Your search keyword '"plant performance"' showing total 1,845 results

1. Hyperspectral Leaf Reflectance Detects Interactive Genetic and Environmental Effects on Tree Phenotypes, Enabling Large‐Scale Monitoring and Restoration Planning Under Climate Change.

Author

Corbin, Jaclyn P. M., Best, Rebecca J., Garthwaite, Iris J., Cooper, Hillary F., Doughty, Christopher E., Gehring, Catherine A., Hultine, Kevin R., Allan, Gerard J., and Whitham, Thomas G.

Subjects

*CHLOROPHYLL in water, *GENETIC variation, *PHENOTYPIC plasticity, *PLANT performance, *POPULATION transfers

Abstract

ABSTRACT Plants respond to rapid environmental change in ways that depend on both their genetic identity and their phenotypic plasticity, impacting their survival as well as associated ecosystems. However, genetic and environmental effects on phenotype are difficult to quantify across large spatial scales and through time. Leaf hyperspectral reflectance offers a potentially robust approach to map these effects from local to landscape levels. Using a handheld field spectrometer, we analyzed leaf‐level hyperspectral reflectance of the foundation tree species Populus fremontii in wild populations and in three 6‐year‐old experimental common gardens spanning a steep climatic gradient. First, we show that genetic variation among populations and among clonal genotypes is detectable with leaf spectra, using both multivariate and univariate approaches. Spectra predicted population identity with 100% accuracy among trees in the wild, 87%–98% accuracy within a common garden, and 86% accuracy across different environments. Multiple spectral indices of plant health had significant heritability, with genotype accounting for 10%–23% of spectral variation within populations and 14%–48% of the variation across all populations. Second, we found gene by environment interactions leading to population‐specific shifts in the spectral phenotype across common garden environments. Spectral indices indicate that genetically divergent populations made unique adjustments to their chlorophyll and water content in response to the same environmental stresses, so that detecting genetic identity is critical to predicting tree response to change. Third, spectral indicators of greenness and photosynthetic efficiency decreased when populations were transferred to growing environments with higher mean annual maximum temperatures relative to home conditions. This result suggests altered physiological strategies further from the conditions to which plants are locally adapted. Transfers to cooler environments had fewer negative effects, demonstrating that plant spectra show directionality in plant performance adjustments. Thus, leaf reflectance data can detect both local adaptation and plastic shifts in plant physiology, informing strategic restoration and conservation decisions by enabling high resolution tracking of genetic and phenotypic changes in response to climate change. [ABSTRACT FROM AUTHOR]

Published

2024

2. Investigating multi‐trophic effects of St. Augustinegrass cultivar blends in the Southeastern United States.

Author

Pinkney, James Louis IV, Iannone, Basil V. III, Milla‐Lewis, Susana, Laat, R., Unruh, J. Bryan, Schiavon, Marco, and Dale, Adam G.

Subjects

*INTEGRATED pest control, *INSECT pests, *PLANT performance, *PLANT species, *CULTIVARS

Abstract

Warm‐season turfgrasses, including St. Augustinegrass [Stenotaphrum secundatum (Walt.) Kuntze], are produced and installed as monocultures of single cultivars. Recent research indicates that blending St. Augustinegrass cultivars can increase turfgrass stand resilience to insect pests, establishment of undesired plant species, and abiotic stressors without reducing plant performance. However, effects on specific key turfgrass insect pests are less documented and the mechanisms driving changes in turfgrass stand resilience are unclear. Moreover, it remains unknown if the effects of cultivar blends on biotic resistance vary across St. Augustinegrass’ range. Here, we pair a regional common garden observational field study with a controlled greenhouse experiment to isolate the effects of cultivar blends on the recruitment of predatory arthropods (top‐down pest regulation) and on southern chinch bug [Blissus insularis Barber] performance (bottom‐up pest regulation). We find that cultivar diversity has no effect on natural enemy recruitment but natural enemies do vary predictably with changes in geographic location. In contrast to our hypothesis, southern chinch bug reached higher densities in cultivar blends compared to cultivar monocultures, although this effect was driven by specific cultivar blends. Despite higher pest densities in turfgrass blends on average, blends of four St. Augustinegrass cultivars maintained a higher percent green cover than cultivar monocultures, suggesting that cultivar blends can persist longer under elevated pest densities compared to cultivar monocultures. Our findings can guide future research focused on blending warm‐season turfgrass cultivars as an integrated pest management strategy for more resilient and sustainable turfgrass lawns. [ABSTRACT FROM AUTHOR]

Published

2024

3. Contrasting responses of naturalized alien and native plants to native soil biota and drought.

Author

Ruppert, Hannah K., van Kleunen, Mark, and Wilschut, Rutger A.

Subjects

*INTRODUCED plants, *NATIVE species, *PLANT performance, *VESICULAR-arbuscular mycorrhizas, *PLANT biomass

Abstract

Terrestrial plant communities often become invaded by alien species, which may benefit from high growth rates, strong phenotypic plasticity and reduced negative impacts from local soil communities. At the same time, terrestrial communities are increasingly more often exposed to periods of drought. However, how drought affects the competition between alien and native plants directly, and indirectly, through changing impacts of soil communities on plant performance, remains poorly understood.Here, we performed a greenhouse pot experiment in which we examined biomass responses of five native and five naturalized alien species (all occurring in mesic grasslands) to drought and benign soil moisture conditions, while growing in interspecific, intraspecific or absence of competition, in the presence or absence of native soil biota. We expected that alien plant species are less negatively affected by soil biota, but more negatively affected by drought than native species, and that drought indirectly weakens soil‐community‐driven competitive benefits of alien plant species over native ones.On average, soil‐community effects on plant biomass were positive, but native performance was less positively affected by soil communities than alien performance, suggesting reduced impacts of soil‐borne enemies on alien plants. Drought more negatively affected alien‐ than native plant performance. Drought impacts on plant biomass did not depend on soil community presence, but in the presence of soil biota, plants overall invested more in root biomass when exposed to drought. The effects of competition were subtle and species‐specific.To better understand the observed positive soil‐community effects on plant performance in our study, we examined mycorrhizal root colonization of plants grown in absence of competition. Among‐species variation in mycorrhizal colonization explained plant performance differences between soils with and without live soil communities, indicating a key role for arbuscular mycorrhizal fungi as driver of plant performance. However, mycorrhizal colonization did not differ between alien and native plants and was unaffected by drought.Overall, our study suggests that drought may weaken alien plant invasions through stronger direct negative impacts on alien than on native plant performance, but that drought does not affect soil‐biota‐driven differences in plant performance between alien and native plants. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2024

4. Empirical tests of trait–function relationships are crucial for advancing trait‐based restoration: a response to Merchant et al. (2023).

Author

Funk, Jennifer L., Eviner, Valerie T., Garbowski, Magda, and Valliere, Justin M.

Subjects

*RESTORATION ecology, *RESEARCH personnel, *PLANT performance, *SCIENTIFIC community, *MERCHANTS

Abstract

Trait‐based restoration strategies are gaining significant attention in the scientific community. A recent article in Restoration Ecology by Merchant et al. outlined four reasons why traits are underused in restoration practice. In their response to the paper, Gornish et al. highlighted examples of how practitioners do, in fact, use traits in restoration and made recommendations for researchers to better engage with practitioners to leverage existing knowledge. Here, we clarify a preeminent challenge for either perspective: that we continue to lack the empirical data needed to develop and apply the effective trait‐based tools envisioned by many researchers. Long‐term, spatially replicated studies designed to address context‐dependency are needed to address critical knowledge gaps. Co‐developing projects with practitioners not only fosters more realistic and relatable study designs but also increases the likelihood of adopting new methods, enabling long‐term research that advances theory while improving local outcomes through more accurate trait‐based predictions. [ABSTRACT FROM AUTHOR]

Published

2024

5. Mycorrhizal fungi as critical biotic filters for tree seedling establishment during species range expansions.

Author

Tourville, Jordon C., Horton, Thomas R., and Dovciak, Martin

Subjects

*TREE seedlings, *FUNGAL colonies, *SUGAR maple, *SPECIES distribution, *PLANT performance

Abstract

Global warming has been shifting climatic envelopes of many tree species to higher latitudes and elevations across the globe; however, unsuitable soil biota may inhibit tree migrations into these areas of suitable climate. Specifically, the role of mycorrhizal fungi in facilitating tree seedling establishment beyond natural species range limits has not been fully explored within forest ecosystems. We used three experiments to isolate and quantify the effects of mycorrhizal colonization and common mycorrhizal networks (CMN) on tree seedling survival and growth across (within and beyond) the elevational ranges of two dominant tree species in northeastern North America, which were associated with either arbuscular mycorrhiza (AMF, Acer saccharum) or ectomycorrhiza (EMF, Fagus grandifolia). In order to quantify the influence of mycorrhiza on seedling establishment independent of soil chemistry and climate, we grew seedlings in soils from within and beyond our study species ranges in a greenhouse experiment (GE) as well as in the field using a soil translocation experiment (STE) and another field experiment manipulating seedling connections to potential CMNs (CMNE). Root length colonized, seedling survival and growth, foliar nutrients, and the presence of potential root pathogens were examined as metrics influencing plant performance across species' ranges. Mycorrhizal inoculum from within species ranges, but not from outside, increased seedling survival and growth in a greenhouse setting; however, only seedling survival, and not growth, was significantly improved in field studies. Sustained potential connectivity to AMF networks increased seedling survival across the entire elevational range of A. saccharum. Although seedlings disconnected from a potential CMN did not suffer decreased foliar nutrient levels compared with connected seedlings, disconnected AM seedlings, but not EM seedlings, had significantly higher aluminum concentrations and more potential pathogens present. Our results indicate that mycorrhizal fungi may facilitate tree seedling establishment beyond species range boundaries in this forested ecosystem and that the magnitude of this effect is modulated by the dominant mycorrhizal type present (i.e., AM vs. EM). Thus, despite changing climate conditions beyond species ranges, a lack of suitable mutualists can still limit successful seedling establishment and stall adaptive climate‐induced shifts in tree species distributions. [ABSTRACT FROM AUTHOR]

Published

2024

6. Reintroduction affects demographic rates but not their interannual correlations in an endangered shrub.

Author

Villellas, Jesús, Sánchez de Dios, Rut, and Domínguez Lozano, Felipe

Subjects

*LIFE cycles (Biology), *ENDANGERED species, *PLANT performance, *SUBSTRATES (Materials science), *RESOURCE allocation, *GYPSUM

