Your search keyword '"plant performance"' showing total 8 results

1. Competition rather than facilitation affects plant performance across an abiotic stress gradient in a restored California salt marsh.

Author

Tanner, Karen E., Wasson, Kerstin, and Parker, Ingrid M.

Subjects

*PLANT performance, *ABIOTIC stress, *COMPETITION (Biology), *LOTKA-Volterra equations, *SALT marshes, *SOIL moisture, *GROUND cover plants

Abstract

The Stress Gradient Hypothesis predicts facilitation will become more important than competition where abiotic stress is high, and the framework successfully predicts positive interactions between species in many systems. Fewer studies have focused on intraspecific facilitation, and to our knowledge none examine intraspecific interactions in Pacific Coast salt marshes of North America. We used two species that tend to occur in large, monospecific patches to test for intraspecific facilitation in a restored California marsh, where tides and evaporation during summer create moisture and salinity gradients across elevation. We tested performance of Frankenia salina or Jaumea carnosa in restoration plots using two treatments: clustered plantings to promote facilitation, and widely spaced plantings to limit interaction between individuals. We characterized the soil water potential gradient and measured plant survival, cover, physiology, and susceptibility to herbivory across elevation and planting treatments. Soil water potential declined sharply with elevation, suggesting plant stress should be higher upslope. However, tissue water potential was unaffected by elevation, and survival was high—suggesting growing conditions remained benign. A seawater addition treatment did not alter the response of plants or plant interactions to the abiotic gradient. At 19 months, intraspecific competition prevailed across the entire elevation gradient for both species, with less transplant cover in clustered plantings. However, clustered Frankenia fared better during a transient period of heavy rabbit herbivory. Aside from this temporary benefit, clustering did not reduce stress and strongly suppressed growth—suggesting that restoration designs for the high marsh should minimize competition. [ABSTRACT FROM AUTHOR]

Published

2023

2. Live soil inocula, not host population or domestication status, is the predominant driver of growth benefits to cowpea.

Author

Manci, M., Mercado, O. G., Camantigue, R. X., Nguyen, T., Rothschild, J., Khairi, F., Neal, S., Farsamin, W. F., Lampe, M. T., Perez, I. A., Le, T. H., Ortiz-Barbosa, G. S., Torres-Martínez, L., and Sachs, J. L.

Subjects

*COWPEA, *SOIL inoculation, *AGRICULTURE, *DOMESTICATION of plants, *PLANT performance, *PLANT populations

Abstract

Purpose: Crops rely on microbes for critical services, but host benefits can be influenced by local makeup of microbiota and the host's capacity to select optimal strains. We investigated host benefits that cowpeas receive from microbiota depending on plant genotype, their domestication status, and soil source. Methods: We performed a full factorial soil inoculation experiment. Twenty diverse cowpea genotypes, selected from wild and domesticated populations, were exposed to soil rinsates from four agricultural sites across California, all having cowpea cultivation and varied physicochemical features. Cowpea investment in and benefit from microbiota was quantified by measuring host growth response to inoculation, nodulation, and segregating trait variation. Results: Variation in induction of root nodulation and strikingly heterogenous benefits to host growth were observed among soil sites. These effects were restricted to live soil inocula but were absent in autoclaved soil controls that lacked microbiota. Cowpeas expressed heritable variation in nodulation, but there was negligible effect of plant population or domestication status on the net benefit that hosts gained from microbiota. Conclusion: Soils varied substantially and consistently among cultivation sites and were the most prominent driver shaping host growth effects on cowpeas. While growth benefits vary among host cultivars, soil microbiota (and the conditions that maintain them) predominantly shape plant performance in agricultural settings. [ABSTRACT FROM AUTHOR]

Published

2023

3. Plant traits are differentially linked to performance in a semiarid ecosystem.

Author

Funk, Jennifer L., Larson, Julie E., and Ricks‐Oddie, Joni

Subjects

*STRUCTURAL equation modeling, *PLANT productivity, *PLANT ecology, *PLANT performance, *PHOTOSYNTHETIC rates, *WATER purification, *ECOLOGICAL models

