Water into nectar: the effects of seasonal drought on bumble bee and flowering plant communities

Simon, Andrew D. F.

16 June 2020

Habitat loss and climate change are major factors implicated in the decline of bumble bees worldwide. These factors may be particularly acute in regions subject to climatic extremes such as seasonal drought. Combining methods from pollinator research and phylogenetic community ecology, I investigated the impacts of seasonal drought on plant phenology and bumble bee community ecology across gradients of disturbance and soil moisture in a semi-arid ecosystem. Seasonal fluctuations in floral resources coincided with significant phylogenetic clustering in plant communities, with decreasing plant diversity observed under conditions of increasing drought stress. In the late season, modified wet areas supported higher floral resource availability and greater bumble bee abundances as compared to dry woodlands, though wetlands were also an important source of late season floral resources. Despite these local effects, however, the areal extent of natural vs modified matrix habitat accounted for the majority of variation in models explaining bumble bee abundances. Modified matrix habitat was negatively associated, and natural matrix habitat positively associated, with the occurrence of bumble bee workers in June and late-flying queens in July and August. Results provide insight into the temporal niche dynamics of entomophilous flowering plants in this system, and emphasize the importance of conserving natural habitat diversity in efforts to promote resilient plant-pollinator communities. This study also provides evidence for the local extinction of Bombus occidentalis Greene, 1858 and Bombus suckleyi Greene, 1860 from Galiano Island, BC, Canada, as well as the island’s recent colonization by Bombus vosnesenskii Radoszkowski, 1862. / Graduate

seasonal drought

ecology

bumble bee

phylogenetic community ecology

pollinator ecology

phenology

Using historical records to explore long-term trends in bumble bee ecology

Hannah Grace Kernen (20323485)

07 December 2024

<p dir="ltr">Bumble bees are crucial pollinators of many natural and agricultural systems. Their recent declines, in the Midwestern United States and beyond, have been marked by notable shifts in phenological patterns, as well as spatial extent. Bumble bees have suffered from diverse stressors, such as climate change, habitat loss, pathogens and pesticides. Preserved specimens can be a valuable way of capturing long-term ecological changes; their associated data can be used to glean information on species’ distribution, nutrition, and even genetics. Bumble bees, in particular, are strong candidates for specimen-based research, as large, charismatic insects that are often over-represented in museum collections. I used preserved specimens from over 35 unique sources to study ecological changes in nine common Indiana bumble bee species from the early 1900s until present. Using quantile regression, I tracked shifts in phenology by estimating the rate of change for the onset, mid, and end dates of the bumble bee flight period throughout history. I found that for most species, the mid and end dates of activity have significantly advanced over time, while flight onset has delayed. While the onset delay was unexpected, this trend could suggest major reductions in flight activity for many important bumble bee species. Next, I created two occupancy models to estimate the effects of crop richness and temperature of county-level bumble bee occupancy. I found that for most species, the probability of occupancy increased over time, however most species responded negatively to increased temperatures. Crop richness did not have a significant effect on occupancy. With future climate warming, some bumble bee species are likely to perform better than others in Indiana, which could lead to significant restructuring in pollinator communities. Bumble bees have gone through major ecological change in the past century, with more changes certainly to come. With declines already in motion in the Midwest and beyond, it is crucial to continue monitoring our pollinators if we are to understand how to best conserve their populations.</p>

Ecology not elsewhere classified

Invertebrate biology

pollinator ecology

Bombus

Museum collections

phenology

occupancy modelling

Cocoa pollination as a potential yield driver under changing management and climate

Toledo-Hernández, Manuel

13 February 2020

No description available.

630

cocoa

farmer income

yield

Indonesia

climate change

sustainability

pollination services

agroforestry systems

pollinator ecology

Land- und Forstwirtschaft (PPN621302791)