Abstract

Reintroducing endangered species constitutes an important conservation tool. The performance of reintroduced populations is commonly assessed through mean demographic rates (survival, growth, reproduction and fecundity), but rate correlations are less studied despite their role in extinction risk and trait evolution. In our study, we reintroduced the endangered shrub Vella pseudocytisus subsp. paui in two locations in Spain and compared its demographic performance to that of two natural populations to assess reintroduction success. In both natural and reintroduced sites, we selected sub‐locations with presumably more favourable (clay) vs. more stressful (gypsum) soil conditions. We monitored a total of 1269 individuals in natural (12 years) and reintroduced populations (6 years) and compared their mean demographic rates and the within‐individual rate correlations between years. In clay substrate, mean demographic rates of the natural and the reintroduced population were similar, suggesting a successful reintroduction. In contrast, the reintroduced population in gypsum showed higher reproduction and fecundity than the natural population, but lower survival and growth. Contrary to mean demographic performance, interannual correlations among demographic rates did not vary between natural and reintroduced populations. While reproduction in a given year was positively correlated with later growth and later reproduction, growth in a given year had some negative consequences in subsequent plant performance, especially in gypsum substrate. Synthesis and applications. Our study shows that stressful conditions may trigger individual‐level trade‐offs in resource allocation and population‐level compensation among demographic rates. Demographic shifts arising from reintroductions in different environmental conditions may be considered by managers as a potential mechanism of resilience against environmental change. Finally, the similarity in rate correlations among sites suggests that information about correlations, which can be relevant when focusing conservation efforts, may be extrapolated from natural to reintroduced populations. This might be particularly reliable for species where rate correlations are demographically influential, such as those living under generally stressful conditions, or lacking buffering mechanisms for demographic variation. [ABSTRACT FROM AUTHOR]

Published

2024

7. Interplay between native plant performance and environment shapes resistance to aquatic plant invasion.

Author

Fan, Shufeng, Lv, Tian, Yu, Haihao, Yang, Lei, Wang, Ligong, Li, Yang, Liu, Chunhua, and Yu, Dan

Subjects

*INTRODUCED plants, *BIOLOGICAL invasions, *RESTORATION ecology, *AQUATIC plants, *PLANT performance, *PLANT invasions

Abstract

In the limited number of studies on biotic resistance in freshwater ecosystems, experimental studies have supported that native plants play a role in resisting exotic plant invasion, but field observations have often reported positive relationships between exotic and native plant richness. To determine the reasons for the lack of evidence supporting biotic resistance in field observations, we surveyed the richness, biomass and coverage of exotic and native aquatic plants in 2801 quadrats at 287 sites in various freshwater ecosystems of China and examined the impacts of scale and environmental factors on the relationships between native and exotic plant richness and performance. At both the site and quadrat scales, we observed a positive correlation between the richness of exotic and native plants. However, at the quadrat scale, high native plant richness was associated with a reduction in the biomass of exotic emergent and floating plants as well as the biomass of exotic submerged plants in low‐nutrient water bodies. An increase in native plant performance, a metric that integrates the biomass and coverage of native plants, was associated with a decrease in both the richness and biomass of exotic plants at both scales. Furthermore, with increasing native plant performance at the quadrat scale, the richness of exotic plants declined more strongly in low‐nutrient water bodies than in high‐nutrient water bodies, and the decline in the biomass of exotic emergent and floating plants was more severe in shallow water than in deep water. Synthesis. Our results indicate that native plant performance is more important than richness for resistance to invasion in freshwater ecosystems, and the strength of biotic resistance is related to environmental factors. This study highlights the importance of environmental variables and multiple native community features and invasibility metrics in field observational studies of invasion. [ABSTRACT FROM AUTHOR]

Published

2024

8. Investigating the effect of changing the K:Ca ratio in nutrient solution on the quantitative and qualitative yield of <italic>Lilium spp</italic>. in hydroponic cultivation.

Author

Ranjbar Sheykhani, Reyhaneh

Subjects

*PLANT nutrition, *PLANT performance, *NUTRIENT uptake, *PERLITE, *BLOCK designs

Abstract

AbstractNowadays, hydroponics is an advanced method for plant production in agriculture. The optimal balance of nutrients in the nutrient solution is crucial to enhance plant performance in this method. To investigate the effect of potassium to calcium (K:Ca) ratio change in nutrient solution on quantitative and qualitative yield of lilies in hydroponic culture, a randomized complete block design with nine treatments and three replications was designed and carried out in 30% perlite and 70% sand. The treatments included different concentrations of calcium (Ca) at three levels of 0, 3, and 6 mM and different concentrations of potassium (K) at three levels of 0, 3, and 6 mM in the Hoagland nutrient solution, with K:Ca ratios of 0:0, 0:3, 0:6, 3:0, 3:3, 3:6, 6:0, 6:3, and 6:6. Results showed that the presence of different levels of potassium and calcium was found to enhance the quality of lilies by influencing nutrient uptake. The results indicated that nutrient solutions containing different ratios of K:Ca had a significant effect on reproductive height, the number of aborted buds, stem diameter at the 5% level and the number of flowers, the number of leaves, the fresh weight of shoots, the dry weight of shoots, and the longevity at the 1% level. The highest yield in terms of longevity (17 days), the number of flowers, the number of leaves, and absorption of potassium and calcium were observed in the nutrient solution with a 3:3 K:Ca ratio. [ABSTRACT FROM AUTHOR]

Published

2024

9. Inoculation with arbuscular mycorrhizal fungi improves plant biomass and nitrogen and phosphorus nutrients: a meta-analysis.

Author

Wu, Yingjie, Chen, Chongjuan, and Wang, Guoan

Subjects

*PLANT biomass, *PLANT inoculation, *VESICULAR-arbuscular mycorrhizas, *COLONIZATION (Ecology), *PLANT performance

Abstract

Arbuscular mycorrhizal fungi (AMF) have profound effects on plant growth and nitrogen (N) and phosphorus (P) nutrition. However, a comprehensive evaluation of how plant N and P respond to AMF inoculation is still unavailable. Here, we complied data from 187 original researches and carried out a meta-analysis to assess the effects of AMF inoculation on plant growth and N and P nutrition. We observe overall positive effects of AMF inoculation on plant performance. The mean increases of plant biomass, N concentration, P concentration, N and P uptake of whole plant are 47%, 16%, 27%, 67%, and 105%, respectively. AMF inoculation induces more increases in plant concentrations and storage of P than N. Plant responses to AMF inoculation are substantially higher with single AMF species than with mixed AMF species, in laboratory experiments than in field experiments, and in legumes than in non-legumes. The response ratios of plant N and P nutrition are positively correlated with AMF colonization rate, N addition, P addition, and water condition, while unvaried with experiment duration. The biggest and smallest effect sizes of AMF inoculation on plant performance are observed in the application of nitrate and ammonium, respectively. Accordingly, this meta-analysis study clearly suggests that AMF inoculation improves both plant N and P nutrients and systematically clarifies the variation patterns in AMF effects with various biotic and abiotic factors. These findings highlight the important role of AMF inoculation in enhancing plant N and P resource acquisitions and provide useful references for evaluating the AMF functions under the future global changes. [ABSTRACT FROM AUTHOR]

Published

2024

10. Acylsugars, Nicotine and a Protease Inhibitor Provide Variable Protection for Nicotiana benthamiana in a Natural Setting.

Author

Negin, Boaz, Wang, Fumin, Fischer, Hillary D., and Jander, Georg

Subjects

*FLEA beetles, *LEAFHOPPERS, *NICOTIANA benthamiana, *PLANT performance, *PROTEASE inhibitors

Abstract

ABSTRACT Plants produce an immense diversity of defensive specialized metabolites. However, despite extensive functional characterization, the relative importance of different defensive compounds is rarely examined in natural settings. Here, we compare the efficacy of three Nicotiana benthamiana defensive compounds, nicotine, acylsugars and a serine protease inhibitor, by growing plants with combinations of knockout mutations in a natural setting, quantifying invertebrate interactions and comparing relative plant performance. Among the three tested compounds, acylsugars had the greatest defensive capacity, affecting aphids, leafhoppers, spiders and flies. Nicotine mutants displayed increased leafhopper feeding and aphid colonization. Plants lacking both nicotine and acylsugars were more susceptible to flea beetles and thrips. By contrast, knockout of the serine protease inhibitor did not affect insect herbivory in the field. Complementary experiments under controlled laboratory conditions with caterpillars, grasshoppers and aphids confirmed results obtained in a natural setting. We conclude that the three metabolite groups collectively provide broad‐spectrum protection to N. benthamiana. However, there is a gradient in their effects on the interacting invertebrates present in the field. Furthermore, we demonstrate that, even if individual metabolites do not have a measurable defensive benefit on their own, they can have an additive effect when combined with other defensive compounds. [ABSTRACT FROM AUTHOR]

Published

2024

11. Diversity of organic amendments increases soil functions and plant growth.

Author

Li, Huiying, Lehmann, Anika, Rongstock, Rebecca, Xu, Yaqi, Kunze, Edda, Meidl, Peter, and Rillig, Matthias C.

