, Apis mellifera, show age-related division of labor in which young adults perform maintenance (“housekeeping”) tasks inside the colony before switching to outside foraging at approximately 23 days old. Disease resistance is an important feature of honeybee biology, but little is known about the interaction of pathogens and age-related division of labor. We tested a hypothesis that older forager bees and younger “house” bees differ in susceptibility to infection. We coupled an infection bioassay with a functional analysis of gene expression in individual bees using a whole genome microarray. Forager bees treated with the entomopathogenic fungus Metarhizium anisopliae s.l. survived for significantly longer than house bees. This was concomitant with substantial differences in gene expression including genes associated with immune function. In house bees, infection was associated with differential expression of 35 candidate immune genes contrasted with differential expression of only two candidate immune genes in forager bees. For control bees (i.e. not treated with M. anisopliae) the development from the house to the forager stage was associated with differential expression of 49 candidate immune genes, including up-regulation of the antimicrobial peptide gene abaecin, plus major components of the Toll pathway, serine proteases, and serpins. We infer that reduced pathogen susceptibility in forager bees was associated with age-related activation of specific immune system pathways. Our findings contrast with the view that the immunocompetence in social insects declines with the onset of foraging as a result of a trade-off in the allocation of resources for foraging. The up-regulation of immune-related genes in young adult bees in response to M. anisopliae infection was an indicator of disease susceptibility; this also challenges previous research in social insects, in which an elevated immune status has been used as a marker of increased disease resistance and fitness without considering the effects of age-related development.     

Effect of age,behaviour and social environment on honey bee brain plasticity

We examined the effects of behaviour, age and social environment on mushroom body volume in adult bees. The mushroom bodies are regions of the central brain important for sensory integration and learning. Their volume was influenced by behaviour throughout life: always larger in forager bees than age-matched nurse bees, even in old bees up to 93 days of age as adults. Mushroom body development was influenced by the social environment in the first 8 days of adult life, with different environments having markedly different effects on mushroom body size. Compared to hive-reared bees, isolation slowed mushroom body growth, but bees reared in isolation confined with a single dead bee showed a dramatic increase in mushroom body volume comparable to that seen in active foragers. Despite their precocious mushroom body development, these bees did not show improved performance in an olfactory learning test. Since simple environmental manipulations can both accelerate and delay mushroom body growth in young bees, and since mushroom body volume is sensitive to behaviour throughout life, the honey bee has great potential as a model for exploring the interactions between environment, behaviour and brain structure.     

Effects of experience and juvenile hormone on the organization of the mushroom bodies of honey bees

There is an age-related division of labor in the honey bee colony that is regulated by juvenile hormone. After completing metamorphosis, young workers have low titers of juvenile hormone and spend the first several weeks of their adult lives performing tasks within the hive. Older workers, approximately 3 weeks of age, have high titers of juvenile hormone and forage outside the hive for nectar and pollen. We have previously reported that changes in the volume of the mushroom bodies of the honey bee brain are temporally associated with the performance of foraging. The neuropil of the mushroom bodies is increased in volume, whereas the volume occupied by the somata of the Kenyon cells is significantly decreased in foragers relative to younger workers. To study the effect of flight experience and juvenile hormone on these changes within the mushroom bodies, young worker bees were treated with the juvenile hormone analog methoprene but a subset was prevented from foraging (big back bees). Stereological volume estimates revealed that, regardless of foraging experience, bees treated with methoprene had a significantly larger volume of neuropil in the mushroom bodies and a significantly smaller Kenyon cell somal region volume than did 1-day-old bees. The bees treated with methoprene did not differ on these volume estimates from untreated foragers (presumed to have high endogenous levels of juvenile hormone) of the same age sampled from the same colony. Bees prevented from flying and foraging nonetheless received visual stimulation as they gathered at the hive entrance. These results, coupled with a subregional analysis of the neuropil, suggest a potentially important role of visual stimulation, possibly interacting with juvenile hormone, as an organizer of the mushroom bodies. In an independent study, the brains of worker bees in which the transition to foraging was delayed (overaged nurse bees) were also studied. The mushroom bodies of overaged nurse bees had a Kenyon cell somal region volume typical of normal aged nurse bees. However, they displayed a significantly expanded neuropil relative to normal aged nurse bees. Analysis of the big back bees demonstrates that certain aspects of adult brain plasticity associated with foraging can be displayed by worker bees treated with methoprene independent of foraging experience. Analysis of the over-aged nurse bees suggests that the post-metamorphic expansion of the neuropil of the mushroom bodies of worker honey bees is not a result of foraging experience. © 1995 John Wiley & Sons, Inc.     

