Your search keyword '"Ashman, Tia‐Lynn"' showing total 9 results

1. Learning to handle flowers increases pollen collection benefits for bees but does not affect pollination success for plants

Author

Mayberry, Maggie M, primary, Naumer, Katherine C, additional, Novinger, Annaliese N., additional, McCart, Dalton M, additional, Wilkins, Rachel V, additional, Muse, Haley, additional, Ashman, Tia-Lynn, additional, and Russell, Avery L, additional

Published

2024

2. Hyperaccumulation of nickel but not selenium drives floral microbiome differentiation: A study with six species of Brassicaceae.

Author

Cullen, Nevin P. and Ashman, Tia‐Lynn

Subjects

*COMPOSITION of flowers, *PLANT populations, *SELENIUM, *NICKEL, *GEOGRAPHY

Abstract

Premise Methods Results Conclusions Intraspecific variation in flower microbiome composition can mediate pollination and reproduction, and so understanding the community assembly processes driving this variation is critical. Yet the relative importance of trait‐based host filtering and dispersal in shaping among‐species variation in floral microbiomes remains unknown.Within two clades of Brassicaceae, we compared diversity and composition of floral microbiomes in natural populations of focal nickel and selenium hyperaccumulator species and two of their non‐accumulating relatives. We assessed the relative strengths of floral elemental composition, plant phylogenetic distance (host filtering), and geography (dispersal) in driving floral microbiome composition.Species in the nickel hyperaccumulator clade had strongly divergent floral microbiomes, the most of that variation driven by floral elemental composition, followed by geographic distance between plant populations and, lastly, phylogenetic distance. Conversely, within the selenium hyperaccumulator clade, floral microbiome divergence was much lower among the species and elemental composition, geography, and plant phylogeny were far weaker determinants of microbiome variation.Our results show that the strength of elemental hyperaccumulation's effect on floral microbiomes differs substantially among plant clades, possibly due to variation in elements as selective filters or in long‐distance dispersal probability in different habitats. [ABSTRACT FROM AUTHOR]

Published

2024

3. Neopolyploidy‐induced changes in giant duckweed (Spirodela polyrhiza) alter herbivore preference and performance and plant population performance.

Author

Assour, Hannah R., Ashman, Tia‐Lynn, and Turcotte, Martin M.

Subjects

*PLANT performance, *RHOPALOSIPHUM, *POLYPLOIDY, *HOST plants, *PLANT populations

Abstract

Premise: Polyploidy is a widespread mutational process in angiosperms that may alter population performance of not only plants but also their interacting species. Yet, knowledge of whether polyploidy affects plant–herbivore dynamics is scarce. Here, we tested whether aphid herbivores exhibit preference for diploid or neopolyploid plants, whether polyploidy impacts plant and herbivore performance, and whether these interactions depend on the plant genetic background. Methods: Using independently synthesized neotetraploid strains paired with their diploid progenitors of greater duckweed (Spirodela polyrhiza), we evaluated the effect of neopolyploidy on duckweed's interaction with the water‐lily aphid (Rhopalosiphum nymphaeae). Using paired‐choice experiments, we evaluated feeding preference of the herbivore. We then evaluated the consequences of polyploidy on aphid and plant performance by measuring population growth over multiple generations. Results: Aphids preferred neopolyploids when plants were provided at equal abundances but not at equal surface areas, suggesting the role of plant population surface area in driving this preference. Additionally, neopolyploidy increased aphid population performance, but this result was dependent on the plant's genetic lineage. Lastly, the impact of herbivory on neopolyploid vs. diploid duckweed varied greatly with genetic lineage, where neopolyploids appeared to be variably tolerant compared to diploids, sometimes mirroring the effect on herbivore performance. Conclusions: By experimentally testing the impacts of polyploidy on trophic species interactions, we showed that polyploidization can impact the preference and performance of herbivores on their plant hosts. These results have significant implications for the establishment and persistence of plants and herbivores in the face of plant polyploidy. [ABSTRACT FROM AUTHOR]

Published

2024

4. Neopolyploidy has variable effects on the diversity and composition of the wild strawberry microbiome.

Author

Anneberg, Thomas J., Cullen, Nevin P., O'Neill, Elizabeth M., Wei, Na, and Ashman, Tia‐Lynn

Subjects

BACTERIAL diversity, MICROBIAL communities, COMPOSITION of leaves, PHENOTYPES, BACTERIAL communities