Subjects

*AGRICULTURE, *PLANT performance, *SOIL amendments, *PLANT growth, *PLANT-soil relationships

Abstract

Societal Impact Statement Management practices, for example, in an agricultural context, are often tested in isolation or in pairwise interaction, but rarely using a higher number of jointly applied practices. In a proof‐of‐concept study, we test the effects of combining up to five management practices. Effects seen on soil and plant performance suggest that it may be worth to systematically and broadly examine the effects of higher order management combinations. [ABSTRACT FROM AUTHOR]

Published

2024

12. Leaf functional trait evolution and its putative climatic drivers in African Coffea species.

Author

Hendrickx, Aiden, Hatangi, Yves, Honnay, Olivier, Janssens, Steven B, Stoffelen, Piet, Vandelook, Filip, and Depecker, Jonas

Subjects

*GERMPLASM conservation, *LEAF area, *BROWNIAN motion, *PLANT performance, *WHITE noise, *BOTANICAL specimens

Abstract

Background and Aims Leaf traits are known to be strong predictors of plant performance and can be expected to (co)vary along environmental gradients. We investigated the variation, integration, environmental relationships and evolutionary history of leaf functional traits in the genus Coffea , typically a rainforest understorey shrub, across Africa. A better understanding of the adaptive processes involved in leaf trait evolution can inform the use and conservation of coffee genetic resources in a changing climate. Methods We used phylogenetic comparative methods to investigate the evolution of six leaf traits measured from herbarium specimens of 58 African Coffea species. We added environmental data and data on maximum plant height for each species to test trait–environment correlations in various (sub)clades, and we compared continuous trait evolution models to identify variables driving trait diversification. Key Results Substantial leaf trait variation was detected across the genus Coffea in Africa, which was mostly interspecific. Of these traits, stomatal size and stomatal density exhibited a clear trade-off. We observed low densities of large stomata in early-branching lineages and higher densities of smaller stomata in more recent taxa, which we hypothesize to be related to declining CO2 levels since the mid-Miocene. Brownian motion evolution was rejected in favor of white noise or Ornstein–Uhlenbeck models for all traits, implying these traits are adaptively significant rather than driven by pure drift. The evolution of leaf area was likely driven by precipitation, with smaller leaves in drier climates across the genus. Conclusions Generally, Coffea leaf traits appear to be evolutionarily labile and governed by stabilizing selection, though evolutionary patterns and correlations differ depending on the traits and clades considered. Our study highlights the importance of a phylogenetic perspective when studying trait relationships across related taxa, as well as the consideration of various taxonomic ranges. [ABSTRACT FROM AUTHOR]

Published

2024

13. 基于字符增强的工业设备故障命名实体识别.

Author

张阳 and 刘瑾

Subjects

*LONG-term memory, *PLANT performance, *RANDOM fields, *INDUSTRIAL equipment, *INDUSTRIAL goods

Abstract

To address the issues of sparse training data, complex entity structures, and uneven entity distribution in the industrial equipment failure domain, this study constructs an industrial equipment failure named entity recognition corpus. Due to the difficulty of character level named entity recognition models in representing the professional vocabulary information in the field of industrial equipment failure, this study proposes a character enhanced industrial equipment failure named entity recognition model to address this problem. In the embedding layer, professional vocabulary information is directly fused between the Transformer layers of ROBERT WWM (Robustly Optimized BERT Pretraining Approach with Whole Word Masking) to allocate word information to each of its constituent characters for enhanced semantics. The global semantic information is obtained through a BiLSTM (Bidirectional Long Short Term Memory), and the CRF (Conditional Random Field) is used to learn the dependency relationship between adjacent labels to obtain the optimal sentence level label sequence. Experimental results demonstrate that the proposed model has good performance on industrial equipment fault named entity recognition tasks, with an average F1 score of 92.403%. [ABSTRACT FROM AUTHOR]

Published

2024

14. Interactive Effects of Climate Change and Pathogens on Plant Performance: A Global Meta‐Analysis.

Author

Gallego‐Tévar, Blanca, Gil‐Martínez, Marta, Perea, Antonio, Pérez‐Ramos, Ignacio M., and Gómez‐Aparicio, Lorena

Subjects

*PHYTOPATHOGENIC microorganisms, *PLANT performance, *PLANT diseases, *PLANT size, *PLANT communities, *DROUGHT management

Abstract

Plant health is increasingly threatened by abiotic and biotic stressors linked to anthropogenic global change. These stressors are frequently studied in isolation. However, they might have non‐additive (antagonistic or synergistic) interactive effects that affect plant communities in unexpected ways. We conducted a global meta‐analysis to summarize existing evidence on the joint effects of climate change (drought and warming) and biotic attack (pathogens) on plant performance. We also investigated the effect of drought and warming on pathogen performance, as this information is crucial for a mechanistic interpretation of potential indirect effects of climate change on plant performance mediated by pathogens. The final databases included 1230 pairwise cases extracted from 117 recently published scientific articles (from 2006) on a global scale. We found that the combined negative effects of drought and pathogens on plant growth were lower than expected based on their main effects, supporting the existence of antagonistic interactions. Thus, the larger the magnitude of the drought, the lower the pathogen capacity to limit plant growth. On the other hand, the combination of warming and pathogens caused larger plant damage than expected, supporting the existence of synergistic interactions. Our results on the effects of drought and warming on pathogens revealed a limitation of their growth rates and abundance in vitro but an improvement under natural conditions, where multiple factors operate across the microbiome. Further research on the impact of climate change on traits explicitly defining the infective ability of pathogens would enhance the assessment of its indirect effects on plants. The evaluated plant and pathogen responses were conditioned by the intensity of drought or warming and by moderator categorical variables defining the pathosystems. Overall, our findings reveal the need to incorporate the joint effect of climatic and biotic components of global change into predictive models of plant performance to identify non‐additive interactions. [ABSTRACT FROM AUTHOR]

Published

2024

15. Assessment of the Performance of a Field Weeding Location-Based Robot Using YOLOv8.

Author

Palva, Reetta, Kaila, Eerikki, García-Pascual, Borja, and Bloch, Victor

Subjects

*SUGAR beets, *PLANT performance, *IMAGE processing, *PLANT spacing, *PLANT growth

Abstract

Field robots are an important tool when improving the efficiency and decreasing the climatic impact of food production. Although several commercial field robots are available, the advantages, limitations, and optimal utilization methods of this technology are still not well understood due to its novelty. This study aims to evaluate the performance of a commercial field robot for seeding and weeding tasks. The evaluation was carried out in a 2-hectare sugar beet field. The robot's performance was assessed by counting plants and weeds using image processing. The YOLOv8 model was trained to detect sugar beets and weeds. The plant and weed densities were compared on a robotically weeded area of the field, a chemically weeded control area, and an untreated control area. The average weed density on the robotically treated area was about two times lower than that on the untreated area and about three times higher than on the chemically treated area. The testing robot in the specific testing environment and mode showed intermediate results, weeding a majority of the weeds between the rows; however, it left the most harmful weeds close to the plants. Software for robot performance assessment can be used for monitoring robot performance and plant conditions several times during plant growth according to the weeding frequency. [ABSTRACT FROM AUTHOR]

Published

2024

16. National‐scale distribution of protists associated with sorghum leaves and roots.

Author

He, Peng, Sun, Anqi, Jiao, Xiaoyan, Ren, Peixin, Li, Fangfang, Wu, Bingxue, He, Ji‐Zheng, and Hu, Hang‐Wei

Subjects

*PLANT performance, *COMPOSITION of leaves, *SOIL acidity, *PROTISTA, *SORGHUM

Abstract

Protists, as integral constituents of the plant microbiome, are posited to confer substantial benefits to plant health and performance. Despite their significance, protists have received considerably less attention compared to other constituents of the plant microbiome, such as bacteria and fungi. To investigate the diversity and community structure of protists in sorghum leaves and roots, we employed amplicon sequencing of the eukaryotic 18S rRNA gene in 563 leaf and root samples collected from 57 locations across China. We found significant differences in the diversity and community structure of protists in sorghum leaves and roots. The leaf was taxonomically dominated by Evosea, Cercozoa and Ciliophora, while the root was dominated by Endomyxa, Cercozoa and Oomycota. The functional taxa of protists exhibited notable differences between leaves and roots, with the former being predominantly occupied by consumers and the latter by parasites. The community composition of protists in the leaf was predominantly influenced by mean annual precipitation, whereas soil pH played a more significant role in the root. The present study identified the most abundant and distributed protists in sorghum leaves and roots and elucidated the underlying factors that govern their community structure. The present study offers a novel perspective on the factors that shape plant‐associated protist communities and their potential roles in enhancing the functionality of plant ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

17. The roles of root‐nodulating bacterial associations and cyanogenesis in the freezing sensitivities of herbaceous legumes.

Author

Rycroft, Samuel L. and Henry, Hugh A. L.

Subjects

*SNOW cover, *HYDROCYANIC acid, *PLANT productivity, *SOIL fertility, *PLANT performance, *LEGUMES

Abstract

Premise: Reduced snow cover and increasing temperature variability can increase freezing stress for herbaceous plants in northern temperate regions. Legumes have emerged as a plant functional group that is highly sensitive to these changes relative to other herbaceous species in these regions. We explored root‐nodulating bacterial associations and cyanogenesis as potential mechanisms explaining this relatively low freezing tolerance of legumes. Methods: To examine the influence of bacterial associations, we grew four legume species with or without crushed‐nodule inoculum at three severities of freezing, and three concentrations of nitrogen to disambiguate the direct benefits of increased nitrogen from the total bacterial effect. We quantified cyanogenesis via hydrogen cyanide production in both true leaves and cotyledons for nine legume species. Results: Root nodulation generally only affected legume survival under low nitrogen, when freezing severity was moderate or low. However, for the frost‐surviving plants, the growth advantage provided by nodulation decreased (it was often no longer significant with increasing freezing severity), and greater freezing severity reduced total nodule mass. In contrast, cyanogenesis was only detected in two of the nine species. Conclusions: The diminished performance of nodulated plants in response to freezing could place legumes at a competitive disadvantage and potentially explain their high sensitivity to freezing relative to other herbaceous species in northern temperate regions. Overall, this result has important implications for changes in soil fertility, community composition, and plant productivity in these ecosystems in the context of a changing winter climate. [ABSTRACT FROM AUTHOR]

Published

2024

18. System for the Acquisition and Monitoring of Energy Consumption in the Context of Industry 4.0.

Author

Covrig, Tudor, Ciobotaru, Alexandru, Bejan, Pavel-Alexandru, Farmathy-Pop, Lucian, Oltean, Stelian, Dumitru, Cristian-Dragoș, and Miclea, Liviu-Cristian

Subjects

*INDUSTRIAL energy consumption, *PLANT performance, *DATA acquisition systems, *MANUFACTURING processes, *ASSEMBLY line methods

Abstract

This paper examines methodologies for monitoring energy consumption and operational parameters of an industrial assembly line, with a particular emphasis on the utilization of virtual tools, augmented reality, and real-time data visualization. The research examines the integration of an interface and the implementation of a data acquisition system, employing augmented reality to facilitate interaction with the collected data. The proposed system employs the Node-RED interface to facilitate the establishment of connections between constituent elements. The data is stored in a database, which provides support for decision-making in the analysis of energy consumption and operational parameters of the industrial assembly line. The results demonstrate that the solution is effective in enhancing energy resource management, identifying inefficiencies, and optimizing the performance of industrial equipment. The findings indicate that the implementation of such a system can markedly enhance the industrial process. [ABSTRACT FROM AUTHOR]

Published

2024

19. Specific physiological responses to alkaline carbonate stress in rice (Oryza sativa) seedlings: organic acid metabolism and hormone signalling.

