5 research outputs found
Invasive plants and water availability mediate outcomes of plant-pollinator interactions
Animal pollination occurs in more than three quarters of all flowering plants. These plant-pollinator interactions can be greatly affected by the environment. The increasing presence of invasive species and changes to abiotic conditions could change the outcomes of plant-pollinator interactions. This dissertation focused on identifying how invasive plants and changes to water availability influence seed production and pollinator-mediated selection. The first chapter demonstrated how water availability to pollen recipient plants (Phacelia parryi) as well as conspecific and heterospecific pollen (the invasive plant, Brassica nigra) donors interacted to influence seed production. In this experiment, water availability to recipient plants did not influenced seed production. High-water availability to conspecific pollen donors led to higher seed production. Water availability to heterospecific pollen donors set the context for how water given to conspecific donors and recipient plants impacted seed production. These results show the potential impacts that environmental heterogeneity has on post-pollination events that lead to seed production. The second chapter explored how water availability influences the shape of the relationship between seeds and pollen received. Water availability influenced the pollen-to-seed relationship and the degree to which seed production is limited by pollen quantity. Data for chapters one and two were collected through a series of hand-pollination experiments done in a pollinator-free greenhouse. The third chapter documented the impacts that the presence of an invasive plant (Linaria vulgaris) across years had on pollinator visitation and pollinator-mediated selection on floral traits in a native plant species (Penstemon strictus). This was done through a multi-year field experiment in Colorado, USA. The presence of Linaria increased pollinator visits to Penstemon. Both pollinator preferences and the relationship between pollinator visits and seed production changed across years. Together, this work documents two previously-unknown mechanisms on how seed production can be influenced by water to pollen donors and to a change in the pollen-to-seed relationship. This work also illustrates how year-to-year variation in plant-pollinator interactions and the presence of a plant invader affects pollinator visitation and pollinator-mediated phenotypic selection
Invasive plants and water availability mediate outcomes of plant-pollinator interactions
Animal pollination occurs in more than three quarters of all flowering plants. These plant-pollinator interactions can be greatly affected by the environment. The increasing presence of invasive species and changes to abiotic conditions could change the outcomes of plant-pollinator interactions. This dissertation focused on identifying how invasive plants and changes to water availability influence seed production and pollinator-mediated selection. The first chapter demonstrated how water availability to pollen recipient plants (Phacelia parryi) as well as conspecific and heterospecific pollen (the invasive plant, Brassica nigra) donors interacted to influence seed production. In this experiment, water availability to recipient plants did not influenced seed production. High-water availability to conspecific pollen donors led to higher seed production. Water availability to heterospecific pollen donors set the context for how water given to conspecific donors and recipient plants impacted seed production. These results show the potential impacts that environmental heterogeneity has on post-pollination events that lead to seed production. The second chapter explored how water availability influences the shape of the relationship between seeds and pollen received. Water availability influenced the pollen-to-seed relationship and the degree to which seed production is limited by pollen quantity. Data for chapters one and two were collected through a series of hand-pollination experiments done in a pollinator-free greenhouse. The third chapter documented the impacts that the presence of an invasive plant (Linaria vulgaris) across years had on pollinator visitation and pollinator-mediated selection on floral traits in a native plant species (Penstemon strictus). This was done through a multi-year field experiment in Colorado, USA. The presence of Linaria increased pollinator visits to Penstemon. Both pollinator preferences and the relationship between pollinator visits and seed production changed across years. Together, this work documents two previously-unknown mechanisms on how seed production can be influenced by water to pollen donors and to a change in the pollen-to-seed relationship. This work also illustrates how year-to-year variation in plant-pollinator interactions and the presence of a plant invader affects pollinator visitation and pollinator-mediated phenotypic selection
Pollination and Infection through the Lens of a Meta Analysis
Pollination is essential for crops and many other flowering species. Parasites of pollinators could influence the future of pollination and flowering plants. A meta-analysis is a useful strategy to detect patterns across different studies collecting data on a similar subject. I will present results from a meta-analysis to determine how pollination is affected by pollinators infected with parasites.The project’s data collection required keywords, finding, downloading, and reading research articles that discussed the impacts of parasites on insect pollinators. Data needed an infected insect pollinator, compared to an uninfected counterpart. Both entries must display the mean and standard error. Out of the literature papers downloaded, only 3.5 percent contained usable data. Over 1,000 different lines of data were extracted from the literature of 74 papers. The two most common insects were bees in the arthropod genera Apis and Bombus, which accounted for 23.5 percent of the study observations. The affected traits due to parasitization varied from behavioral, density, morphological, and physiological. Meta analysis determined that population density was the trait most impacted by parasitization, making up 53.5 percent of observations. Given the importance of pollinator populations for flowering plants, it is critical to measure the affected changes in pollinator population density. Our results predict that as the pollinator density is negatively affected by parasites, in turn, pollination will be affected, and therefore, important flowering plant species will be impacted. Furthermore, we found correlations that reinforce the importance of parasitism and its effects on flowering plant species
Monarchs, Milkweeds, Modeling: How Climate Change Will Affect Species Distribution in Florida
Monarch Butterflies (Danaus plexippus) are predicted to go quasi-extinct within the next 20 years. Pesticides, pathogens, habitat loss, and the effects of climate change are all driving this charismatic and formerly widespread species towards unsustainably low populations. Climate change is increasingly of concern in terms of Monarch conservation because it exacerbates other factors, particularly, habitat fragmentation and depletion of the Monarch’s host genus, the Asclepias. Monarchs are dependent on Asclepias, commonly known as Milkweeds, for their reproduction and success of multigenerational migrations. Monarch distribution is more limited by Asclepias distribution than by environmental factors; as such, understanding how Asclepias respond to climate change is an important element of Monarch conservation. How climate change will affect Asclepias and Monarch populations in Florida, a major Monarch migratory route, is not fully understood. To investigate this, I built a Species Distribution Model using the modeling program MaxEnt. By modeling the present and future distribution of introduced Asclepias curassavica, Florida natives A. tuberosa and A. perennis, and Monarchs within the state of Florida, I aimed to address how changing environmental conditions would affect the spatial distribution of Monarchs. Preliminary results indicate range reduction for Asclepias species, with the potential for local extinctions of A. currasavica and A. incarnata within Florida. Further analysis will explore questions as to which host plants will be used by future monarch populations and investigate trends in terms of the directionality of range change