Abstract

Premise: Whole‐genome duplication (neopolyploidy) can instantly differentiate the phenotype of neopolyploids from their diploid progenitors. These phenotypic shifts in organs such as roots and leaves could also differentiate the way neopolyploids interact with microbial species. While some studies have addressed how specific microbial interactions are affected by neopolyploidy, we lack an understanding of how genome duplication affects the diversity and composition of microbial communities. Methods: We performed a common garden experiment with multiple clones of artificially synthesized autotetraploids and their ancestral diploids, derived from 13 genotypes of wild strawberry, Fragaria vesca. We sequenced epiphytic bacteria and fungi from roots and leaves and characterized microbial communities and leaf functional traits. Results: Autotetraploidy had no effect on bacterial alpha diversity of either organ, but it did have a genotype‐dependent effect on the diversity of fungi on leaves. In contrast, autotetraploidy restructured the community composition of leaf bacteria and had a genotype‐dependent effect on fungal community composition in both organs. The most differentially abundant bacterial taxon on leaves belonged to the Sphingomonas, while a member of the Trichoderma was the most differentially abundant fungal taxon on roots. Ploidy‐induced change in leaf size was strongly correlated with a change in bacterial but not fungal leaf communities. Conclusions: Genome duplication can immediately alter aspects of the plant microbiome, but this effect varies by host genotype and bacterial and fungal community. Expanding these studies to wild settings where plants are exposed continuously to microbes are needed to confirm the patterns observed here. [ABSTRACT FROM AUTHOR]

Published

2024

5. Neopolyploidy increases stress tolerance and reduces fitness plasticity across multiple urban pollutants: support for the “general-purpose” genotype hypothesis

Author

Turcotte, Martin M, primary, Kaufmann, Nancy, additional, Wagner, Katie L, additional, Zallek, Taylor A, additional, and Ashman, Tia-Lynn, additional

Published

2024

6. Evaluating the influences of floral traits and pollinator generalism on α and β diversity of heterospecific pollen on stigmas.

Author

Ashman, Tia‐Lynn and Wei, Na

Subjects

*POLLINATION, *POLLINATORS, *PLANT species diversity, *POLLEN, *STRUCTURAL equation modeling, *FLOWERING of plants, *PLANT evolution

Abstract

Pollinator sharing often leads to receipt of heterospecific pollen (HP) along with conspecific pollen. As a result, flowering plants can accumulate diverse communities of HP on stigmas. While variation in HP diversity is an important selective force contributing to flowering plant fitness, evolution and community assembly, our understanding of the extent and drivers of heterogeneity of HP diversity is limited.In this study, we examined the species compositions and abundances of ~1000 HP communities across 59 co‐flowering plant species in three serpentine seep communities in California, USA. We evaluated the variation in HP diversity (γ diversity) across plant species in each seep and asked whether the variation in HP γ diversity was caused by variation in HP diversity within stigmas (α diversity) or HP compositional variation among stigmas (β diversity) due to the replacement of HP species (turnover) or their loss (nestedness) from one stigma to another. We further evaluated the potential drivers of variation in HP α and β diversity using phylogenetic structural equation models.We found that variation in HP γ diversity across plant species was driven strongly by differences among species in HP α diversity and to a lesser extent by HP β diversity. HP community turnover contributed more to HP β diversity than nestedness consistently across plant species and seeps, suggesting a general pattern of HP compositional heterogeneity from stigma to stigma. The phylogenetic structural equation models further revealed that floral traits (e.g., stigma area, stigma‐anther distance, stigma exposure) and floral abundance were key in determining HP α diversity by influencing HP abundance (load size), while floral traits and abundance showed variable impact on HP β diversity (turnover and nestedness). Pollination generalism contributed relatively less to HP‐α and β diversity.These findings disentangle the heterogeneity in HP diversity at different levels, which is essential for understanding the process underlying patterns of HP receipt in plant communities. That floral traits drive the heterogeneity in HP diversity points to additional avenues by which HP receipt may contribute to plant evolution. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2024

7. The Effect of Polyploidy and Mating System on Floral Size and the Pollination Niche in Brassicaceae.

Author

Streher, Nathália Susin, Budinsky, Trezalka, Halabi, Keren, Mayrose, Itay, and Ashman, Tia-Lynn