Author

Wang, Dan, Xu, Miao, Xu, Teng-yuan, Lin, Xiu-yun, Musazade, Elshan, Lu, Jing-mei, Yue, Wei-jie, Guo, Li-quan, and Zhang, Yu

Subjects

*JASMONIC acid, *PHOSPHOPROTEIN phosphatases, *ABSCISIC acid, *PLANT performance, *RICE, *ORGANIC acids

Abstract

In recent years, alkaline soda soil has stimulated numerous biological research on plants under carbonate stress. Here, we explored the difference in physiological regulation of rice seedlings between saline (NaCl) and alkaline carbonate (NaHCO3 and Na2CO3) stress. The rice seedlings were treated with 40 mM NaCl, 40 mM NaHCO3 and 20 mM Na2CO3 for 2 h, 12 h, 24 h and 36 h, their physiological characteristics were determined, and organic acid biosynthesis and metabolism and hormone signalling were identified by transcriptome analysis. The results showed that alkaline stress caused greater damage to their photosynthetic and antioxidant systems and led to greater accumulation of organic acid, membrane damage, proline and soluble sugar but a decreased jasmonic acid content compared with NaCl stress. Jasmonate ZIM-Domain (JAZ), the probable indole-3-acetic acid-amido synthetase GH3s, and the protein phosphatase type 2Cs that related to the hormone signalling pathway especially changed under Na2CO3 stress. Further, the organic acid biosynthesis and metabolism process in rice seedlings were modified by both Na2CO3 and NaHCO3 stresses through the glycolate/glyoxylate and pyruvate metabolism pathways. Collectively, this study provides valuable evidence on carbonate-responsive genes and insights into the different molecular mechanisms of saline and alkaline stresses. Understanding how seedlings respond to stress from salt and alkalis can help inform strategies to boost plant performance in adverse environments. We examined how these stressors affect rice seedling physiology and gene expression. Genes that respond to salt and alkali stress are mainly involved in hormone signalling, and in the synthesis and metabolism of organic acids. These findings will contribute to engineering stress-tolerant crops. [ABSTRACT FROM AUTHOR]

Published

2024

20. Elevated concentrations of soil carbon dioxide with partial root-zone drying enhance drought tolerance and agro-physiological characteristics by regulating the expression of genes related to aquaporin and stress response in cucumber plants.

Author

Abdeldaym, Emad A., Hassan, Hassan A., El-Mogy, Mohamed M., Mohamed, Mohamed S., Abuarab, Mohamed E., and Omar, Hanaa S.

Abstract

Water scarcity and soil carbon dioxide elevation in arid regions are considered the most serious factors affecting crop growth and productivity. This study aimed to investigate the impacts of elevated CO2 levels (eCO2 at rates of 700 and 1000 ppm) on agro-physiological attributes to induce drought tolerance in cucumbers by activating the expression of genes related to aquaporin and stress response, which improved the yield of cucumber under two levels of irrigation water conditions [75% and 100% crop evapotranspiration (ETc)]. Therefore, two field experiments were conducted in a greenhouse with controlled internal climate conditions, at the Mohamed Naguib sector of the national company for protected agriculture, during the winter seasons of 2021–2022 and 2022–2023. The treatments included eCO2 in soil under normal and partial root zoon drying (PRD, 100% ETc Full irrigations, and 75% ETc). All the applied treatments were organized as a randomized complete block design (RCBD) and each treatment was replicated six times. Untreated plants were designed as control treatment (CO2 concentration was 400 ppm). The results of this study showed that elevating CO2 at 700 and 1000 ppm in soil significantly increased plant growth parameters, photosynthesis measurements, and phytohormones [indole acetic acid (IAA) and gibberellic acid (GA3)], under partial root-zone drying (75% ETc) and full irrigation conditions (100% ETc). Under PRD condition, eCO2 at 700 ppm significantly improved plant height (13.68%), number of shoots (19.88%), Leaf greenness index (SPAD value, 16.60%), root length (24.88%), fresh weight (64.77%) and dry weight (61.25%) of cucumber plant, when compared to untreated plants. The pervious treatment also increased photosynthesis rate, stomatal conductance, and intercellular CO2 concentration by 50.65%, 15.30% and 12.18%; respectively, compared to the control treatment. Similar findings were observed in nutrient concentration, carbohydrate content, Proline, total antioxidants in the leaf, and nutrients. In contrast, eCO2 at 700 ppm in the soil reduced the values of transpiration rate (6.33%) and Abscisic acid (ABA, 34.03%) content in cucumber leaves compared to untreated plants under both water levels. Furthermore, the results revealed that the gene transcript levels of the aquaporin-related genes (CsPIP1-2 and CsTIP4) significantly increased compared with a well-watered condition. The transcript levels of CsPIP improved the contribution rate of cell water transportation (intermediated by aquaporin’s genes) and root or leaf hydraulic conductivity. The quantitative real-time PCR expression results revealed the upregulation of CsAGO1 stress-response genes in plants exposed to 700 ppm CO2. In conclusion, elevating CO2 at 700 ppm in the soil might be a promising technique to enhance the growth and productivity of cucumber plants in addition to alleviating the adverse effects of drought stresses. [ABSTRACT FROM AUTHOR]

Published

2024

21. ETHYLENE RESPONSE FACTOR6, A Central Regulator of Plant Growth in Response to Stress.

Author

Li, Ting, Peng, Zhen, Kangxi, Du, Inzé, Dirk, and Dubois, Marieke

Subjects

*PLANT regulators, *PLANT performance, *PLANT growth, *ABIOTIC stress, *ETHYLENE

Abstract

ABSTRACT ETHYLENE RESPONSE FACTOR6 (ERF6) has emerged as a central player in stress‐induced plant growth inhibition. It orchestrates complex pathways that enable plants to acclimate and thrive in challenging environments. In response to various abiotic and biotic stresses, ERF6 is promptly activated through both ethylene‐dependent and ‐independent pathways, and contributes to enhanced stress tolerance mechanisms by activating a broad spectrum of genes at various developmental stages. Despite the crucial role of ERF6, there is currently a lack of published comprehensive insights into its function in plant growth and stress response. In this respect, based on the tight connection between ethylene and ERF6, we review the latest research findings on how ethylene regulates stress responses and the mechanisms involved. In addition, we summarize the trends and advances in ERF6‐mediated plant performance under optimal and stressful conditions. Finally, we also highlight key questions and suggest potential paths to unravel the ERF6 regulon in future research. [ABSTRACT FROM AUTHOR]

Published

2024

22. Establishment of polyploidy in natural populations of Mimulus guttatus.

Author

Salony, Susnata, Clo, Josselin, Vallejo-Marín, Mario, and Kolář, Filip

Subjects

*SYMPATRIC speciation, *PLANT species, *PLANT performance, *PLOIDY, REPRODUCTIVE isolation

Abstract

Whole-genome duplication (WGD) is a leading force of plant sympatric speciation. However, the evolutionary mechanisms promoting the establishment of neopolyploid mutants in nature remain elusive. We studied polyploid establishment in a unique natural system of Mimulus guttatus (Phrymaceae) in Shetland where a recently (< 100 years ago) locally formed autotetraploid still coexists with its diploid progenitor. We cytotyped 679 adults and 766 seedlings and scored relevant reproductive traits in the field and performed controlled crossings to infer differences in plant performance and get a first insight into the crossing barriers between ploidies. Tetraploids grew in 25% of Shetland populations, mostly in mixtures with diploids, but triploids were absent both among seedlings and adults. Seeds of both cytotypes sampled in areas of immediate sympatry exhibited similar, high germination rates (98% on average). In contrast, low (2%) germination of progeny from controlled interploidy crosses demonstrated strong postzygotic isolation. Yet, plants simultaneously pollinated by diploid and tetraploid pollen donors set viable progeny with ploidy levels identical to the seed parent. The abundant presence of fertile tetraploids in the field despite strong postzygotic isolation demonstrates the ability of novel autopolyploids to cope with both intrinsic and extrinsic challenges associated with WGD and to successfully establish in nature. [ABSTRACT FROM AUTHOR]

Published

2024

23. Linking root cell wall width with plant functioning under drought conditions.

Author

Han, Qinwen, Yang, Qingpei, Guo, Binglin, and Kong, Deliang

Subjects

*PLANT breeding, *PLANT cell walls, *GENOME-wide association studies, *NITROGEN deficiency, *PLANT performance, *CORN, *ROOT growth, *PLANT roots

Abstract

This article discusses the relationship between root cortical parenchyma wall width (CPW) and plant functioning under drought conditions. The study found that thicker CPW in maize roots promotes growth and yield under suboptimal water and nitrogen supply. The authors used a functional-structural root anatomy model to predict the effects of increased CPW on root respiration and conducted field experiments to confirm their findings. They also identified potential genes associated with CPW changes and suggested that thicker CPW allows for deeper rooting, which enhances water uptake and plant performance under drought. The article highlights the importance of understanding root cortical cell structures and their impact on plant adaptation to stressful environments. [Extracted from the article]

Published

2024

24. Root plasticity improves maize nitrogen use when nitrogen is limiting: an analysis using 3D plant modelling.

Author

Lu, Jie, Lankhost, Jan A, Stomph, Tjeerd Jan, Schneider, Hannah M, Chen, Yanling, Mi, Guohua, Yuan, Lixing, and Evers, Jochem B

Subjects

*PHENOTYPIC plasticity, *PLANT productivity, *PLANT performance, *CORN, *PLANT yields

Abstract

Plant phenotypic plasticity plays an important role in nitrogen (N) acquisition and use under nitrogen-limited conditions. However, this role has never been quantified as a function of N availability, leaving it unclear whether plastic responses should be considered as potential targets for selection. A combined modelling and experimentation approach was adopted to quantify the role of plasticity in N uptake and plant yield. Based on a greenhouse experiment we considered plasticity in two maize (Zea mays) traits: root-to-leaf biomass allocation ratio and emergence rate of axial roots. In a simulation experiment we individually enabled or disabled both plastic responses for maize stands grown across six N levels. Both plastic responses contributed to maintaining a higher N uptake, and plant productivity as N availability declined compared with stands in which plastic responses were disabled. We conclude that plastic responses quantified in this study may be a potential target trait in breeding programs for greater N uptake across N levels while it may only be important for the internal use of N under N-limited conditions in maize. Given the complexity of breeding for plastic responses, an a priori model analysis is useful to identify which plastic traits to target for enhanced plant performance. [ABSTRACT FROM AUTHOR]

Published

2024

25. Transgenerational effects of mycorrhiza are stronger in sexual than in clonal offspring of Fragaria vesca and are partly adaptive.

