More flowers and pollinator diversity could help protect bees from parasites


Bee on a clover flower

Having more flowers and maintaining diverse bee communities could help reduce the spread of bee parasites, according to a new study.

The research, conducted on more than 5,000 flowers and bees, reveals how bee parasites spread and what measures could help control them.

Bees can be infected with a cocktail of parasites that can cause a range of symptoms from reduced foraging ability to dysentery and death. Though parasites contribute to bee declines, scientists are unsure how they spread between bee species.

It’s a little like if subway cars are sites of transmission between humans – if there are more subway cars, there are less people in each and less chance for transmission. Dr Peter Graystock

Flowers are essential for bee health, but may also act as transmission hubs for bee diseases. Over a growing season the diversity and abundance of bees and flowers change but little is known about how this may be linked to the risk of parasite transmission.

The new study, published today in Nature Ecology and Evolution, suggests having more flowers and a more diverse bee community could help dilute the load of parasites, and that this may be particularly important in areas with high densities of social bees, such as honeybees and bumblebees.

Most studies of bee parasites focus on social bee species that often live in farmed colonies. Little is therefore known about the interactions between parasites and wild solitary bee species, or how parasites are transferred between them. The team behind the new paper studied how parasites are spread across diverse bee and flower communities, including solitary bee species.

More flowers and diverse bee species

Lead author Dr Peter Graystock, who completed the work at Cornell University and now works in the Department of Life Sciences at Imperial College London, said: “We found that when bee communities are at their most diverse, the proportion of infected bees were at their lowest; and when flowers were at their most abundant, fewer were likely to be acting as transmission hubs.

Bee on a flower“There are two things potentially occurring here. In diverse bee communities, parasites are more likely to end up in a species they are not compatible with, meaning they can’t replicate and spread further. The second thing is by having more flowers, bees aren’t all visiting and contaminating the same few flowers with high concentrations of parasites.

“It’s a little like if subway cars are sites of transmission between humans – if there are more subway cars, there are less people in each and less chance for transmission. Furthermore if some of the ‘people’ riding the subway cars were different animal species that were not susceptible to the parasite, that too reduces the risk of transmission.”

The team screened more than 5,000 wildflowers and bees across a 24-week growing season, capturing changes as different flowers bloomed and different species of bee dominated.

Over 110 bee species and 89 flower species were screened, revealing 42% of bee species (12.2% individual bees) and 70% of flower species (8.7% individual flowers) had at least one parasite in or on them.

Bees had the highest prevalence of parasites late in the season, when social bees formed the majority of screened bees and overall bee diversity was lowest. This suggests keeping bee diversity high, with a variety of social and solitary species present, could help reduce the spread of parasites.

Since social bees are likely to come from farmed colonies, the researchers also say their research points to the importance of keeping hives healthy, to avoid infecting wild bees.

Favourite flowers

The study is the first time researchers have screened wildflowers and bees for parasites over the season, and as well as the abundance of flowers affecting transmission, the team also found that the species of flowers played a role.

For example, the species Lychnis flos-cuculi, commonly known as ‘ragged robin’, often had multiple parasite species on them, whereas Lythrum salicaria, or ‘purple loosestrife’ had few.

Dr Graystock added: “The power of this study is the number of bees and flowers screened over time, allowing us to see if the patterns fit with parasite transmission theory. We next want to dig deeper and understand some of the underlying mechanisms – such as why some flowers are more likely to harbour parasites than others.”

The work was funded by the National Institute of General Medical Sciences of the National Institutes of Health in the US.


Dominant bee species and floral abundance drive parasite temporal dynamics in plant-pollinator communities’ by Peter Graystock, Wee Hao Ng, Kyle Parks, Amber D. Tripodi, Paige A. Muñiz, Ashley A. Fersch, Christopher R. Myers, Quinn S. McFrederick and Scott H. McArt is published in Nature Ecology and Evolution.


Hayley Dunning

Hayley Dunning
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