Elijah C. Mehlferber scite author profile

The above-ground plant microbiome (the phyllosphere) is increasingly recognized as an important component of plant health. We hypothesized that phyllosphere interactions may be disrupted in a greenhouse setting, where microbial dispersal is limited, and that adding a microbial amendment might yield important benefits to the host plant. Using a newly developed synthetic phyllosphere microbiome for Tomato, we tested this hypothesis across multiple trials by manipulating microbial colonization of leaves and measuring subsequent plant growth and reproductive success, comparing results from plants grown in both greenhouse and field settings. We confirmed that greenhouse-grown plants have a depauperate phyllosphere microbiome and that the addition of the synthetic microbial community was responsible for a clear and repeatable increase in fruit production in this setting. We further show that this effect is synergistic with the addition of micronutrient-based soil amendments, with important implications for agriculture. These results suggest that greenhouse environments have poor phyllosphere microbiome establishment, with negative impacts on the plant. The results also implicate the phyllosphere microbiome as a key component of plant fitness, emphasizing that these communities have a clear role to play in the ecology and evolution of plant communities.

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Duplication and Sub/Neofunctionalization ofMalvolio, an Insect Homolog ofNramp, in the Subsocial BeetleNicrophorus vespilloides

Mehlferber

Benowitz

Roy-Zokan

et al. 2017

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With growing numbers of sequenced genomes, increasing numbers of duplicate genes are being uncovered. Here we examine Malvolio, a gene in the natural resistance-associated macrophage protein (Nramp) family, that has been duplicated in the subsocial beetle, Nicrophorus vespilloides, which exhibits advanced parental behavior. There is only one copy of Mvl in honey bees and Drosophila, whereas in vertebrates there are two copies that are subfunctionalized. We first compared amino acid sequences for Drosophila, beetles, mice, and humans. We found a high level of conservation between the different species, although there was greater variation in the C-terminal regions. A phylogenetic analysis across multiple insect orders suggested that Mvl has undergone several independent duplications. To examine the potential for different functions where it has been duplicated, we quantified expression levels of Mvl1 and Mvl2 in eight tissues in N. vespilloides. We found that while Mvl1 was expressed ubiquitously, albeit at varying levels, expression of Mvl2 was limited to brain and midgut. Because Mvl has been implicated in behavior, we examined expression during different behavioral states that reflected differences in opportunity for social interactions and expression of parental care behaviors. We found differing expression patterns for the two copies, with Mvl1 increasing in expression during resource preparation and feeding offspring, and Mvl2 decreasing in these same states. Given these patterns of expression, along with the protein analysis, we suggest that Mvl in N. vespilloides has experienced sub/neofunctionalization following its duplication, and may be evolving differing and tissue-specific roles in behavior and physiology.

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Elijah C. Mehlferber

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Duplication and Sub/Neofunctionalization ofMalvolio, an Insect Homolog ofNramp, in the Subsocial BeetleNicrophorus vespilloides

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