Proteome Analysis Unravels Mechanism Underling the Embryogenesis of the Honeybee Drone and Its Divergence with the Worker (Apis mellifera lingustica)

The worker and drone bees each contain a separate diploid and haploid genetic makeup, respectively. Mechanisms regulating the embryogenesis of the drone and its mechanistic difference with the worker are still poorly understood. The proteomes of the two embryos at three time-points throughout develo...

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Bibliographic Details
Published in:Journal of proteome research 2015-09, Vol.14 (9), p.4059-4071
Main Authors: Fang, Yu, Feng, Mao, Han, Bin, Qi, Yuping, Hu, Han, Fan, Pei, Huo, Xinmei, Meng, Lifeng, Li, Jianke
Format: Article
Language:English
Subjects:
Animals
Bees - embryology
Embryonic Development - physiology
Insect Proteins - analysis
Insect Proteins - metabolism
Insect Proteins - physiology
Protein Interaction Maps - physiology
Proteome - analysis
Proteome - metabolism
Proteome - physiology
Proteomics
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Summary:The worker and drone bees each contain a separate diploid and haploid genetic makeup, respectively. Mechanisms regulating the embryogenesis of the drone and its mechanistic difference with the worker are still poorly understood. The proteomes of the two embryos at three time-points throughout development were analyzed by applying mass spectrometry-based proteomics. We identified 2788 and 2840 proteins in the worker and drone embryos, respectively. The age-dependent proteome driving the drone embryogenesis generally follows the worker’s. The two embryos however evolve a distinct proteome setting to prime their respective embryogenesis. The strongly expressed proteins and pathways related to transcriptional–translational machinery and morphogenesis at 24 h drone embryo relative to the worker, illustrating the earlier occurrence of morphogenesis in the drone than worker. These morphogenesis differences remain through to the middle–late stage in the two embryos. The two embryos employ distinct antioxidant mechanisms coinciding with the temporal-difference organogenesis. The drone embryo’s strongly expressed cytoskeletal proteins signify key roles to match its large body size. The RNAi induced knockdown of the ribosomal protein offers evidence for the functional investigation of gene regulating of honeybee embryogenesis. The data significantly expand novel regulatory mechanisms governing the embryogenesis, which is potentially important for honeybee and other insects.
ISSN:1535-3893
1535-3907
DOI:10.1021/acs.jproteome.5b00625