Microbial Community Structure among Honey Samples of Different Pollen Origin

Honey’s antibacterial activity has been recently linked to the inhibitory effects of honey microbiota against a range of foodborne and human pathogens. In the current study, the microbial community structure of honey samples exerting pronounced antimicrobial activity was examined. The honey samples were obtained from different geographical locations in Greece and had diverse pollen origin (fir, cotton, fir–oak, and <i>Arbutus unedo</i> honeys). Identification of honey microbiota was performed by high-throughput amplicon sequencing analysis, detecting 335 distinct taxa in the analyzed samples. Regarding ecological indices, the fir and cotton honeys possessed greater diversity than the fir–oak and <i>Arbutus unedo</i> ones. <i>Lactobacillus kunkeei</i> (basionym of <i>Apilactobacillus kun-keei</i>) was the predominant taxon in the fir honey examined. <i>Lactobacillus</i> spp. appeared to be favored in honey from fir-originated pollen and nectar since lactobacilli were more pronounced in fir compared to fir–oak honey. <i>Pseudomonas</i>, <i>Streptococcus</i>, <i>Lysobacter</i> and <i>Meiothermus</i> were the predominant taxa in cotton honey, whereas <i>Lonsdalea</i>, the causing agent of acute oak decline, and <i>Zymobacter</i>, an osmotolerant facultative anaerobic fermenter, were the dominant taxa in fir–oak honey. Moreover, methylotrophic bacteria represented 1.3–3% of the total relative abundance, independently of the geographical and pollen origin, indicating that methylotrophy plays an important role in honeybee ecology and functionality. A total of 14 taxa were identified in all examined honey samples, including bacilli/anoxybacilli, paracocci, lysobacters, pseudomonads, and sphingomonads. It is concluded that microbial constituents of the honey samples examined were native gut microbiota of melliferous bees and microbiota of their flowering plants, including both beneficial bacteria, such as potential probiotic strains, and animal and plant pathogens, e.g., <i>Staphylococcus</i> spp. and <i>Lonsdalea</i> spp. Further experimentation will elucidate aspects of potential application of microbial bioindicators in identifying the authenticity of honey and honeybee-derived products.