Abstract

A central principle in trait‐based ecology is that trait variation has an adaptive value. However, uncertainty over which plant traits influence individual performance across environmental gradients may limit our ability to use traits to infer ecological processes at larger scales. To better understand which traits are linked to performance under different precipitation regimes, we measured above‐ and belowground traits, growth, and reproductive allocation for four annual and four perennial species from a coastal sage scrub community in California under conditions of 50%, 100%, and 150% ambient precipitation. Across water treatments, annual species displayed morphological trait values consistent with high rates of resource acquisition (e.g., low leaf mass per area, low root tissue density, high specific root length), and aboveground measures of resource acquisition (including photosynthetic rate and leaf N concentration) were positively associated with plant performance (reproductive allocation). Results from a structural equation model demonstrated that leaf traits explained 38% of the variation in reproductive allocation across the water gradient in annual species, while root traits accounted for only 6%. Although roots play a critical role in water uptake, more work is needed to understand the mechanisms by which root trait variation can influence performance in water‐limited environments. Perennial species showed lower trait plasticity than annuals across the water gradient and were more variable as a group in terms of trait–performance relationships, indicating that species rely on different functional strategies to respond to drought. Our finding that species identity drives much of the variation in trait values and trait–performance relationships across a water gradient may simplify efforts to model ecological processes, such as productivity, that are potentially influenced by environmentally induced shifts in trait values. [ABSTRACT FROM AUTHOR]

Published

2021

4. Invasive annuals respond more negatively to drought than native species.

Author

Valliere, Justin M., Escobedo, Evelin B., Bucciarelli, Gary M., Sharifi, M. Rasoul, and Rundel, Philip W.

Subjects

*DROUGHTS, *DROUGHT management, *PLANT performance, *WATER supply, *SPECIES, *PLANT species

Abstract

Summary: In his foundational list of 'ideal weed' characteristics, Baker (1965) proposed that weedy plants maximize reproductive output under high resource availability. Since then, the idea that invasive plant species are more responsive to fluctuating resources compared with native or noninvasive species has gained considerable traction, although few studies extend this hypothesis to include reproductive output. We revisit Baker's hypothesis in the context of invasion and drought in California grasslands, exploring whether invasives show greater growth and reproductive responses to water availability compared with the native wildflowers they displace.In an outdoor potted study, we grew eight native and eight invasive species of annuals commonly found in southern California grasslands to reproductive maturity under both well‐watered and drought conditions.While drought negatively impacted plant performance overall, invasives showed more negative responses for growth and reproductive traits. Invasives also grew larger than native species, especially under well‐watered conditions, and produced seed with higher rates of germination.Invasives may be more negatively impacted by drought compared with natives, but they are also able to capitalize on high resource conditions and greatly increase reproductive output. Such opportunistic responses exhibited by invasives might explain previously observed fluctuations in their abundance under variable precipitation. [ABSTRACT FROM AUTHOR]

Published

2019

5. Functional Traits Explain Variation in Chaparral Shrub Sensitivity to Altered Water and Nutrient Availability.

Author

Nielsen, Reina L., James, Jeremy J., and Drenovsky, Rebecca E.

Subjects

WATER supply, PLANT nutrition, WATER efficiency, GLOBAL environmental change, PLANT performance, LEAF area, GREENHOUSE gardening

Abstract

Worldwide drylands are threatened by changes in resource availability associated with global environmental change. Functional traits may help predict which species will be most responsive to these alterations in nutrient and water availability. Current functional trait work focuses on tissue construction and nutrient concentrations, but plant performance in low resource environments also may be strongly influenced by traits related to nutrient budgets and allocation. Our overall objective was to compare trait responses in a suite of serpentine and nonserpentine congener pairs from the California chaparral, a biodiverse region facing nutrient deposition and future changes in precipitation. In a common garden greenhouse environment, we grew small plants of Arctostaphylos manzanita, A. viscida, Ceanothus cuneatus, C. jepsonii, Quercus berberidifolia, and Q. durata in contrasting soil nutrient and moisture treatments. We measured a suite of traits representing physiological, growth, and mineral nutrient responses to these treatments. Overall, plant growth rate and leaf-level phosphorus use efficiency were greatest in the low water, high nutrient treatment, and lowest in the high water, low nutrient treatment. Variation in growth rate and plasticity among species and treatments was primarily associated with differences in mineral nutrition-based traits as opposed to differences in biomass allocation or specific leaf area. Namely, faster growing species and species with greater plasticity allocated more nitrogen and phosphorous to leaves and demonstrated greater photosynthetic phosphorus use efficiency. Overall, nonserpentine species had greater plasticity and biomass response to resource addition than serpentine species, and congener pairs responded to these resource additions more similarly to each other than species across congener pairs. This study extends our general understanding of how functional traits may influence species responses to environmental change and highlights the need to integrate mineral nutrition-based traits, including allocation of nutrient pools and nutrient use efficiency into this larger trait framework. Ultimately, this insight can help identify, in part, why coexisting species may vary in sensitivity to anthropogenic driven changes in soil resource availability. [ABSTRACT FROM AUTHOR]