The microRNA ame-miR-279a regulates sucrose responsiveness of forager honey bees (Apis mellifera)

Increasing evidence demonstrates that microRNAs (miRNA) play an important role in the regulation of animal behaviours. Honey bees (Apis mellifera) are eusocial insects, with honey bee workers displaying age-dependent behavioural maturation. Many different miRNAs have been implicated in the change of behaviours in honey bees and ame-miR-279a was previously shown to be more highly expressed in nurse bee heads than in those of foragers. However, it was not clear whether this difference in expression was associated with age or task performance. Here we show that ame-miR-279a shows significantly higher expression in the brains of nurse bees relative to forager bees regardless of their ages, and that ame-miR-279a is primarily localized in the Kenyon cells of the mushroom body in both foragers and nurses. Overexpression of ame-miR-279a attenuates the sucrose responsiveness of foragers, while its absence enhances their sucrose responsiveness. Lastly, we determined that ame-miR-279a directly target the mRNA of Mblk-1. These findings suggest that ame-miR-279a plays important roles in regulating honey bee division of labour.     

Biogenic amines and division of labor in honey bee colonies: behaviorally related changes in the antennal lobes and age-related changes in the mushroom bodies

Levels of the biogenic amines dopamine, serotonin, and octopamine were measured in different brain regions of adult worker honey bees as a function of age-related division of labor, using social manipulations to unlink age and behavioral state. In the antennal lobes, foragers had higher levels of all three amines than nurses, regardless of age. Differences were larger for octopamine than serotonin or dopamine. In the mushroom bodies, older bees had higher levels of all three amines than younger bees, regardless of behavioral state. These correlative results suggest that increases in octopamine in the antennal lobes may be particularly important in the control of age-related division of labor in honey bees. Accepted: 10 February 1999     

西方蜜蜂采集蜂上颚腺中高表达基因的筛选与表达分析

【目的】本研究旨在筛选西方蜜蜂Apis mellifera采集蜂上颚腺中高表达基因,为进一步筛选和研究蜜蜂采集行为相关基因提供依据。【方法】基于前期测序的西方蜜蜂5种不同职能工蜂(3日龄工蜂、10日龄哺育蜂、10日龄采集蜂、21日龄哺育蜂和21日龄采集蜂)上颚腺转录组数据,筛选采集蜂上颚腺的差异表达基因(differentially expressed genes, DEGs),并对这些DEGs进行GO和KEGG分析;qRT-PCR检测随机选取的8个DEGs在10日龄哺育蜂和10日龄采集蜂上颚腺以及两个关键DEGs(Δ-1-吡咯啉-5-羧酸合成酶基因Amp5cs和细胞色素P450 9e2基因CYP9Q3)在工蜂不同发育时期和采集蜂各组织中的表达量。【结果】筛选到22个DEGs在21日龄采集蜂上颚腺中的表达量显著高于在3日龄工蜂、10日龄哺育蜂和21日龄哺育蜂上颚腺中的表达量,同时在10日龄采集蜂上颚腺中的表达量也显著高于在10日龄哺育蜂上颚腺中的表达量。GO和KEGG富集分析显示这些DEGs主要富集在胆固醇代谢、半乳糖代谢、淀粉和蔗糖代谢、精氨酸和脯氨酸代谢、细胞凋亡-果蝇、氨基酸生物合成等方面。qRT-PCR结果表明,8个DEGs(LOC100576395, LOC411983, LOC410235, LOC725581, LOC410527, LOC406131, LOC408453和LOC410253)的表达模式与转录组数据的表达模式一致;2个关键DEGs Amp5cs和CYP9Q3在工蜂各发育阶段均有表达,且在采集蜂中表达量最高;Amp5cs在采集蜂腹、胸、上颚腺和触角中高量表达,P450 9e2在采集蜂触角 和足中表达量显著高于在其他组织中的。【结论】本研究在减小日龄因素干扰下筛选了西方蜜蜂采集蜂上颚腺中22个高表达的DEGs,这些DEGs可能主要参与采集蜂上颚腺生理发育以及能量供应、外源性物质解毒、花蜜转化等代谢通路,进而影响蜜蜂的采集行为。这些结果为西方蜜蜂上颚腺的功能研究提供理论参考,同时也为采集力强的新品种培育奠定了基础。     