Author

Latzel, Vít, Mizgur‐Hribar, Danej, Sammarco, Iris, and Janoušková, Martina

Subjects

*PLANT colonization, *PLANT performance, *ECOSYSTEM dynamics, *MYCORRHIZAS, *PLANT growth

Abstract

Whilst transgenerational effects (TGE) of abiotic conditions are becoming generally accepted in plants, those of biotic interactions remain largely unexplored. We therefore investigated the influence of TGE due to arbuscular mycorrhiza, the most widespread mutualistic interaction of plants with microorganisms, on clonal and sexual offspring of Fragaria vesca. We hypothesized that the ecological and evolutionary significance of TGE will vary between clonal and sexual offspring based on mycorrhizal status and phosphorus (P) availability experienced by the parent. In a two‐generation greenhouse experiment, parental plants were exposed to full‐factorial combinations of mycorrhizal status and high or low P availability. TGE on mycorrhiza establishment and plant performance were evaluated in their clonal and sexual offspring, which experienced the parental or all non‐parental environments. Consistently in both generations, mycorrhiza improved plant growth at low P availability, but had no or even negative effect at high P availability, concomitantly with decreased root colonization by the arbuscular mycorrhizal (AM) fungus. TGE due to mycorrhiza was generally stronger in sexually derived offspring, both on mycorrhiza formation and plant growth. In sexual offspring, parental mycorrhizal status was adaptive if the offspring's mycorrhizal status was of disadvantage: for mycorrhizal offspring growing in high P availability and for non‐mycorrhizal offspring at low P availability. Synthesis: Our results suggest that clonal and sexual reproduction are under different evolutionary pressures, leading to the development of stronger TGE mechanisms in response to mycorrhizal symbiosis in the latter. The complexity of the observed effects highlights the need for disentangling the mechanisms contributing to the TGE in clonal and sexual reproduction. Our study underlines the importance of considering reproductive strategies and the interplay between environmental factors and TGE in understanding the ecological and evolutionary dynamics of plant–symbiotic interactions. [ABSTRACT FROM AUTHOR]

Published

2024

26. Combined application of biochar and peatmoss for mitigation of drought stress in tobacco.

Author

Zaman, Qamar uz, Rehman, Muzammal, Feng, Youhong, Liu, Zhiyuan, Murtaza, Ghulam, Sultan, Khawar, Ashraf, Kamran, Elshikh, Mohamed S., Al Farraj, Dunia A., Rizwan, Muhammad, Iqbal, Rashid, and Deng, Gang

Subjects

*SUSTAINABILITY, *RICE straw, *PLANT performance, *CHLORIDE ions, *PSEUDOPOTENTIAL method

Abstract

Drought poses a significant ecological threat that limits the production of crops worldwide. The objective of this study to examine the impact of soil applied biochar (BC) and peatmoss (PM) on the morpho-biochemical and quality traits of tobacco plants under drought conditions. In the present experiment work, a pot trial was conducted with two levels of drought severity (~ well-watered 75 ± 5% field capacity) and severe drought stress (~ 35 ± 5% field capacity), two levels of peatmoss (PM) @ 5% [PM+ (with peatmoss) and PM- (without peatmoss)] and three levels of rice straw biochar (BC0 = no biochar; BC1 = 150 mg kg− 1; and BC2 = 300 mg kg− 1 of soil) in tobacco plants. The results indicate that drought conditions significantly impacted the performance of tobacco plants. However, the combined approach of BC and PM significantly improved the growth, biomass, and total chlorophyll content (27.94%) and carotenoids (32.00%) of tobacco. This study further revealed that the drought conditions decreased the production of lipid peroxidation and proline accumulation. But the synergistic approach of BC and PM application increased soluble sugars (17.63 and 12.20%), soluble protein (31.16 and 15.88%), decreased the proline accumulation (13.92 and 9.03%), and MDA content (16.40 and 8.62%) under control and drought stressed conditions, respectively. Furthermore, the combined approach of BC and PM also improved the leaf potassium content (19.02%) by limiting the chloride ions (33.33%) under drought stressed conditions. Altogether, the balanced application of PM and BC has significant potential as an effective approach and sustainable method to increase the tolerance of tobacco plants subjected to drought conditions. This research uniquely highlights the combined potential of PM and BC as an eco-friendly strategy to enhance plant resilience under drought conditions, offering new insights into sustainable agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

27. Phyllosphere fungal diversity generates pervasive nonadditive effects on plant performance.

Author

Almeida, Brianna K., Tran, Elan H., and Afkhami, Michelle E.

Subjects

*PLANT diversity, *PLANT performance, *FUNGAL communities, *IPOMOEA, *VACCINATION, *PLANT productivity

Abstract

Summary: Plants naturally harbor diverse microbiomes that can dramatically impact their health and productivity. However, it remains unclear how fungal microbiome diversity, especially in the phyllosphere, impacts intermicrobial interactions and consequent nonadditive effects on plant productivity.Combining manipulative experiments, field collections, culturing, microbiome sequencing, and synthetic consortia, we experimentally tested for the first time how foliar fungal community diversity impacts plant productivity. We inoculated morning glories (Ipomoea hederifolia L.) with 32 phyllosphere consortia of either low or high diversity or with single fungal taxa, and measured effects on plant productivity and allocation.We found the following: (1) nonadditive effects were pervasive with 56% of fungal consortia interacting synergistically or antagonistically to impact plant productivity, including some consortia capable of generating acute synergism (e.g. > 1000% increase in productivity above the additive expectation), (2) interactions among 'commensal' fungi were responsible for this nonadditivity in diverse consortia, (3) synergistic interactions were approximately four times stronger than antagonistic effects, (4) fungal diversity affected the magnitude but not frequency or direction of nonadditivity, and (5) diversity affected plant performance nonlinearly with the highest performance in low‐diversity treatments.These findings highlight the importance of interpreting plant–microbiome interactions under a framework that incorporates intermicrobial interactions and nonadditive outcomes to understand natural complexity. See also the Commentary on this article by Whitaker, 243: 2050–2051. [ABSTRACT FROM AUTHOR]

Published

2024

28. Combined application of biochar and peatmoss for mitigation of drought stress in tobacco.

Author

Zaman, Qamar uz, Rehman, Muzammal, Feng, Youhong, Liu, Zhiyuan, Murtaza, Ghulam, Sultan, Khawar, Ashraf, Kamran, Elshikh, Mohamed S., Al Farraj, Dunia A., Rizwan, Muhammad, Iqbal, Rashid, and Deng, Gang

Subjects

*SUSTAINABILITY, *RICE straw, *PLANT performance, *CHLORIDE ions, *PSEUDOPOTENTIAL method

Abstract

Drought poses a significant ecological threat that limits the production of crops worldwide. The objective of this study to examine the impact of soil applied biochar (BC) and peatmoss (PM) on the morpho-biochemical and quality traits of tobacco plants under drought conditions. In the present experiment work, a pot trial was conducted with two levels of drought severity (~ well-watered 75 ± 5% field capacity) and severe drought stress (~ 35 ± 5% field capacity), two levels of peatmoss (PM) @ 5% [PM+ (with peatmoss) and PM- (without peatmoss)] and three levels of rice straw biochar (BC0 = no biochar; BC1 = 150 mg kg− 1; and BC2 = 300 mg kg− 1 of soil) in tobacco plants. The results indicate that drought conditions significantly impacted the performance of tobacco plants. However, the combined approach of BC and PM significantly improved the growth, biomass, and total chlorophyll content (27.94%) and carotenoids (32.00%) of tobacco. This study further revealed that the drought conditions decreased the production of lipid peroxidation and proline accumulation. But the synergistic approach of BC and PM application increased soluble sugars (17.63 and 12.20%), soluble protein (31.16 and 15.88%), decreased the proline accumulation (13.92 and 9.03%), and MDA content (16.40 and 8.62%) under control and drought stressed conditions, respectively. Furthermore, the combined approach of BC and PM also improved the leaf potassium content (19.02%) by limiting the chloride ions (33.33%) under drought stressed conditions. Altogether, the balanced application of PM and BC has significant potential as an effective approach and sustainable method to increase the tolerance of tobacco plants subjected to drought conditions. This research uniquely highlights the combined potential of PM and BC as an eco-friendly strategy to enhance plant resilience under drought conditions, offering new insights into sustainable agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

29. Effect of nanoparticles on the ex-vitro performance of cryopreservation-derived plant material.

Author

Kulus, Dariusz, Tymoszuk, Alicja, Kulpińska, Alicja, Viehmannova, Iva, Wojnarowicz, Jacek, and Szałaj, Urszula

Subjects

*PLANT growing media, *LEAF development, *NUCLEAR DNA, *PLANT performance, *GOLD nanoparticles

Abstract

The integration of nanoparticles into plant cryopreservation protocols holds great promise for improving the survival rates and recovery potential of explants. This study aimed to verify the effect of nanoparticles on the ex-vitro performance of cryopreservation-derived plants. Lamprocapnos spectabilis (L.) Fukuhara (bleeding heart) 'Gold Heart' and 'Valentine' cultivars were used as the plant material. The encapsulation-vitrification cryopreservation protocol of shoot tips included the preculture, encapsulation, dehydration, storage in liquid nitrogen, rewarming, and recovery steps. Gold (AuNPs), silver (AgNPs), or zinc oxide (ZnONPs) nanoparticles were added at varying concentrations, either into the preculture medium or the protective bead matrix during encapsulation. After the in vitro recovery, the plants were transferred to the glasshouse and subjected to detailed biometrical, biochemical and cytogenetic analyses. Nanoparticles had no evident effect on the acclimatization efficiency (80–100% survival) and leaf number in L. spectabilis 'Gold Heart'. Nonetheless, shoots developed from alginate beads supplemented with 5 ppm AuNPs were twice as long as the control, while the leaves of plants grown on the preculture medium with ZnONPs contained significantly more chlorophyll and had higher Leaf Soil-Plant Analysis Development (SPAD) values. Moreover, several NPs treatments stimulated the development of leaves, including their surface area, length, and perimeter. Higher ZnONPs levels enhanced also the replication process, resulting in higher nuclear DNA content. As for L. spectabilis 'Valentine', alginate augmentation with 5 ppm AgNPs or 5 ppm ZnONPs stimulated the elongation of shoots. There was also a tendency suggesting a positive influence of 5 ppm AgNPs in the alginate bead matrix on foliar growth. The effect of nanoparticles on the content of flavonoids, anthocyanins, and stress markers in the plants varied depending on the treatment and cultivar, but also on the organ studied (leaf or stem). Overall, L. spectabilis 'Gold Heart' was more stress-tolerant and genetically stable than 'Valentine' judging by the activity of Photosystem II (PSII) and flow cytometric analyses, respectively. The complex effects of nanoparticles on survival, biometric parameters, physiological responses, and cytogenetic events underscore the intricate interplay between nanoparticles and plant systems. Nonetheless, our research confirmed the positive effect of nanoparticles on the ex-vitro growth and development of L. spectabilis plants after cryostorage. [ABSTRACT FROM AUTHOR]

