Distinct pollinator communities persist among co-flowering specialty crops in Indiana

Eleanor Stroh; Ashley Leach; Zeus Mateos-Fierro; Ian Kaplan

doi:10.26786/1920-7603(2024)808

Authors

Eleanor Stroh Purdue University https://orcid.org/0009-0005-7269-2856
Ashley Leach
Zeus Mateos-Fierro https://orcid.org/0000-0002-6970-6533
Ian Kaplan https://orcid.org/0000-0003-4469-2750

DOI:

https://doi.org/10.26786/1920-7603(2024)808

Keywords:

bee communities, pan traps, pollinator diversity, wild bees, pollinator observations

Abstract

Diverse bee communities pollinate fruits and vegetables, and the composition of these communities has been described for many specialty crops in major production regions. However, pollinator communities in landscapes dominated by agronomic crops may differ in species composition and the contribution of wild bees. With over 4 million ha of maize and soybean, Indiana presents a novel landscape to compare pollinator communities among specialty crops that differ in their use of managed bees and bloom phenology, with potential implications for the composition of wild bee communities and their contributions to flower visitation. We sampled pollinator communities with flower observations and pan traps in spring-blooming apples and blueberries and summer-blooming tomatoes and watermelons, allowing us to compare communities between specialty crops with overlapping and distinct bloom times. Apples, blueberries, and watermelons were stocked with honey bees, and watermelons additionally had managed bumble bees. Across two years of sampling, we observed 1,651 flower visits by 13 taxa, collected 1,967 bees, and identified 84 taxa from collected specimens. Apples and blueberries hosted the richest pollinator communities (34 and 51 taxa, respectively) followed by watermelons (22 taxa), and tomatoes (19 taxa). While 70% of flower visits in apples and blueberries were attributed to honey bees, wild bees accounted for 82% and 99% of flower visits in watermelons and tomatoes, respectively. Our results indicate that distinct pollinator communities persist among co-flowering specialty crops in a landscape dominated by maize and soybean production and underscore the contribution of wild bees for specialty crop pollination, particularly in watermelons and tomatoes.

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