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Feresa Corazon Cabrera

Investigating the mechanisms of evolutionary innovation
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Multiscale interactions between plant part and a steep environmental gradient determine plant microbial composition in a tropical watershed

Journal article

Jared Bernard, C. B. Wall, Maria Costantini, Randi L. Rollins, Melissa L Atkins, Feresa P. Cabrera, Nicolas Cetraro, Christian K. J. Feliciano, Austin Greene, Philip K. Kitamura, Alejandro Olmedo-Velarde, Vithanage N. S. Sirimalwatta, Helen W. Sung, Leah Thompson, Huong T. Vu, Chad J Wilhite, A. Amend
bioRxiv, 2020
Semantic Scholar DOI
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APA   Click to copy
Bernard, J., Wall, C. B., Costantini, M., Rollins, R. L., Atkins, M. L., Cabrera, F. P., … Amend, A. (2020). Multiscale interactions between plant part and a steep environmental gradient determine plant microbial composition in a tropical watershed. BioRxiv.

Chicago/Turabian   Click to copy
Bernard, Jared, C. B. Wall, Maria Costantini, Randi L. Rollins, Melissa L Atkins, Feresa P. Cabrera, Nicolas Cetraro, et al. “Multiscale Interactions between Plant Part and a Steep Environmental Gradient Determine Plant Microbial Composition in a Tropical Watershed.” bioRxiv (2020).

MLA   Click to copy
Bernard, Jared, et al. “Multiscale Interactions between Plant Part and a Steep Environmental Gradient Determine Plant Microbial Composition in a Tropical Watershed.” BioRxiv, 2020.

BibTeX   Click to copy 

@article{jared2020a,
  title = {Multiscale interactions between plant part and a steep environmental gradient determine plant microbial composition in a tropical watershed},
  year = {2020},
  journal = {bioRxiv},
  author = {Bernard, Jared and Wall, C. B. and Costantini, Maria and Rollins, Randi L. and Atkins, Melissa L and Cabrera, Feresa P. and Cetraro, Nicolas and Feliciano, Christian K. J. and Greene, Austin and Kitamura, Philip K. and Olmedo-Velarde, Alejandro and Sirimalwatta, Vithanage N. S. and Sung, Helen W. and Thompson, Leah and Vu, Huong T. and Wilhite, Chad J and Amend, A.}
}

Abstract

Plant microbiomes are shaped by forces working at different spatial scales. Environmental factors determine a pool of potential symbionts while host physiochemical factors influence how those microbes associate with distinct plant tissues. Interactions between these scales, however, are seldom considered. Here we analyze epiphytic microbes from nine Hibiscus tiliaceus trees across a steep environmental gradient within a single Hawaiian watershed. At each location we sampled eight microhabitats: leaves, petioles, axils, stems, roots, and litter from the plant, as well as surrounding air and soil. While the composition of microbial communities is driven primarily by microhabitat, this variable predicted more than twice the compositional variance for bacteria compared to fungi. Fungal community compositional dissimilarity increased more rapidly along the gradient than did bacteria. Additionally, the spatial dynamics of fungal communities differed among plant parts, and these differences influenced the distribution patterns and range size of individual taxa. Within plants, microbes were compositionally nested such that aboveground communities contained a subset of the diversity found belowground. Our findings identify potential differences underlying the mechanisms shaping communities of fungi and bacteria associated with plants, and indicate an interaction between assembly mechanisms working simultaneously on different spatial scales.