Published

2024

30. Plant performance and soil–plant carbon relationship response to different biochar types.

Author

Liao, Jia Xin, So, Pui San, Bordoloi, Sanandam, Li, De Nian, Yuan, Hao Ran, Chen, Yong, and Xin, Li Qing

Subjects

*LEAF area index, *PEANUT hulls, *SOIL salinity, *PLANT performance, *AGRICULTURE

Abstract

Biochar (BC) applications in soil has positive effects on plant performance, particularly for loose soil in agricultural context. However, how biochar types affect plant performance of non-crop species and soil–plant carbon relationships is not clear. We selected five different BC types and three plant species to investigate the responses of plant performance and the soil–plant carbon relationship to BC effects. The result demonstrated that peanut shell BC led to the death of both R. tomentosa and C. edithiae, due to a reduction in nutrient uptake caused by higher soil electricity conductivity (2001.7 and 976.3 µS cm−1). However, the carbon content of S. arboricola increased by 57% in peanut shell BC-amended soil, suggesting that S. arboricola has a higher tolerance for soil salinity. Wood BC-amended soil led to better stomatal conductance (gs) and leaf area index (LAI) of both R. tomentosa and C. edithiae due to the higher water retention in the soil (22.68% and 20.79%). This illustrated that a higher amount of water retention brought by wood BC with a great amount of pore volume might be the limited factor for plant growth. The relationship between gs and LAI suggested that gs would not increase when LAI reached beyond 3. Moreover, wood and peanut shell BC caused a negative relationship between soil organic carbon and plant carbon content, suggesting that plants consume more carbon from the soil to store it in the plant. Overall, wood BC is recommended for plant growth of R. tomentosa and C. edithiae, and peanut shell BC is suggested for S. arboricola carbon storage. Highlights: Peanut shell biochar enhanced soil salinity which causes the death of R. tomentosa and C. edithiae, while wood biochar is suitable for these plant species. Wood and peanut shell biochar caused a negative relationship between soil organic carbon and plant carbon content. The stomatal conductance will not increase when the leaf area reaches the limiting value 3. An empirical function is developed to correlate plant carbon content and leaf area index under different biochar applications. [ABSTRACT FROM AUTHOR]

Published

2024

31. Unraveling genotypic interactions in sugar beet for enhanced yield stability and trait associations.

Author

Ramazi, Mahdi, Omidi, Heshmat, Sadeghzadeh Hemayati, Saeed, and Naji, Amirmohammad

Subjects

*GENOTYPE-environment interaction, *GENOTYPES, *SUGAR beets, *PLANT performance

Abstract

The interaction between genotype and environment (GEI) significantly influences plant performance, crucial for breeding programs and ultimately boosting crop productivity. Alongside GEI, breeders encounter another hurdle in their quest for yield improvement, notably adverse and negative correlations among pivotal traits. This study delved into the stability of white sugar yield (WSY), root yield (RY), sugar content (SC), extraction coefficient of sugar (ECS), and the interplay among essential traits including RY, SC, alpha amino nitrogen (N), sodium (Na+), and potassium (K+) across 15 sugar beet hybrids and three control varieties. The investigation spanned two locations over two consecutive years (2022–2023), employing a randomized complete block design with four replications to comprehensively analyze these factors. The analysis of variance highlighted the significant effects of environment, genotype, and GEI at the 1% probability level. Notably, the AMMI analysis of GEI revealed the significance of the first component for WSY, RY, and SC, with the first two components proving significant for ECS. Within the linear mixed model (LMM), WSY, RY, SC, and ECS demonstrated significant effects from both genotype and GEI. In the WAASB biplot, genotypes 10, 8, 17, 6, 13, 14, 15, 7, 12, and 16 exhibited stability in WSY, while genotypes 9, 10, 6, 14, 7, 8, 13, 12, 18, and 15 displayed stability in RY. Additionally, genotypes 10, 15, 12, 13, 16, 17, 6, and 14 were stable for SC, and genotypes 8, 10, 7, 6, 13, 12, 16, 17, 15, 14, and 18 showcased stability in ECS, boasting above-average yield values. In the genotype by yield × trait (GYT) biplot, genotypes 15, 18, and 16 emerged as top performers when combining RY with SC, Na+, N, and K+, suggesting their potential for inclusion in breeding programs. [ABSTRACT FROM AUTHOR]

Published

2024

32. Soil-borne fungal diseases in Aotearoa New Zealand pastures: a significant research blind spot.

Author

van Amsterdam, Sarah A. M., Templeton, Matthew D., Lear, Gavin, and Bell, Nigel L.

Subjects

*MYCOSES, *PLANT performance, *PASTURE plants, *PLANT species, *PLANT growth

Abstract

In Aotearoa New Zealand (AoNZ), where pastoral agriculture is vital to the economy, reports of pasture plant species failing to persist in long-term pastures, particularly in northern regions, are increasingly common. The underlying cause of this decline in pasture persistence remains elusive. Soil-borne diseases are a potential contributing factor affecting root function and consequently, plant growth and performance. Despite their potential significance, little is known about the soil-borne diseases affecting pastoral species and cultivars. The detrimental effects of fungal soil-borne pathogens on global agroecosystems are well documented. Mitigating these impacts requires a comprehensive understanding of their distribution, abundance, and host relationships. This review summarises pasture pathology research in AoNZ, and the current and future challenges influencing fungal pathogens are discussed. This review concludes that a more comprehensive understanding of soil-borne pathogens affecting AoNZ pastures is required to mitigate impacts and future disease-risk. Furthermore, it advocates for a multidisciplinary approach, in collaboration with commercial partners and farmers, to develop effective mitigation strategies and decision-tools for farmers. [ABSTRACT FROM AUTHOR]

Published

2024

33. Overview of preparation for the American WAKE ExperimeNt (AWAKEN).

Author

Moriarty, Patrick, Bodini, Nicola, Letizia, Stefano, Abraham, Aliza, Ashley, Tyler, Bärfuss, Konrad B., Barthelmie, Rebecca J., Brewer, Alan, Brugger, Peter, Feuerle, Thomas, Frère, Ariane, Goldberger, Lexie, Gottschall, Julia, Hamilton, Nicholas, Herges, Thomas, Hirth, Brian, Hung, Lin-Ya, Iungo, Giacomo Valerio, Ivanov, Hristo, and Kaul, Colleen

Subjects

*ATMOSPHERIC radiation measurement, *WIND power, *PLANT performance, *WIND turbines, *RESEARCH personnel

Abstract

The American WAKE ExperimeNt (AWAKEN) is a multi-institutional field campaign focused on gathering critical observations of wind farm–atmosphere interactions. These interactions are responsible for a large portion of the uncertainty in wind plant modeling tools that are used to represent wind plant performance both prior to construction and during operation and can negatively impact wind energy profitability. The AWAKEN field campaign will provide data for validation, ultimately improving modeling and lowering these uncertainties. The field campaign is designed to address seven testable hypotheses through the analysis of the observations collected by numerous instruments at 13 ground-based locations and on five wind turbines. The location of the field campaign in Northern Oklahoma was chosen to leverage existing observational facilities operated by the U.S. Department of Energy Atmospheric Radiation Measurement program in close proximity to five operating wind plants. The vast majority of the observations from the experiment are publicly available to researchers and industry members worldwide, which the authors hope will advance the state of the science for wind plants and lead to lower cost and increased reliability of wind energy systems. [ABSTRACT FROM AUTHOR]

Published

2024

34. Performance evaluation of triangular cell sunflower seed metering roller under field condition using power tiller.

Author

F. M., Mhala, Marandu, S. I., and Elias, E. N.

Subjects

*FEED quality, *PLANT performance, *BLOCK designs, *JOB performance, *CULTIVATORS, *SUNFLOWER seeds

Abstract

Presently, the triangular cell sunflower seed metering roller has not been evaluated in field conditions using a power tiller. This study was undertaken to evaluate its working performance in the field conditions. Randomized complete block design with three replications and three level of forward speed and a quantity of seeds in hopper was used to evaluate performance of the triangular cell sunflower seed metering roller. Performance indices namely mean spacing; miss index, multiple indexes, quality of feed index, precision index, and coefficient of variation were used to describe the performance of the triangular cell sunflower seed metering roller. Results were analysed statistically to determine the effect of forward speed, quantity of seed in the hopper and their interaction on the performance indices. Best performance was at a combination of forward speed 1.3 km h-1 and a quantity of seeds in the hopper of 2.392 kg, which gave a mean spacing of 226.16 cm, a miss index of 25%, multiple indexes of 0.43%, a quality of feed index of 97.33% and a precision index of 16.58%. Based on agronomical recommendations for sunflower planting and performance comparison with other sunflower metering device, it is concluded that triangular cell sunflower seed metering roller can perform efficiently and economically and can be adopted by the small and medium farmers. [ABSTRACT FROM AUTHOR]

Published

2024

35. Energy, exergy and performance analysis of a 380 kWP roof-top PV plant assisted with data-driven models for energy generation.

