Your search keyword '"Michala L"' showing total 4 results

1. Differences in root phenology and water depletion by an invasive grass explains persistence in a Mediterranean ecosystem.

Author

Phillips, Michala L, McNellis, Brandon E, Allen, Michael F, and Allen, Edith B

Subjects

Poaceae, Rosaceae, chaparral, global change, invasion, roots, soil, water-use, Evolutionary Biology, Plant Biology, Ecology

Abstract

PREMISE:Flexible phenological responses of invasive plants under climate change may increase their ability to establish and persist. A key aspect of plant phenology is the timing of root production, how it coincides with canopy development and subsequent water-use. The timing of these events within species and across communities could influence the invasion process. We examined above- and belowground phenology of two species in southern California, the native shrub, Adenostoma fasciculatum, and the invasive perennial grass, Ehrharta calycina to investigate relative differences in phenology and water use. METHODS:We used normalized difference vegetation index (NDVI) to track whole-canopy activity across the landscape and sap flux sensors on individual chaparral shrubs to assess differences in aboveground phenology of both species. To determine differences in belowground activity, we used soil moisture sensors, minirhizotron imagery, and stable isotopes. RESULTS:The invasive grass depleted soil moisture earlier in the spring and produced longer roots at multiple depths earlier in the growing season than the native shrub. However, Adenostoma fasciculatum produced longer roots in the top 10 cm of soil profile in May. Aboveground activity of the two species peaked at the same time. CONCLUSIONS:The fact that Ehrharta calycina possessed longer roots earlier in the season suggests that invasive plants may gain a competitive edge over native plants through early activity, while also depleting soil moisture earlier in the season. Depletion of soil moisture earlier by E. calycina suggests that invasive grasses could accelerate the onset of the summer drought in chaparral systems, assuring their persistence following invasion.

Published

2019

2. Invasive grass density negatively impacts chaparral seedling establishment.

Author

Phillips, Michala L. and Allen, Edith B.

Subjects

*CHEATGRASS brome, *NATIVE species, *SEEDLINGS, *NATIVE plants, *SOIL moisture, *ANNUALS (Plants)

Abstract

Type conversion from native shrubland to invasive annual grassland is on the rise due to global change factors such as prolonged drought and increasing fire frequency. Efforts to restore chaparral ecosystems are limited by current understanding of competitive interactions between shrub seedlings and invasive grasses as well as soil moisture requirements of chaparral seedlings. We set up a restoration experiment where we out‐planted Adenostoma fasciculatum seedlings, manipulated invasive grass density, monitored soil moisture at two depths, and tracked seedling survival and biomass. We found that higher invasive grass cover was associated with higher rates of seedling mortality but found no difference in biomass per surviving plant. Soil moisture was higher at 15 cm under the 100% weeded treatment than the 50% weeded and control treatments during January. Lower invasive cover resulted in higher richness of annual native plant species, as plots with 100% invasive removal had higher richness than 50% removal and unplanted control plots. Future restoration efforts in the chaparral will likely be more successful in increasing initial seedling establishment if invasive grass removal is included. [ABSTRACT FROM AUTHOR]

Published

2024

3. Fungal community assembly in soils and roots under plant invasion and nitrogen deposition

Author

Emma L. Aronson, Lela V. Andrews, Michael F. Allen, S□ren E. Weber, Michala L. Phillips, and Edith B. Allen

Subjects

0106 biological sciences, Plant invasion, Introduced species, Plant Science, Nitrogen deposition, Microbiology, 010603 evolutionary biology, 01 natural sciences, Soil, Glomeraceae, Abundance (ecology), AMF, Mycorrhizae, Ecosystem, Community ecology, Life Below Water, Global change, Relative species abundance, Ecology, Evolution, Behavior and Systematics, geography, California chaparral, geography.geographical_feature_category, Ecology, biology, Community assembly, Ecological Modeling, fungi, Fungi, Biological Sciences, biology.organism_classification, Chaparral, Soil water, Species richness, Environmental Sciences, 010606 plant biology & botany, Gigasporaceae

Abstract

Abstract Fungal community composition in the Anthropocene is driven by rapid changes in environmental conditions caused by human activities. This study examines the relative importance of two global change drivers – atmospheric nitrogen (N) deposition and annual grass invasion – on structuring fungal communities in a California chaparral ecosystem, with emphasis on arbuscular mycorrhizal fungi. We used molecular markers, functional groupings, generalized linear statistics and joint distribution modeling, to examine how environmental variables structure taxonomic and functional composition of fungal communities. Invasion of a chaparral ecosystem decreased richness and relative abundance of non-AMF symbionts and rhizophilic AMF (e.g. Glomeraceae) as well as the proportion of edaphophilic AMF (e.g. Gigasporaceae). We found increased richness and the proportion of rhizophilic and edaphophilic AMF with increasing soil NO3. Our findings suggest that invasive persistence may decrease the presence of multiple soil symbionts that native species depend on for pathogen protection and increased access to soil resources.

Published

2019

4. Differences in root phenology and water depletion by an invasive grass explains persistence in a Mediterranean ecosystem

Author

Michael F. Allen, Brandon E. McNellis, Edith B. Allen, and Michala L. Phillips

Subjects

0106 biological sciences, roots, chaparral, ved/biology.organism_classification_rank.species, Growing season, Plant Biology, Plant Science, Poaceae, 010603 evolutionary biology, 01 natural sciences, Shrub, California, soil, Soil, Genetics, Adenostoma, Rosaceae, Ecology, Evolution, Behavior and Systematics, Ecosystem, global change, geography, Evolutionary Biology, geography.geographical_feature_category, biology, Ecology, ved/biology, Phenology, Water, food and beverages, Native plant, biology.organism_classification, Chaparral, invasion, Ehrharta calycina, Calycina, Droughts, Agronomy, water-use, Seasons, 010606 plant biology & botany

Abstract

Author(s): Phillips, Michala L; McNellis, Brandon E; Allen, Michael F; Allen, Edith B | Abstract: PREMISE:Flexible phenological responses of invasive plants under climate change may increase their ability to establish and persist. A key aspect of plant phenology is the timing of root production, how it coincides with canopy development and subsequent water-use. The timing of these events within species and across communities could influence the invasion process. We examined above- and belowground phenology of two species in southern California, the native shrub, Adenostoma fasciculatum, and the invasive perennial grass, Ehrharta calycina to investigate relative differences in phenology and water use. METHODS:We used normalized difference vegetation index (NDVI) to track whole-canopy activity across the landscape and sap flux sensors on individual chaparral shrubs to assess differences in aboveground phenology of both species. To determine differences in belowground activity, we used soil moisture sensors, minirhizotron imagery, and stable isotopes. RESULTS:The invasive grass depleted soil moisture earlier in the spring and produced longer roots at multiple depths earlier in the growing season than the native shrub. However, Adenostoma fasciculatum produced longer roots in the top 10 cm of soil profile in May. Aboveground activity of the two species peaked at the same time. CONCLUSIONS:The fact that Ehrharta calycina possessed longer roots earlier in the season suggests that invasive plants may gain a competitive edge over native plants through early activity, while also depleting soil moisture earlier in the season. Depletion of soil moisture earlier by E. calycina suggests that invasive grasses could accelerate the onset of the summer drought in chaparral systems, assuring their persistence following invasion.

Published

2019