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Expression level of acetylcholinesterase 1 is associated with honey bee brooding status
Young Ho Kim,Ju Hyeon Kim,Kyungmun Kim,Si Hyeock Lee 한국응용곤충학회 2015 한국응용곤충학회 학술대회논문집 Vol.2015 No.10
The acetylcholinesterase 1 (AmAChE1) of the honey bee is known to be abundantly expressed both in the central and peripheral nervous systems. AmAChE1 exists mostly in the soluble form with little catalytic activity and has non-neuronal functions. Our preliminary observation showed that AmAChE1 expression fluctuated between the forages and nurses. A more systematic expression profiling of AmAChE1 over a year cycle on a monthly basis revealed that AmAChE1 was predominantly expressed during the winter months with being moderately expressed during the rainy summer time. However, no significant difference in AmAChE1 expression was noticed between the nurse and forager workers. Interestingly, AmAChE1 expression was inhibited when bees were allowed for brooding by placing overwintering bee hives in strawberry green houses with the supplement of pollen diets whereas it was resumed when the bee hives were removed from the green houses, thereby suppressed brooding. To confirm whether brooding status is a main determining factor for the suppression of AmAChE1 expression, active bee hives were placed in a screen tent, thereby hindering foraging, until brooding was completely suppressed, and then allowed to restore brooding by removing the screen. The AmAChE1 expression in the head was up-regulated when brooding was suppressed whereas its expression was down-regulated when brooding was resumed. These finding demonstrates that AmAChE1 expression in the central nervous system (i.e., head) is related with brooding status of honey bee. To understand the connection between the AmAChE1 expression and other pathways related with brooding, currently in progress are the analyses of head transcriptomes of honey bee workers with or without their brooding suppressed.
Kim, Kyungmun,Kim, Ju Hyeon,Kim, Young Ho,Hong, Seong-Eui,Lee, Si Hyeock Elsevier 2018 Genomics Vol.110 No.1
<P><B>Abstract</B></P> <P>Perturbation of normal behaviors in honey bee colonies by any external factor can immediately reduce the colony's capacity for brood rearing, which can eventually lead to colony collapse. To investigate the effects of brood-rearing suppression on the biology of honey bee workers, gene-set enrichment analysis of the transcriptomes of worker bees with or without suppressed brood rearing was performed. When brood rearing was suppressed, pathways associated with both protein degradation and synthesis were simultaneously over-represented in both nurses and foragers, and their overall pathway representation profiles resembled those of normal foragers and nurses, respectively. Thus, obstruction of normal labor induced over-representation in pathways related with reshaping of worker bee physiology, suggesting that transition of labor is physiologically reversible. In addition, some genes associated with the regulation of neuronal excitability, cellular and nutritional stress and aggressiveness were over-expressed under brood rearing suppression perhaps to manage in-hive stress under unfavorable conditions.</P> <P><B>Highlights</B></P> <P> <UL> <LI> Gene-set enrichment analysis of the transcriptomes of <I>Apis mellifera</I> with or without suppressed brood rearing was analyzed. </LI> <LI> Obstruction of normal labor induced over-representation in pathways related with reshaping of worker bee physiology. </LI> <LI> Transition of labor is physiologically reversible. </LI> <LI> Brood rearing suppression appeared to result in reduction of neuronal excitability and aggressiveness in worker bees. </LI> </UL> </P>
Characterization of the transcriptome of Tropilaelaps mercedesae mite parasitizing the honey bee
Kyungmun Kim,Ju Hyeon Kim,Deok Jea Cha,Si Hyeock Lee 한국응용곤충학회 2015 한국응용곤충학회 학술대회논문집 Vol.2015 No.10
Tropilaelaps mercedesae is an ectoparasite of immature honey bees belonging to the genus Tropilaelaps (Acari: Laelapidae). T. mercedesae has become a major threat to the Western honey bee Apis mellifera in Asia, including Korea, and is expanding its geographical range to northern regions due to global warming. To establish gene resources of T. mercedesae, the whole transcriptome was analyzed by RNA sequencing. An mRNA-focused library was generated from total RNA extracted from the mixed stages using the TruSeq RNA Library Preparation kit and sequenced using the HiSeq 2000 platform. A total of 6.0 Gb reads were obtained with 85% Q30 value. Trimmed sequence data were de novo assembled using the CLC Assembly Cell v 4.2. A total of 64,868 non-duplicate contigs were finally obtained and annotated by the Blast2GO using the NCBI nr database. The most abundant species in the resulting 14,336 Blast hits (22.1%) was Metaseiulus occidentalis, a predatory mite, followed by Ixodes scapularis and Tribolium castaneum, suggesting that the T. mercedesae transcriptome matches well with closely related other arthropod species, including mites and ticks. In order to provide basic information for efficient control and monitoring of potential resistance in T. mercedesae, acaricide target genes were annotated and characterized. One voltage-sensitive sodium channel gene encoding the molecular target of fluvalinate, a pyrethroid acaricide most widely used for the control of T. mercedesae, was identified and its molecular properties were investigated. In addition, other acaricide target genes, including acetylcholinesterase and glutamate (or GABA)-gated chloride channel, were identified and characterized.
Kyungmun Kim,Sang hyeon Kim,Jea ho Lee,Seung hee Han,Young ho Kim,Si hyeock Lee 한국응용곤충학회 2016 한국응용곤충학회 학술대회논문집 Vol.2016 No.10
Honey bee swarming is a natural phenomenon that occurs when the colony encounters changes in the in-hive (i.e. population size and queen condition) and environmental conditions. To better understand the molecular basis of swarming, we conducted the transcriptomic profiles of worker bees between before swarming [pre-swarming colony (PSC)] and after swarming [swarming group (SG) and remaining group (RG)]. Based on the gene set enrichment analysis (GSEA), we predicted the biological processes associated with swarming. In addition, we analyzed the composition of cuticular hydrocarbons (CHCs) by gas chromatography-mass spectrometry and compared their profiles between different bee groups. GSEA results showed that there were a little differences between PSC and RG while many of the pathways related with metabolism and protein processing were down regulated in SG relative to PSC and RG. CHCs profiling revealed a similar CHCs composition between PSC and RG but some differences in CHCs composition (i.e. heneicosane, octacosane, octacosanol) were detected between SG and RG. These differences in gene pathway and CHC composition were discussed with respect to physiological changes and social communication.