Project description:We investigated genome-wide DNA methylation of newly emerged queens, newly emerged workers, adult nurses, adult foragers and adult reverted nurses using comprehensive high throughput arrays for relative methylation (CHARM) We used custom Nimblegen microarrays We isolated genomic DNA from newly emerged queens, newly emerged workers, adult continuous nurses, adult continuous foragers and adult reverted nurses hybridized to custom-designed Nimblegen microarrays (CHARM arrays). Multiple brains were pooled for each sample and used for the genome-wide DNA methylation analysis.

Project description:We investigated genome-wide DNA methylation of newly emerged queens, newly emerged workers, adult nurses, adult foragers and adult reverted nurses using comprehensive high throughput arrays for relative methylation (CHARM) We used custom Nimblegen microarrays

Project description:In social insects, workers perform distinct tasks according to the caste they belong to, and workers from different castes differ in their age (nest workers are usually younger than foragers are). The caste shift thus seems inseparable from age, preventing from deciphering the role of labour division and age in regulating individual physiology and ageing rates. We set up an experimental protocol separating age and caste effects by defining four groups of black garden ant (Lasius niger) workers: young foragers (Y.F), old foragers (O.F), young nest workers (Y.NW) and old nest workers (O.NW). Proteomics highlighted differences between individuals according to their age, whereas metabolomics revealed caste-related differences. Our study highlighted that age and caste influence specifically different aspects of the physiology of ant workers.

Project description:In ant Harpegnathos saltator, workers can become the reproductive gamergates in a queenless condition. During the worker-to-gamergate transition, juvenile hormone signaling decreases but ovarian ecdysone production increases in the gamergate. Injecting juvenile hormone analog (JHA or methoprene) induces expression of worker-biased genes in the brain , while ecydsone promotes expression of ecdysone-responsive genes in ovaries.

Project description:While Apis cerana cerana, like Apis mellifera, undergoes a behavioral transition from in-hive nursing to outdoor foraging duties, nothing is known about the genes underlying this social signal-triggered aged-related transition in this species. Here, we simultaneously sequenced the head transcriptomes of the 7-day-old normal nurses (N7BY), 18- and 22-day-old normal foragers (N18CJ and N22CJ), 7-day-old precocious foragers (Tq7CJ) and 22-day-old overaged or reverted nurses (Tq22BY) of A. cerana cerana by RNA-seq and made a 3-tier comparison (from pairwise to group-wise and between-group) to unravel the genes associated with this transition. Six pairwise comparisons revealed 165-492 differentially expressed genes between nurses vs. foragers. Subsequent 3 group-wise and 1 between-group comparisons narrowed the transition-associated genes down to 18 nurse- and 41 forager-unique genes and 29 (14 and 15 genes upregulated in nurses and foragers, respectively) differentially expressed genes between the 3 types of foragers and 2 types of nurses. The uniquely expressed genes are usually low-abundance long noncoding RNAs, transcription factors, transcription coactivators, RNA-binding proteins, kinases or phosphatases involved in signaling transduction and/or gene expression regulation, whereas the differentially expressed genes are often high-abundance downstream genes that directly perform the tasks of nurses or foragers, such as major royal jelly proteins for nurses and the genes involved in sugar/protein digestion, lipids/fatty acids metabolism, plant allelochemicals detoxification and defense against pathogens and predators for foragers. Mapping of the clean reads to the published A. mellifera genome uncovered that the 3 types of foragers had a greater percentage of reads from annotated exons and intergenic regions, whereas the 2 types of nurses had a greater percentage of reads from introns. Taken together, these results suggest that the reciprocal nurse-forager behavioral transition of the A. cerana cerana is regulated by a social signal-triggered intron-exon/intergenic epigenetic shift and the resulted transcriptional shift of the nurse- and forager-associated genes.

Project description:Olfaction system plays a fundamental role in mediating insect behavior. Besides, the division of queen, worker and drone, honeybee also exhibit an age-dependent division of labor. Worker bees perform discrete sets of behaviors throughout their lifespan. These behavioral states rely on the sense of the environments and chemical communications via their olfactory system - antennae. However, the olfactory adaption mechanism of workers in these processes of behavioral development is still unclear. In this study, we conducted a comprehensive and quantitative analysis of gene expression in Apis mellifera antenna of newly emerged workers, nurses, foragers, and defenders using RNA-seq. We found that antennae tissues continue to develop after transformation from pupae to adult. Additionally, we identified both developmental and labor-division specific expressed genes. We validated the unexpected discovery of major royal jelly protein genes, which are highly and specifically expressed in nurse honeybee workers. We further identified and validated that significant alternative splicing events are also involved in the development and division of labor. These findings provided a comprehensive transcriptome profile and new perspective into the molecular mechanism underlying honeybee division of labor.