Subjects

POLLINATION, POLYPLOIDY, BOTANICAL specimens, PLOIDY, POLLEN

Abstract

Premise of research. Polyploidy, a major evolutionary process in flowering plants, is expected to impact floral traits, which can have cascading effects on pollination interactions, but this may depend on selfing propensity. In a novel use of herbarium specimens, we assessed the effects of polyploidy and mating system on floral traits and the pollination niche of 40 Brassicaceae species. Methodology. We combined data on mating system (self-compatible or self-incompatible) with inferred ploidy level (polyploid or diploid) and used phylogenetically controlled analyses to investigate their influence on floral traits (size and shape) and the degree of pollination generalism based on the frequency and the richness of heterospecific pollen morphospecies captured by stigmas. Pivotal results. Flower size (but not shape) depended on the interaction between ploidy and mating system. Self-incompatible polyploid species had larger flowers than self-incompatible diploids, but there was no difference for self-compatible species. The breadth of pollination niche (degree of generalism) was not affected by ploidy but was rather strongly affected by mating system only. Self-incompatible species had more stigmas with heterospecific pollen and higher heterospecific pollen morphospecies richness per stigma than self-compatible species, regardless of their ploidy. Conclusions. Our results demonstrate that mating system moderated the influence of ploidy on morphological features associated with pollination generalism but that response in terms of heterospecific pollen captured as a proxy of pollination generalism was more variable. [ABSTRACT FROM AUTHOR]

Published

2024

8. Genomic data provides insights into the evolutionary history and adaptive differentiation of two tetraploid strawberries

Author

Lin, Hanyang, Chen, Luxi, Cai, Chaonan, Ma, Junxia, Li, Junmin, Ashman, Tia-Lynn, Liston, Aaron, and Dong, Ming

Abstract

Over the decades, evolutionists and ecologists have shown intense interest in the role of polyploidization in plant evolution. Without clear knowledge of the diploid ancestor(s) of polyploids, we would not be able to answer fundamental ecological questions such as the evolution of niche differences between them or its underlying genetic basis. Here, we explored the evolutionary history of two Fragariatetraploids, Fragaria corymbosaand Fragaria moupinensis. We de novoassembled five genomes including these two tetraploids and three diploid relatives. Based on multiple lines of evidence, we found no evidence of subgenomes in either of the two tetraploids, suggesting autopolyploid origins. We determined that Fragaria chinensiswas the diploid ancestor of F. corymbosawhile either an extinct species affinitive to F. chinensisor an unsampled population of F. chinensiscould be the progenitor of F. moupinensis. Meanwhile, we found introgression signals between F. chinensisand Fragaria pentaphylla, leading to the genomic similarity between these two diploids. Compared to F. chinensis, gene families related to high ultraviolet (UV)-B and DNA repair were expanded, while those that responded towards abiotic and biotic stresses (such as salt stress, wounding, and various pathogens) were contracted in both tetraploids. Furthermore, the two tetraploids tended to down-regulate defense response genes but up-regulate UV-B response, DNA repairing, and cell division gene expression compared to F. chinensis. These findings may reflect adaptions toward high-altitude habitats. In summary, our work provides insights into the genome evolution of wild Fragariatetraploids and opens up an avenue for future works to answer deeper evolutionary and ecological questions regarding the strawberry genus.

Published

2024

9. Co-flowering richness has variable effects on pollen quantity and quality limitation in four Clarkia species.

Author

Albor C, Eisen K, Moore E, Geber M, Ashman TL, Raguso RA, and Arceo-Gomez G

Abstract

Background and Aims: Pollination failure occurs from insufficient pollen quantity or quality. However, the relative contributions of pollen quantity vs quality to overall pollen limitation, and how this is affected by the co-flowering context, remain unknown for most plant populations. Here, we studied patterns of pollen deposition and pollen tube formation across populations of four predominately outcrossing species in the genus Clarkia to evaluate how richness of co-flowering congeners affects the contribution of pollen quantity and quality to pollen limitation., Methods: We partition variation in pollen deposition and pollen tube production across individuals, populations and species to identify the main sources of variation in components of reproductive success. We further quantify the relative contribution of pollen quantity and quality limitation to the reproductive success of the four Clarkia species using piecewise regression analyses. Finally, we evaluate how variation in the number of co-flowering Clarkia species in the community affects the strength of pollen quality and quality limitation., Results: Across all contexts, pollen deposition and the proportion of pollen tubes produced varied greatly among individuals, populations, and species, and these were not always correlated. For instance, C. xantiana received the smallest pollen loads yet produced the highest proportion of pollen tubes, while C. speciosa exhibited the opposite pattern. Yet, co-flowering richness had variable effects on the strength of pollen quantity and quality limitation among populations. Specifically, breakpoint values, which are an indicator of overall pollen limitation, were two times larger in the four-species community compared with one and two-species communities for two Clarkia species, suggesting that pollen limitation can increase with increasing richness of co-flowering congeners., Conclusions: Our results reveal a complex interplay between quantity and quality of pollen limitation and co-flowering context that may have different evolutionary outcomes across species and populations., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024