More Like this

1. Hydroperiod and Salinity Interactions Control Mangrove Root Dynamics in a Karstic Oceanic Island in the Caribbean Sea (San Andres, Colombia)

   https://doi.org/10.3389/fmars.2020.598132  

   Medina-Calderón, Jairo Humberto ; Mancera-Pineda, José Ernesto ; Castañeda-Moya, Edward ; Rivera-Monroy, Víctor H. ( January 2021 , Frontiers in Marine Science)

   null (Ed.)

   Mangroves sustain high soil accretion and carbon sequestration rates, yet it is still unknown if they can keep pace with increasing sea level rise (SLR) across a wider range of coastal geomorphic settings. Because accretion rates are controlled by mineral sediment inputs and organic matter accumulation, it is paramount to assess the relative contribution of root productivity to soil formation. Here, we evaluated root biomass, production, and turnover in three mangrove ecotypes to evaluate the role of soil nutrient limitation, stressors, and hydroperiod in controlling root dynamics in San Andres Island (SAI), a karstic oceanic island in the Caribbean Sea. Root production was modulated by soil stress conditions and not by nutrient availability as it has been reported for other karstic environments. The lowest root biomass allocation, and both production and turnover of fine roots were measured under low flooding duration, and low salinity (<20 PSU) and sulfide concentrations (0.84 ± 0.4 mM). Yet, when soil stress conditions increased during high flooding duration (6207 h y –1 ) and low oxygen conditions (Eh), root tissues reached the highest biomass and production values, including a relative fast turnover of fine roots (<2 mm; 0.75 y –1 ). Our results follow the predictions of the plant root longevity cost-benefit hypothesis where plants maintain roots only until the efficiency of resource acquisition is maximized by water and nutrient acquisition. Because of the importance of groundwater in controlling porewater salinity and mangrove root productivity in karstic oceanic islands such as SAI, water use and coastal development should be regulated in the short term to avoid the loss of mangrove area and concomitant ecosystem services. 

   more » « less
2. Salinity Impacts the Functional mcrA and dsrA Gene Abundances in Everglades Marshes

   https://doi.org/10.3390/microorganisms11051180  

   Jordan, Deidra S. ; Kominoski, John ; Servais, Shelby ; Mills, DeEtta ( May 2023 , Microorganisms)

   Coastal wetlands, such as the Everglades, are increasingly being exposed to stressors that have the potential to modify their existing ecological processes because of global climate change. Their soil microbiomes include a population of organisms important for biogeochemical cycling, but continual stresses can disturb the community’s composition, causing functional changes. The Everglades feature wetlands with varied salinity levels, implying that they contain microbial communities with a variety of salt tolerances and microbial functions. Therefore, tracking the effects of stresses on these populations in freshwater and brackish marshes is critical. The study addressed this by utilizing next generation sequencing (NGS) to construct a baseline soil microbial community. The carbon and sulfur cycles were studied by sequencing a microbial functional gene involved in each process, the mcrA and dsrA functional genes, respectively. Saline was introduced over two years to observe the taxonomic alterations that occurred after a long-term disturbance such as seawater intrusion. It was observed that saltwater dosing increased sulfite reduction in freshwater peat soils and decreased methylotrophy in brackish peat soils. These findings add to the understanding of microbiomes by demonstrating how changes in soil qualities impact communities both before and after a disturbance such as saltwater intrusion. 

   more » « less
3. Culturable fungal endophyte communities of primary successional plants on Mount St. Helens, WA, USA

   https://doi.org/10.1186/s12862-022-01974-2  

   Wolfe, Emily R. ; Dove, Robyn ; Webster, Cassandra ; Ballhorn, Daniel J. ( February 2022 , BMC Ecology and Evolution)

   While a considerable amount of research has explored plant community composition in primary successional systems, little is known about the microbial communities inhabiting these pioneer plant species. Fungal endophytes are ubiquitous within plants, and may play major roles in early successional ecosystems. Specifically, endophytes have been shown to affect successional processes, as well as alter host stress tolerance and litter decomposition dynamics—both of which are important components in harsh environments where soil organic matter is still scarce.