Project description:We used whole-genome fire ant microarrays to examine the molecular basis for social organization in Solenopsis invicta. Monogyne (single queen) fire ant colonies were collected in the field and transported into the lab were they were reared in standard conditions for two weeks. At this point, each colony was split into two sub-colonies: one sub-colony contained the functional mother queen (queenright) while the other was left queenless. Each sub-colony included a nesting chamber, containing the brood and workers performing nursing tasks, and a foraging area, separated from the nesting chamber and provided with food and water sources. For both queenright and queenless sub-colonies, foraging workers were collected in the foraging area while non-foraging workers were collected in the nesting chamber. Total RNA was isolated from pools of 10 whole workers and processed for microarrays.

Project description:This dataset contains samples of honey bee worker hemolymph extracted from nurses and foragers one month after colony establishment in Western red cedar and white pine nuc boxes.

Project description:In honey bees, Vitellogenin (Vg) is hypothesized to be a major factor affecting hormone signaling, food-related behavior, immunity, stress resistance and lifespan. Likewise microRNAs play important roles in posttranscriptional gene regulation and affect many biological processes thereby showing many parallels to Vg functions. The molecular basis of Vg and microRNA interactions is largely unknown. Here, we exploited the well-established RNA interference (RNAi) protocol for Vg knockdown to investigate its effects on microRNA population in honey bee foragerM-bM-^@M-^Ys brain and fat body tissue. To identify microRNAs that are differentially expressed between tissues in control and knockdown foragers, we used M-BM-5ParafloM-BM-. microfluidic oligonucleotide microRNA microarrays. Our results show 76 and 74 miRNAs were expressed in the brain of control and knockdown foragers whereas 66 and 69 miRNAs were expressed in the fat body of control and knockdown foragers respectively. Target prediction identified potential seed matches for differentially expressed subset of microRNAs affected by Vg knockdown. These candidate genes are involved in a broad range of biological processes including insulin signaling, juvenile hormone (JH) and ecdysteroid signaling previously shown to affect foraging behavior. Thus, here we demonstrate a causal link between Vg expression-variation and variation in the abundance of microRNAs in different tissues with possible consequences for regulation of foraging behavior. We knocked down Vitellogenin (Vg) gene expression (using RNAi) in adult workers to identify potential downstream consequences on the expression of microRNA population in the fat body compared to control group (dsRNA-GFP injected bees). Six biological samples of fat body-derived small RNA fraction were prepared for each treatment group (dsRNA-Vg and dsRNA-GFP). Each biological sample contained pooled RNA from 5 unique individuals. Each fat body pool contained a total of 2 M-BM-5g of small RNA fraction, to which each of the 5 individuals contributed equally (400 ng). Pools were named as M-bM-^@M-^\control forager fat bodyM-bM-^@M-^] (GFFb) and M-bM-^@M-^\knockdown forager fat bodyM-bM-^@M-^] (VFFb), followed by a number from 1 to 6.

Project description:In honey bees, Vitellogenin (Vg) is hypothesized to be a major factor affecting hormone signaling, food-related behavior, immunity, stress resistance and lifespan. Likewise microRNAs play important roles in posttranscriptional gene regulation and affect many biological processes thereby showing many parallels to Vg functions. The molecular basis of Vg and microRNA interactions is largely unknown. Here, we exploited the well-established RNA interference (RNAi) protocol for Vg knockdown to investigate its effects on microRNA population in honey bee foragerM-bM-^@M-^Ys brain and fat body tissue. To identify microRNAs that are differentially expressed between tissues in control and knockdown foragers, we used M-BM-5ParafloM-BM-. microfluidic oligonucleotide microRNA microarrays. Our results show 76 and 74 miRNAs were expressed in the brain of control and knockdown foragers whereas 66 and 69 miRNAs were expressed in the fat body of control and knockdown foragers respectively. Target prediction identified potential seed matches for differentially expressed subset of microRNAs affected by Vg knockdown. These candidate genes are involved in a broad range of biological processes including insulin signaling, juvenile hormone (JH) and ecdysteroid signaling previously shown to affect foraging behavior. Thus, here we demonstrate a causal link between Vg expression-variation and variation in the abundance of microRNAs in different tissues with possible consequences for regulation of foraging behavior. We knocked down Vitellogenin (Vg) gene expression (using RNAi) in adult workers to identify potential downstream consequences on the expression of microRNA population in the brain compared to control group (dsRNA-GFP injected bees). Six biological samples of brain-derived small RNA fraction were prepared for each treatment group (dsRNA-Vg and dsRNA-GFP). Each biological sample contained pooled RNA from 5 unique individuals. Each brain pool contained a total of 1 M-BM-5g of small RNA fraction, to which each of the 5 individuals contributed equally (200 ng). Pools were named as M-bM-^@M-^\control forager brainM-bM-^@M-^] (GFBr) and M-bM-^@M-^\knockdown forager brainM-bM-^@M-^] (VFBr), followed by a number from 1 to 6.