A Single SNP Turns a Social Honey Bee (<i>Apis mellifera</i>) Worker into a Selfish Parasite

Aumer, Denise; Stolle, Eckart; Allsopp, Michael H.; Mumoki, Fiona N.; Pirk, Christian Walter Werner; Moritz, Robin F. A.

doi:10.1093/molbev/msy232

Cited by 34 publications

(40 citation statements)

References 87 publications

(146 reference statements)

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“…The long‐term breeding programme for high royal jelly producing honey bees in China has resulted in an extraordinary and stable social phenotype, enabling the entire royal jelly production industry and providing a unique opportunity for understanding female reproductive investment in social insects. The study of complex social phenotypes using selected strains has revealed underlying molecular changes in a few cases that involve individual reproductive physiology (Aumer et al, ; Page et al, ; Ronai et al, ), but the breadth and duration of the selection programme for high royal jelly production is unprecedented and has led to a novel social phenotype. The increased production of new queens and royal jelly (RJ) provisioning per queen correspond in >10‐fold higher RJ production of RJBs compared to unselected Italian (ITB) honey bees that the RJBs were originally derived from (Li & Wang, ).…”

Section: Discussionmentioning

confidence: 99%

Behavioural, physiological and molecular changes in alloparental caregivers may be responsible for selection response for female reproductive investment in honey bees

Han

et al. 2019

Molecular Ecology

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Reproductive investment is a central life history variable that influences all aspects of life. Hormones coordinate reproduction in multicellular organisms, but the mechanisms controlling the collective reproductive investment of social insects are largely unexplored. One important aspect of honey bee (Apis mellifera) reproductive investment consists of raising female‐destined larvae into new queens by alloparental care of nurse bees in form of royal jelly provisioning. Artificial selection for commercial royal jelly production over 40 years has increased this reproductive investment by an order of magnitude. In a cross‐fostering experiment, we establish that this shift in social phenotype is caused by nurse bees. We find no evidence for changes in larval signalling. Instead, the antennae of the nurse bees of the selected stock are more responsive to brood pheromones than control bees. Correspondingly, the selected royal jelly bee nurses are more attracted to brood pheromones than unselected control nurses. Comparative proteomics of the antennae from the selected and unselected stocks indicate putative molecular mechanisms, primarily changes in chemosensation and energy metabolism. We report expression differences of several candidate genes that correlate with the differences in reproductive investment. The functional relevance of these genes is supported by demonstrating that the corresponding proteins can competitively bind one previously described and one newly discovered brood pheromone. Thus, we suggest several chemosensory genes, most prominently OBP16 and CSP4, as candidate mechanisms controlling queen rearing, a key reproductive investment, in honey bees. These findings reveal novel aspects of pheromonal communication in honey bees and explain how sensory changes affect communication and lead to a drastic shift in colony‐level resource allocation to sexual reproduction. Thus, pheromonal and hormonal communication may play similar roles for reproductive investment in superorganisms and multicellular organisms, respectively.

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Section: Discussionmentioning

confidence: 99%

Behavioural, physiological and molecular changes in alloparental caregivers may be responsible for selection response for female reproductive investment in honey bees

Han

et al. 2019

Molecular Ecology

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“…A genome-wide association study within a single Capensis colony headed by a naturally mated queen identified a second candidate th locus on chromosome 1, GB46427 [35,36]. GB46427 is linked to Ecdysis-triggering hormone receptor (Ethr) within a non-recombining region of the genome [36].…”

Section: Introductionmentioning

confidence: 99%

A Single Gene Causes Thelytokous Parthenogenesis, the Defining Feature of the Cape Honeybee Apis mellifera capensis

et al. 2020

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“…Charting the genotype-phenotype map in honey bees has been substantially enhanced by the availability of a genome sequence because it allows powerful techniques such as the genomewide association mapping of complex traits Zayed 2019, Kent et al 2019;Grozinger and Zayed 2020). These approaches were recently applied to study the genetics of thelytoky yielding a different candidate gene on chromosome 1, GB46427 (Aumer et al 2017, Aumer et al 2019; this uncharacterized gene contains a non-synonymous single nucleotide mutation that was strongly associated with worker clonal reduction in a single Cape honey bee colony. Yet again, population genomic data refuted this hypothesis, as the thelytoky-associated mutation in GB46427 in Aumer et al's study was also common in non-thelytokous populations (Christmas et al 2019).…”

Section: Case Studies: What Happened When Honey Bee Genomics Was Applied To Fundamental Questions In Bee Biology and Health?mentioning

confidence: 99%

The honey bee genome-- what has it been good for?

Toth

Zayed

2021

Apidologie

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In 2006, the full complement of DNA sequence information (or ‘genome’) of the Western honey bee, Apis mellifera, was published. This important resource was one of the most important advances in the history of honey bee research, with seemingly limitless applications to unlocking the secrets of honey bee biology and social life and for improving health, breeding and management. Honey bee genomics has seen immense growth in the past one and a half decades. In this article, we reflect on what the genome has added to our understanding of fundamental aspects of honey bee biology, including evolutionary origins, behaviour and health/disease. We conclude that while the genome has fuelled growth in many areas of honey bee research, it is only one part of an emerging systems-based, multi-omics approach. Moving forward, we posit that honey bee research will benefit most from an even fuller integration of genomics with classical approaches in evolution, ethology, physiology and microbiology.

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A Single SNP Turns a Social Honey Bee (Apis mellifera) Worker into a Selfish Parasite

Cited by 34 publications

References 87 publications

Behavioural, physiological and molecular changes in alloparental caregivers may be responsible for selection response for female reproductive investment in honey bees

Behavioural, physiological and molecular changes in alloparental caregivers may be responsible for selection response for female reproductive investment in honey bees

A Single Gene Causes Thelytokous Parthenogenesis, the Defining Feature of the Cape Honeybee Apis mellifera capensis

The honey bee genome-- what has it been good for?

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