Author

RATHORE, Abhijeet, ALMAS, and SUNDARAM, Sivasankari

Subjects

*ARTIFICIAL neural networks, *PHOTOVOLTAIC power systems, *PLANT performance, *ENERGY consumption, *EXERGY, *DEEP learning

Abstract

Energy and Exergy based performetric analysis integrated with deep learning assisted energy modelling for grid connected solar PV system, tested to non-trained location is proposed. The first objective is to perform an energy and exergy based performetric analysis for a realistic 380 kWp grid connected roof-top PV system whose performance parameter is used for testing the proposed energy prediction models. The second objective is to formulate a simple and an improved energy estimation method applicable for 34 locations in South India, without change in model-coefficients. So, a long-term annual performance analysis of a 380 kWp PV based distributed generator situated at 12.97°N and 77.59°E is performed which estimates the characteristic performance indicators like energy efficiency, exergy efficiency, performance ratio and capacity factor amounting to 8.49%, 1.03%, 37%, and 8.03% respectively. The performance ratio of the plant is less as evident from the least exergy efficiency. The annual average losses in the system like thermal capture loss, array capture loss, system loss and miscellaneous loss amount to 0.46 (h/d), 2.51(h/d), 0.71 (h/d) and 2.97(h/d) respectively. The annual average energy generation of 380 kWp is 732.84 kWh/year. Furthermore, for realizing the second objective, a total of four models are proposed namely linear, exponential, non-linear and deep learning based neural network model resulting in R of 0.933, 0.9071, 0.9386, and 0.9603 respectively is formulated. The proposed models are tested for non-trained locations where the R value justifying the closeness between the actual and the predicted value is as high as 0.8. The proposed models are then compared upon their performances and benchmarked against the reported models. [ABSTRACT FROM AUTHOR]

Published

2024

36. Genetic Insights into Stress Resilience via Enhancing Salinity Adaptation in Barley.

Author

Thabet, Samar G., Elkelish, Amr, Alwutayed, Khairiah Mubarak, and Alqudah, Ahmad M.

Subjects

*GENOME-wide association studies, *SOIL salinity, *ADENOSINE triphosphatase, *PLANT performance, *VITAMIN C

Abstract

Salinity stress is one of the major abiotic stresses that significantly impacts plant growth and performance. Therefore, this study investigated the role of foliar-applied ascorbic acid (AsA) at a concentration of 2 mM as a mitigative approach to salt stress in barley during its vegetative stage. The research aimed to elucidate the genetic responses induced by AsA that potentially confer enhanced tolerance to salinity. A controlled environment experiment was conducted, wherein barley plants were subjected to salt stress and treated with a foliar application of AsA. Natural phenotypic variation showed an increment for all agronomical traits after the foliar application of AsA compared to saline environment (control). Highly significant markers were detected by using a genome-wide association study (GWAS) that are associated with all of the studied traits, underscoring the protective role of AsA under salt stress. Furthermore, the study identified several novel stress-responsive genes influenced by AsA treatment, pointing to complex genetic networks underlying salt stress mitigation. For instance, the gene HORVU.MOREX.r3.2HG0199440 at position (622,219,977–622,220,459 bp) on 2H, which is annotated as V-type ATP synthase beta chain, helps to maintain cellular redox balance during stress conditions. This research paves the way for future work on the practical applications of AsA in agriculture, especially in breeding programs aimed at enhancing salt stress tolerance in barley and similar cereals. [ABSTRACT FROM AUTHOR]

Published

2024

37. Genotype and Nitrogen Source Influence Drought Stress Response in Oil Palm Seedlings.

Author

Ruiz-Romero, Rodrigo, De la Peña, Marlon, Ayala-Díaz, Iván, Montoya, Carmenza, and Romero, Hernán Mauricio

Subjects

*WATER shortages, *SUSTAINABLE agriculture, *AGRICULTURE, *PLANT performance, *ROOT development, *DROUGHT management, *OIL palm

Abstract

As a significant global source of vegetable oil, the oil palm's ability to withstand abiotic stresses, particularly drought, is crucial for sustainable agriculture. This is especially significant in tropical regions, where water scarcity is becoming more common. Nitrogen, a vital nutrient, plays an essential role in various physiological and biochemical processes in plants, directly influencing growth and stress tolerance. This study investigates the interaction between nitrogen sources (ammonium vs. nitrate) and drought stress in oil palm (Elaeis guineensis) seedlings, which is critical in enhancing productivity in this economically important crop. The experiment evaluated five commercial oil palm genotypes, which were supplied with nitrogen solutions (15 mM NH4+ or NO3−) for 46 days, followed by 30 days of progressive drought. The results showed that drought conditions universally reduced the biomass, with ammonium-fed plants exhibiting greater shoot biomass sensitivity than nitrate-fed plants. Drought also significantly decreased the chlorophyll a, PhiPS2, and root-reducing sugar levels—critical indicators of photosynthetic efficiency and overall plant health. The effects on the root architecture were complex, with ammonium nutrition differentially influencing the lateral root length under well-watered versus drought conditions, highlighting nitrogen forms' nuanced role in root development. Importantly, substantial genotypic variability was observed in most traits, affecting the responses to both the nitrogen source and drought stress. This variability suggests that certain genotypes may be better suited to cultivation in specific environmental conditions, particularly drought-prone areas. In conclusion, this study underscores the intricate interplay between nitrogen nutrition, genotypic variability, and drought tolerance in oil palm seedlings. These findings highlight the need to integrate these factors into agricultural management strategies to improve resilience and productivity in oil palm plantations. [ABSTRACT FROM AUTHOR]

Published

2024

38. Strangers in a foreign land: 'Yeastizing' plant enzymes.

Author

Van Gelder, Kristen, Lindner, Steffen N., Hanson, Andrew D., and Zhou, Juannan

Subjects

*MACHINE learning, *PLANT enzymes, *PLANT performance, *AMINO acid sequence, *ENZYMES

Abstract

Expressing plant metabolic pathways in microbial platforms is an efficient, cost‐effective solution for producing many desired plant compounds. As eukaryotic organisms, yeasts are often the preferred platform. However, expression of plant enzymes in a yeast frequently leads to failure because the enzymes are poorly adapted to the foreign yeast cellular environment. Here, we first summarize the current engineering approaches for optimizing performance of plant enzymes in yeast. A critical limitation of these approaches is that they are labour‐intensive and must be customized for each individual enzyme, which significantly hinders the establishment of plant pathways in cellular factories. In response to this challenge, we propose the development of a cost‐effective computational pipeline to redesign plant enzymes for better adaptation to the yeast cellular milieu. This proposition is underpinned by compelling evidence that plant and yeast enzymes exhibit distinct sequence features that are generalizable across enzyme families. Consequently, we introduce a data‐driven machine learning framework designed to extract 'yeastizing' rules from natural protein sequence variations, which can be broadly applied to all enzymes. Additionally, we discuss the potential to integrate the machine learning model into a full design‐build‐test cycle. [ABSTRACT FROM AUTHOR]

Published

2024

39. Differential physio-chemical responses of wild and cultivar Sesamum species exposed to drought and recovery.

Author

Jeyaraj, S., Raj Aswathi, K.P., Puthur, Jos T., and Suhara Beevy, S.

Subjects

*CLIMATE change, *CULTIVARS, *DROUGHT tolerance, *PLANT performance, *AGRICULTURE, *SESAME

Abstract

• Sesamum indicum , a commercial oilseed crop shows less productivity during severe and recurrent drought exposure. But its wild relative S. radiatum is considered as a potential candidate for drought-resistance. • Upon exposure to drought (15 days), the wild taxa sustained cellular turgor, regulated lipid peroxidation through enhanced accumulation of osmolytes, and higher activity of antioxidants than the cultivar. • The wild taxa recovered at a faster rate upon rewatering, and can be used to improve the drought-tolerance of sesame, thereby to combat the forthcoming climate crisis. Drought is one of the most significant abiotic stresses that affect plant performance, lowers agricultural output, and, in extreme cases, results in crop loss. The major challenge faced by farmers is to ensure the production of crop varieties under extreme environmental conditions. Sesame (Sesamum indicum L.) is a traditionally important major cash crop for small and marginal farmers in some developing countries since it requires less intensive care and investment. Although sesame is considered as a resilient crop, it remains sensitive to severe drought. In this study, the morpho-physiological, biochemical, and antioxidant responses of wild and cultivar species of Sesamum viz., S. radiatum , and S. indicum subjected to different irrigation treatments such as mild (75 % Field capacity), moderate (50 % FC) and severe (25 % FC) drought and subsequent recovery (rewatered to 100 % FC) were evaluated in comparison with control groups. Present findings revealed that both species displayed differential responses to the drought stress and subsequent recovery. In particular, the wild taxa demonstrated better drought tolerance, probably due to their higher leaf-relative water content, decreased lipid peroxidation, enhanced accumulation of osmolytes, and increased activities of enzymatic and non-enzymatic antioxidants. On the other hand, the cultivar presented reduced leaf-relative water content, increased lipid peroxidation, higher electrolyte leakage, and reduced antioxidant activities, mostly at 25 % FC. Present data suggests that the cultivar was strictly exacerbated, mostly during severe water deficits; however, the wild species could re-adjust to the water deficit circumstances and recover completely. The current study implies the potential of wild species that can be used to improve the drought tolerance of commercial sesame by utilizing the same in breeding programs. [ABSTRACT FROM AUTHOR]

Published

2024

40. The role of indole-3-butyric acid and polyamines on in vitro rooting of microshoots of Rosa damascena Mill. and Gladiolus hybridus Hort.

Author

Kumar, Anil, Nagar, P.K., and Palni, L.M.S.

