Individual and social heterosis act independently in honey bee (Apis mellifera) colonies.

IF 3 2区 生物学 Q2 EVOLUTIONARY BIOLOGY Journal of Heredity Pub Date : 2024-08-16 DOI:10.1093/jhered/esae043
Dylan K Ryals, Amos C Buschkoetter, J Krispn Given, Brock A Harpur
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Abstract

Heterosis occurs in individuals when genetic diversity, i.e., heterozygosity, increases fitness. Many advanced eusocial insects evolved mating behaviors, including polyandry and polygyny, which increase inter-individual genetic diversity within colonies. The possibility of this structure of diversity to improve group fitness has been termed social heterosis. Neither the independence of individual and social heterosis nor their relative effect sizes have been explicitly measured. Through controlled breeding between pairs of Western honey bee queens (Apis mellifera L.; n=3 pairs) from two distinct populations, we created inbred colonies with low genetic diversity, hybrid colonies with high heterozygosity, and mixed colonies (combining inbred workers from each population) with low heterozygosity and high social diversity. We then quantified two independent traits in colonies: survival against bacterial challenge and maintenance of brood nest temperature. For both traits, we found hybrid and mixed colonies outperformed inbred colonies but did not perform differently from each other. During immune challenge assays, hybrid and mixed colonies experienced hazard ratios of 0.49 (95% CI [0.37, 0.65]) and 0.69 (95% CI [0.50, 0.96]) compared to inbred colonies. For nest temperatures, hybrid and mixed colonies experienced 1.94±0.97°C and 2.82±2.46°C less thermal error and 0.14±0.11°C2 and 0.16±0.06°C2 less thermal variance per hour than inbred lines. This suggests social and individual heterosis operate independently and may have similar effect sizes. These results highlight the importance of both inter- and intra-individual diversity to fitness, which may help explain the emergence of polyandry/polygyny in eusocial insects and inform breeding efforts in these systems.

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蜜蜂(Apis mellifera)蜂群中的个体异质性和社会异质性是独立作用的。
当遗传多样性(即杂合度)提高了个体的适应性时,个体中就会出现异质性。许多高级社会性昆虫进化出了交配行为,包括多雄性交配和多雌性交配,这增加了群体内个体间的遗传多样性。这种多样性结构提高群体适合度的可能性被称为社会异质性。个体异质性和社会异质性的独立性及其相对效应大小均未得到明确测量。通过对来自两个不同种群的西方蜜蜂蜂王(Apis mellifera L.; n=3 对)进行控制繁殖,我们创造了遗传多样性低的近交蜂群、杂合度高的杂交蜂群以及杂合度低而社会多样性高的混合蜂群(结合来自每个种群的近交工蜂)。然后,我们对蜂群的两个独立性状进行了量化:抗细菌挑战的存活率和育雏巢温度的维持率。我们发现杂交群和混合群在这两个性状上的表现都优于近交群,但彼此间的表现并无差异。在免疫挑战试验中,杂交和混合群落与近交群落相比,危险比分别为 0.49(95% CI [0.37,0.65])和 0.69(95% CI [0.50,0.96])。在巢温方面,杂交种群和混交种群每小时的热误差分别为1.94±0.97°C和2.82±2.46°C,热变异分别为0.14±0.11°C2和0.16±0.06°C2。这表明社会异质性和个体异质性是独立运作的,可能具有相似的效应大小。这些结果突显了个体间和个体内多样性对适应性的重要性,这可能有助于解释群居昆虫多雄性/多雌性的出现,并为这些系统的育种工作提供参考。
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来源期刊
Journal of Heredity
Journal of Heredity 生物-遗传学
CiteScore
5.20
自引率
6.50%
发文量
63
审稿时长
6-12 weeks
期刊介绍: Over the last 100 years, the Journal of Heredity has established and maintained a tradition of scholarly excellence in the publication of genetics research. Virtually every major figure in the field has contributed to the journal. Established in 1903, Journal of Heredity covers organismal genetics across a wide range of disciplines and taxa. Articles include such rapidly advancing fields as conservation genetics of endangered species, population structure and phylogeography, molecular evolution and speciation, molecular genetics of disease resistance in plants and animals, genetic biodiversity and relevant computer programs.
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