Identification and validation of reference genes for real time PCR expression studies in heads of nurse honeybees

The primary aim of this study was to identify reference genes and workers of particular role and ages that would be suitable for exploring genetic/epigenetic variations in constitutive expression of a gene encoding antimicrobial peptide defensin1 in worker heads using real-time PCR. This peptide is an integral component of larval food and honey and has potential to act against some brood pathogens. Expression levels of distinct genes may vary in worker heads due to genetic factors, age of bee, and particular role of a worker that depends on its age or colony needs. Prerequisite for exploring the variations in defensin1 expression was therefore to identify such workers in which correlated expression of defensin1 and suitable reference genes occurs. Selection process was done by carefully designed quantitative real-time PCR procedure in two colonies showing different age-related division of labor. Expression of ten candidate reference genes, defensin1 and amylase, as a marker of forager bees, was assessed in pooled head samples of workers aged 2 to 30 days. Correlated and moreover stable expression of defensin1 and six candidate genes was detected in nursing bees in both colonies. The suitable reference genes were therefore selected on the basis of their expression stability. This was evaluated by geNorm and NormFinder algorithms in pooled head samples and through plotted Cq data in head samples of individual nurse bees. As the best reference genes were selected: psa1, tctp1, cyclophilin, gapdh and mrjp4 (in this order). They are suitable for aforementioned defensin1 expression studies and also for studies of other genes expressed in heads of nurses. In addition, an amylase expression-based procedure for reliable distinguishing nurses from foragers was elaborated.     

period expression in the honey bee brain is developmentally regulated and not affected by light, flight experience, or colony type

Changes in circadian rhythms of behavior are related to age-based division of labor in honey bee colonies. The expression of the clock gene period (per) in the bee brain is associated with age-related changes in circadian rhythms of behavior, but previous efforts to firmly associate per brain expression with division of labor or age have produced variable results. We explored whether this variability was due to differences in light and flight experience, which vary with division of labor, or differences in colony environment, which are known to affect honey bee behavioral development. Our results support the hypothesis that per mRNA expression in the bee brain is developmentally regulated. One-day-old bees had the lowest levels of expression and rarely showed evidence of diurnal fluctuation, while foragers and forager-age bees (> 21 days of age) always had high levels of brain per and strong and consistent diurnal patterns. Results from laboratory and field experiments do not support the hypothesis that light, flight experience, and colony type influence per expression. Our results suggest that the rate of developmental elevation in per expression is influenced by factors other than the ones studied in our experiments, and that young bees are more sensitive to these factors than foragers.     

Changes in the Gene Expression Profiles of the Hypopharyngeal Gland of Worker Honeybees in Association with Worker Behavior and Hormonal Factors

The hypopharyngeal glands (HPGs) of worker honeybees undergo physiological changes along with the age-dependent role change from nursing to foraging: nurse bee HPGs secrete mainly major royal jelly proteins, whereas forager HPGs secrete mainly α-glucosidase III, which converts the sucrose in the nectar into glucose and fructose. We previously identified two other genes, Apis mellifera buffy (Ambuffy) and Apis mellifera matrix metalloproteinase 1 (AmMMP1), with enriched expression in nurse bee and forager HPGs, respectively. In the present study, to clarify the molecular mechanisms that coordinate HPG physiology with worker behavior, we first analyzed whether Ambuffy, AmMMP1, mrjp2 (a gene encoding one of major royal jelly protein isoforms), and Hbg3 (a gene encoding α-glucosidase III) expression, is associated with worker behavior in ''single-cohort colonies'' where workers of almost the same age perform different tasks. Expression of these genes correlated with the worker’s role, while controlling for age, indicating their regulation associated with the worker’s behavior. Associated gene expression suggested the possible involvement of some hormonal factors in its regulation. We therefore examined the relationship between ecdysone- and juvenile hormone (JH)-signaling, and the expression profiles of these ‘indicator’ genes (nurse bee HPG-selective genes: mrjp2 and Ambuffy, and forager HPG-selective genes: Hbg3 and AmMMP1). Expression of both ecdysone-regulated genes (ecdysone receptor, mushroom body large type Kenyon cell specific protein-1, and E74) and JH-regulated genes (Methoprene tolerant and Krüppel homolog 1) was higher in the forager HPGs than in the nurse bee HPGs, suggesting the possible roles of ecdysone- and JH-regulated genes in worker HPGs. Furthermore, 20-hydroxyecdysone-treatment repressed both nurse bee- and forager-selective gene expression, whereas methoprene-treatment enhanced the expression of forager-selective genes and repressed nurse bee-selective genes in the HPGs. Our findings suggest that both ecdysone- and JH-signaling cooperatively regulate the physiological state of the HPGs in association with the worker’s behavior.     

