Abstract
This study investigated both bacterial and fungal communities in corbicular pollen and hive-stored bee bread of two commercial honey bees, Apis mellifera and Apis cerana, in China. Although both honey bees favor different main floral sources, the dynamics of each microbial community is similar. During pH reduction in hive-stored bee bread, results from conventional culturable methods and next-generation sequencing showed a declining bacterial population but a stable fungal population. Different honey bee species and floral sources might not affect the core microbial community structure but could change the number of bacteria. Corbicular pollen was colonized by the Enterobacteriaceae bacterium (Escherichia-Shiga, Panteoa, Pseudomonas) group; however, the number of bacteria significantly decreased in hive-stored bee bread in less than 72 h. In contrast, Acinetobacter was highly abundant and could utilize protein sources. In terms of the fungal community, the genus Cladosporium remained abundant in both corbicular pollen and hive-stored bee bread. This filamentous fungus might encourage honey bees to reserve pollen by releasing organic acids. Furthermore, several filamentous fungi had the potential to inhibit both commensal/contaminant bacteria and the growth of pathogens. Filamentous fungi, in particular, the genus Cladosporium, could support pollen preservation of both honey bee species.
Highlights
Colony collapse disorder (CCD) has resulted in the decline of the honey bee population worldwide [1]
A 10-fold dilution was made from the suspension, and 200 μL of the diluted sample was spread onto potato dextrose agar (PDA) or nutrient agar (NA) to determine the number of fungal and bacterial colonies, respectively
PICRUSt 1.0.0 was used for the functional genomic analysis predictions of the bacteria associated with corbicular pollen and hive-stored bee bread based on the Silva 16S rRNA dataset
Summary
Colony collapse disorder (CCD) has resulted in the decline of the honey bee population worldwide [1]. Yeast species that have been identified in pollen and bee bread include Candida guilliermondii var. In 2014, a new perspective was presented concerning the microbial community associated with pollen and hive-stored bee bread [26]. This research only focused on the bacterial communities in new pollen and hive-stored bee bread but did not evaluate the role of associated fungal communities. We investigated the microbial community in A. mellifera and A. cerana in China Both the bacterial and fungal community structures in corbicular pollen and the hive-stored bee bread of each species were evaluated by conventional culture methods and high-throughput sequencing. Our results showed fungal isolation in the new pollen and hive-stored pollen that could suggest a possible interaction between the microorganisms present in the dietary sources of Apis bees
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