Published

2019

6. Use of young plants for biological indexing of graft transmissible pathogens of citrus.

Author

Lee, Richard F., Keremane, Manjunath L., and Ramadugu, Chandrika

Subjects

GREENHOUSES, BIOLOGICAL laboratories, PLANT indicators, CITRUS, USEFUL plants, PLANT performance, PLANT size

Abstract

In budwood certification programs, routinely used, technology-based laboratory methods for detecting known citrus pathogens need to be complemented with biological indexing to confirm the absence of known and unknown graft transmissible pathogens (GTPs). We report here a procedure for biological indexing using very young indicator plants, 75–90 days old. Assay results of traditional biological indexing and mini-plant indexing conducted for 51 quarantine accessions and 29 positives infected with known pathogens were compared. The evaluation indicated similar sensitivity of detection between the two methods. Traditional bioindexing requires premium greenhouse resources and a lengthy incubation period; the use of mini-plants for indexing can provide a viable alternative since the technique can be conducted with a fraction of the resources typically needed. In southern California, we were able to index for GTPs requiring cooler temperatures during summer by placing mini-bioindicator plants near the cooling pads in an evaporatively-cooled greenhouse. Indicator plants kept under favorable conditions expressed symptoms throughout the year. Limited greenhouse space is required due to the small size of the indicator plants, and they can be used for biological indexing within 3 months as compared to 9–12 months with traditional indicator plants. Young plants require much less space with 240 plants/m2 of bench space as compared to 30 plants/m2 using the conventional approach for biological indexing. The use of mini-plant biological indexing will enable citrus 'clean stock' and certification programs to function more efficiently with limited resources and facilities. • Young plants under 90 days old can be used for efficient bioindexing of citrus pathogens. •Requirements for greenhouse space and assay time significantly reduced. •The performance of young plant assays is comparable to traditional bioindexing. Non-Technical Summary: We describe protocols for using young plants (<90 days old) as indicator plants for graft-transmissible pathogens of citrus. Young plants are useful as indicators for biological indexing and require fewer resources than 9-12 month-old plants used traditionally. [ABSTRACT FROM AUTHOR]

Published

2021

7. NRG Says Massive California Solar Plant Now on Pace to Meet Goal.

Author

Ryan, Joe

Subjects

PHOTOVOLTAIC cells, PLANT performance

Abstract

The release of the February output data comes 12 days after California regulators gave NRG and its partners more time to avoid defaulting on a contract with PG&E for failing to supply power they had guaranteed. Attribution Joe Ryan: by reporter Reed Landberg: editor responsible Charlotte Porter: editor Will Wade: editor. [Extracted from the article]

Published

2016

8. Switching to the Right Switch.

Subjects

UPGRADING of sewage disposal plants, EFFICIENCY of sewage disposal plants, ETHERNET, OPTICAL fiber communication, PLANT performance, FACILITY management, FIBER optics

Abstract

The article reports on the slow fiber-optic communication network problem of Pleasant Grove Wastewater Treatment Plant in Roseville, California. Plant operators identified the workstation problem to be coming from the optical communications modules (OCM) that sustained the workstations. Another source of the problem was that the graphics software for the treatment procedure needed more bandwidth than what was originally designed. A research by engineer Dan Mazorra showed that a new redundant fiber network using gigabit Ethernet switches can support the workstations and surveillance cameras. However, some modifications to the Ethernet OCM network system were made because the multimode fiber identified by Mazorra showed an impediment in terms of available bandwidth at gigabit speeds.

Published

2006