   To determine possible contributions of fungal endophytes to plant colonization patterns, we surveyed six of the most common woody species on the Pumice Plain of Mount St. Helens (WA, USA; Lawetlat'la in the Cowlitz language; created during the 1980 eruption)—a model primary successional ecosystem—and found low colonization rates (< 15%), low species richness, and low diversity. Furthermore, while endophyte community composition did differ among woody species, we found only marginal evidence of temporal changes in community composition over a single field season (July–September).

   Our results indicate that even after a post-eruption period of 40 years, foliar endophyte communities still seem to be in the early stages of community development, and that the dominant pioneer riparian species Sitka alder (Alnus viridisssp.sinuata) and Sitka willow (Salix sitchensis) may be serving as important microbial reservoirs for incoming plant colonizers.

    

   more » « less
4. Foliar endophytic fungi alter patterns of nitrogen uptake and distribution in Theobroma cacao

   https://doi.org/10.1111/nph.15693  

   Christian, Natalie ; Herre, Edward Allen ; Clay, Keith ( February 2019 , New Phytologist)

   Colonization by foliar endophytic fungi can affect the expression of host plant defenses and other ecologically important traits. However, whether endophyte colonization affects the uptake or redistribution of resources within and among host plant tissues remains unstudied.

   We inoculated leaves ofTheobroma cacaowith four common colonizers that range in their effect from protective to pathogenic (Colletotrichum tropicale,Pestalotiopsissp.,Colletotrichum theobromicola, orPhytophthora palmivora). We pulsed the soil with nitrogen‐15 (¹⁵N) and then traced¹⁵N uptake and its subsequent distribution to whole plants and individual leaves.

   At a whole‐plant level,C. tropicale‐inoculated plants showed significantly greater¹⁵N uptake than endophyte‐free plants did in the same pot. Among leaves within plants, younger leaves were particularly enriched in¹⁵N, but endophyte inoculation at the individual leaf level did not alter¹⁵N distribution within plants. However, leaves co‐inoculated with pathogenicPhytophthoraand protectiveC. tropicaleexperienced significantly elevated¹⁵N content as pathogen damage increased, compared with leaves inoculated only with the pathogen. Further, endophyte–pathogen co‐infection also increased total plant biomass.

   Our results indicate that colonization by foliar endophytes significantly affects N uptake and distribution among and within host plants in ways that appear to be context dependent on other microbiome components.

    

   more » « less
5. Species diversity of fungal endophytes across a stress gradient for plants

   https://doi.org/10.1111/nph.16709  

   Oono, Ryoko ; Black, Danielle ; Slessarev, Eric ; Sickler, Burton ; Strom, Amanda ; Apigo, Austen ( July 2020 , New Phytologist)

   Foliar fungal endophytes are one of the most diverse guilds of symbiotic fungi found in the photosynthetic tissues of every plant lineage, but it is unclear how plant environments and leaf resource availability shape their diversity.

   We explored correlations between leaf nutrient availability and endophyte diversity amongPinus muricataandVaccinium ovatumplants growing across a soil nutrient gradient spanning a series of coastal terraces in Mendocino, California.

   Endophyte richness decreased in plants with higher leaf nitrogen‐to‐phosphorus ratios for both host species, but increased with sodium, which may be toxic to fungi at high concentrations. Isolation frequency, a proxy of fungal biomass, was not significantly predicted by any of the same leaf constituents in the two plant species.

   We propose that stressed plants can exhibit both low foliar nutrients or high levels of toxic compounds, and that both of these stress responses predict endophyte species richness. Stressful conditions that limit growth of fungi may increase their diversity due to the suppression of otherwise dominating species. Differences between the host species in their endophyte communities may be explained by host specificity, leaf phenology, or microclimates.

    

   more » « less