Transcriptional response to foraging experience in the honey bee mushroom bodies

Enriched environmental conditions induce neuroanatomical plasticity in a variety of vertebrate and invertebrate species. We explored the molecular processes associated with experience-induced plasticity, using naturally occurring foraging behavior in adult worker honey bees (Apis mellifera). In honey bees, the mushroom bodies exhibit neuroanatomical plasticity that is dependent on accumulated foraging experience. To investigate molecular processes associated with foraging experience, we performed a time-course microarray study to examine gene expression changes in the mushroom bodies as a function of days foraged. We found almost 500 genes that were regulated by duration of foraging experience. Bioinformatic analyses of these genes suggest that foraging experience is associated with multiple molecular processes in the mushroom bodies, including some that may contribute directly to neuropil growth, and others that could potentially protect the brain from the effects of aging and physiological stress.     

中华蜜蜂Malvolio基因 Acmvl 的克隆及组织表达分析

【目的】本研究克隆了中华蜜蜂Apis cerana cerana Malvolio (Mvl)基因的cDNA序列,分析了其编码蛋白的结构特点,并探讨其mRNA在内勤蜂、采蜜蜂和采粉蜂各部位组织中的表达差异,以期为该基因的生物学功能研究提供参考。【方法】利用RT-PCR技术从中华蜜蜂内勤蜂头部组织中扩增和克隆获得Acmvl的全长序列,并采用多种生物信息学软件分析Acmvl蛋白的结构特征;采用Real-time PCR对中华蜜蜂Acmvl在内勤蜂、采蜜蜂和采粉蜂各组织中的表达特征进行分析。【结果】Acmvl基因cDNA全长为2 130 bp（GenBank登录号：KP662686）,编码587个氨基酸,预测该蛋白分子量为65.86 kD,等电点为6.03,无信号肽,存在11个跨膜结构域、9个糖基化位点和14个潜在磷酸化位点;系统发育树分析结果显示,中华蜜蜂Acmvl与其他膜翅目昆虫Malvolio聚为一支,与小鼠Mus musculus和人Homo sapiens Nramp家族的Nramp2聚为另一大分支,且与小鼠、水稻 Oryza sativa 、黑腹果蝇 Drosophila melanogaster 和酵母Saccharomyces cerevisiae的Nramp家族同源体在跨膜区、跨膜区带电残基及转运蛋白特征结构域上有很高的保守性,尤其是与Nramp2。Acmvl 基因在中华蜜蜂各部位组织中均有表达,但高表达于内勤蜂的胸部及采蜜蜂和采粉蜂的腹部和足部,提示该基因表达的差异影响采集行为。【结论】Acmvl 属于Nramp基因家族,可能为Nramp2的同源基因,该基因影响采集行为可能与转运Cu²⁺, Mn²⁺和Fe²⁺（尤其是Fe²⁺）有关。     

Neuronal plasticity in the mushroom body calyx during adult maturation in the honeybee and possible pheromonal influences

Honeybee workers express a pronounced age‐dependent polyethism switching from various indoor duties to foraging outside the hive. This transition is accompanied by tremendous changes in the sensory environment that sensory systems and higher brain centers have to cope with. Foraging and age have earlier been shown to be associated with volume changes in the mushroom bodies (MBs). Using age‐ and task‐controlled bees this study provides a detailed framework of neuronal maturation processes in the MB calyx during the course of natural behavioral maturation. We show that the MB calyx volume already increases during the first week of adult life. This process is mainly driven by broadening of the Kenyon cell dendritic branching pattern and then followed by pruning of projection neuron axonal boutons during the actual transition from indoor to outdoor duties. To further investigate the flexible regulation of division of labor and its neuronal correlates in a honeybee colony, we studied the modulation of the nurse‐forager transition via a chemical communication system, the primer pheromone ethyl oleate (EO). EO is found at high concentrations on foragers in contrast to nurse bees and was shown to delay the onset of foraging. In this study, EO effects on colony behavior were not as robust as expected, and we found no direct correlation between EO treatment and synaptic maturation in the MB calyx. In general, we assume that the primer pheromone EO rather acts in concert with other factors influencing the onset of foraging with its effect being highly adaptive. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 75: 1368–1384, 2015