Subjects

*DAMASK rose, *SPERMIDINE, *SPERMINE, *PLANT species, *PLANT performance

Abstract

A. Shoots of Gladiolus hybridus on masal MS medium; B. Shoots of Rosa damascena multiplied on MS medium containing 2.5 µM BAP. Rotted shoots of C. Gladiolus hybridus and D. Rosa damascena on MS medium supplemented with 2.5 µM IBA. [Display omitted] • IBA and putrescine both induced rooting individually in miroshoots of rosa damascena and gladiolus hybridus, and their synergistic effect was also observed. • Inhibition of diamine oxidase by l -aminoguanidine inhibited rooting in microshoots, which suggests the role of putrescine oxidation products in root induction, or the observed inhibition of rooting could be due to the accumulation of free putrescine. • When the endogenous synthesis of spermidine and spermine was blocked by methylglyoxal(bis) guanylhydrazone; the exogenous spermine application only induced rooting in microshoots, indicating its essential role in root induction. The effect of indole-3-butyric (IBA) acid and polyamines was investigated on in vitro rooting of microshoots of Rosa damascena Mill. (difficult-to-root) and Gladiolus hybridus Hort. (easy-to-root) plants. Both IBA and putrescine (PUT) individually induced rooting and showed a synergistic effect in the rooting of microshoots of both plant species. Maximum rooting of microshoots (%) was observed on Murashige and Skoog medium (MS medium) supplemented with 2.5 μM IBA and 100 μM PUT. The incorporation of methylglyoxal(bis) guanylhydrazone (MGBG: a competitive inhibitor of s-adenosyl methionine decarboxylase and is known to block spermidine and spermine synthesis) completely inhibited the rooting of microshoots of both plant species. Similarly, the incorporation of l -aminoguanidine (AG: an inhibitor of diamine oxidase) also inhibited the adventitious rooting of microshoots of both species, indicating the role of the oxidation product of PUT in rooting. Rooting was not observed in either species when a medium containing MGBG was supplemented with spermidine. In contrast, when spermine was incorporated in a MS medium with MGBG, the rooting was achieved in both species, thus establishing spermine's clear role in the rooting of microshoots. An increase in peroxidase activity was observed during IBA and PUT-induced rooting. The performance of plants rooted on a medium containing 2.5 μM IBA was significantly better than those rooted on a medium containing 2.5 μM IBA and 100 μM PUT. [ABSTRACT FROM AUTHOR]

Published

2024

41. Transgenerational phenotypic responses to herbicide stress are more rapid than to shade and simulated herbivory in Arabidopsis.

Author

Sharma, Gourav, Haak, David, Westwood, James H., Askew, Shawn, and Barney, Jacob N.

Subjects

*AGRICULTURE, *ARABIDOPSIS thaliana, *PLANT performance, *WEEDS, *PHENOTYPES

Abstract

SUMMARY: Weeds in agricultural settings continually adapt to stresses from ecological and anthropogenic sources, in some cases leading to resistant populations. However, consequences of repeated sub‐lethal exposure of these stressors on fitness and stress "memory" over generations remain poorly understood. We measured plant performance over a transgenerational experiment with Arabidopsis thaliana where plants were exposed to sub‐lethal stress induced by the herbicides glyphosate or trifloxysulfuron, stresses from clipping or shading in either one (G1) or four successive generations (G1–G4), and control plants that never received stress. We found that fourth‐generation (G4) plants that had been subjected to three generations of glyphosate or trifloxysulfuron stress produced higher post‐stress biomass, seed weight, and rosette area as compared to that produced by plants that experienced stress only in the first generation (G1). By the same measure, clipping and shade were more influential on floral development time (shade) and seed weight (clipping) but did not show responsive phenotypes for vegetative metrics after multiple generations. Overall, we found that plants exhibited more rapid transgenerational vegetative "stress memory" to herbicides while reproductive plasticity was stressor dependent and similar between clipping/shade and anthropogenic stressors. Our study suggests that maternal plant stress memory aids next‐generation plants to respond and survive better under the same stressors. Significance Statement: We show differential transgenerational phenotypes to different stressors over four generations in Arabidopsis. [ABSTRACT FROM AUTHOR]

Published

2024

42. Enhanced sorbent materials for post-combustion CO2 capture - A prolix review.

Author

Millerjothi, N. K., Adhithan, S. Kavin, Khogulanand, V. R., and Kiruba, P.

Subjects

*COMBUSTION efficiency, *PLANT performance, *SORBENTS, *HIGH temperatures, *POWER plants

Abstract

The capture of CO2 after combustion poses efficiency challenges for power plants, taking into account its general influence on the power plants overall performance, capturing CO2 after combustion has posed a challenge in terms of efficiency. The paper quantitatively compares the performance of integrated systems utilizing various solid sorbents such as calcium-based sorbents, Potassium based sorbent, amine based sorbent and magnesium-based sorbent. This investigation focuses on carbonate looping, which is a concept using high temperature CO2 capture materials. The study shows that despite having potential material degradation and decreased CO2 capacity over several cycles is one of the major challenges it faces Solid sorbents are seen as promising low-cost technologies for CO2 capture at this stage. The initial findings of this paper assess the merits of specific post-combustion CO2 capture sorbent materials. [ABSTRACT FROM AUTHOR]

Published

2024

43. The thermodynamics investigation of steam power plant Riau Andalan Pulp and Paper Pangkalan Kerinci: An energy and exergy analysis.

Author

Yulia, Fayza, Sinaga, Gary, Daris, Miftah, Ra'if, Kato, Dzar, Zaky, Tegar, Ibnu, Ashari, Fikri, Wahyuni, Fitri, Rizal, Reda, and Julian, James

Subjects

*SECOND law of thermodynamics, *PAPER pulp, *PLANT performance, *EXERGY, *ENERGY dissipation

Abstract

The energy and exergy analysis of the Riau Andalan Pulp and Paper (RAPP) Pangkalan Kerinci are described in this article. This article's main goals are to study the system components independently and to locate and quantify the locations with the greatest energy and exergy losses. The analysis with the first law and second law of thermodynamics which are able to observe comprehensively the irreversibility of each component in the system is carried out due to the low efficiency of the steam power plant. The investigation is performed with the actual data obtained from the plant. From the evaluation results, the Pump II Component has the highest Exergetic Efficiency (95%), while the Feed Water Tank (FWT) component has the lowest Exergetic Efficiency (30.68%). The Boiler component has the largest exergy destruction value (454.2548 MW), while the Pump component has the smallest exergy destruction value (0.0006 MW). Next, the FWT component has the largest Exergy Destruction Ratio value (69.32%), while the Pump I component has the smallest Exergy Destruction Ratio (0.79%) at the steam power plant. In addition, the investigation of the ambient temperature effects on the performance of the plant was also carried out. From the results that have been investigated, the ambient temperature significantly affects the performance of each component. Some components are at their best performance when the ambient temperature reaches 23°C and the condenser has the lowest efficiency when the environmental pressure in the power plant reaches 1.5 bar (64.8%) [ABSTRACT FROM AUTHOR]

Published

2024

44. The role of feedwater heater operational combination toward steam power plant performance.

Author

Teguh, Nurdin Hasananto, Darmadi, Djarot B., Yuliati, Lilis, and Siswanto, Eko

Subjects

*STEAM power plants, *WATER leakage, *PLANT performance, *ENERGY consumption, *ELECTRICITY pricing

Abstract

Feedwater heater has vital role for improving steam power plant by regenerative heating method. As some failures such water leakage and tube leakage in feedwater heater may affect performance and lead to shut down for repairing. Further study is required to evaluate the effect of either one or more feedwater heater shutdown towards steam power plant performance. This work describes and analyses the 25 MW steam power plant in the Indonesia region, a possible example of feedwater operation flexibility. We tried to examine the possible operation changing with 8 variations towards energy evaluation based on thermodynamic assessment and further calculate into fuel gap and cost evaluation (fuel consumption gap and electricity price). After conducting 9 conditions including normal case, at constant fuel rate, the result shows that lowest point in terms of power generation and efficiency occurred when Low Pressure Heater 2 shutdown resulting in 196 kWh, 0.22% decrease respectively. The economical deficit of this condition accumulatively as much as 11-million-rupiah loss. [ABSTRACT FROM AUTHOR]

Published

2024

45. Geothermal power plant performance estimation using ANFIS-PCA and ANFIS-GA.

Author

Adiarte, G. G., Suheri, A., and Prajitno, P.

Subjects

*GEOTHERMAL power plants, *GEOTHERMAL resources, *PRINCIPAL components analysis, *PLANT performance, *FUZZY logic

Abstract

Monitoring the performance of the power plant is important to see the overall system efficiency. The performance in geothermal power plants can be viewed from the Specific Steam Consumption (SSC) value. This research aims to estimate the SSC using an artificial intelligence approach based on the Adaptive Neuro Fuzzy Inference System (ANFIS). The ANFIS's input variables consist of 10 variables originating from the geothermal power generation sub-system, namely the steam supply and venting system (SSVS), the turbine-generator system (TGS), the steam return and condensate system (SCRS), the gas removal system (GRS), and a cooling water system (CWS). In this study, principal component analysis (PCA) and genetic algorithm (GA) are used to minimize the estimation error value and to analyze variables affecting the SSC. The evaluations of the ANFIS-PCA and ANFIS-GA models used are RMSE, MAE, and MAPE. In this study, the ANFIS-GA and ANFIS-PCA algorithms produce the same and better estimation performance than without selecting variables. The ANFIS-PCA, ANFIS-GA, and ANFIS are successfully implemented for SSC performance estimation. The RMSE evaluation showed a value of 0.0298 for ANFIS-GA and ANFIS-PCA and 0.0351 for ANFIS without variable selection. [ABSTRACT FROM AUTHOR]

Published

2024

46. Caught between two states: The compromise in acclimation of photosynthesis, transpiration and mesophyll conductance to different amplitudes of fluctuating irradiance.

Author

Durand, Maxime, Zhuang, Xin, Salmon, Yann, and Robson, T. Matthew

Subjects

*LEAF temperature, *PLANT performance, *ARABIDOPSIS thaliana, *ACCLIMATIZATION, *MAINTENANCE costs

Abstract

While dynamic regulation of photosynthesis in fluctuating light is increasingly recognized as an important driver of carbon uptake, acclimation to realistic irradiance fluctuations is still largely unexplored. We subjected Arabidopsis thaliana (L.) wild‐type and jac1 mutants to irradiance fluctuations with distinct amplitudes and average irradiance. We examined how irradiance fluctuations affected leaf structure, pigments and physiology. A wider amplitude of fluctuations produced a stronger acclimation response. Large reductions of leaf mass per area under fluctuating irradiance framed our interpretation of changes in photosynthetic capacity and mesophyll conductance as measured by three separate methods, in that photosynthetic investment increased markedly on a mass basis, but only a little on an area basis. Moreover, thermal imagery showed that leaf transpiration was four times higher under fluctuating irradiance. Leaves growing under fluctuating irradiance, although thinner, maintained their photosynthetic capacity, as measured through light‐ and CO2‐response curves; suggesting their photosynthesis may be more cost‐efficient than those under steady light, but overall may incur increased maintenance costs. This is especially relevant for plant performance globally because naturally fluctuating irradiance creates conflicting acclimation cues for photosynthesis and transpiration that may hinder progress towards ensuring food security under climate‐related extremes of water stress. Summary statement: We investigated photosynthesis acclimation and dynamics of leaf transpiration under specific light fluctuations in A. thaliana. The response was stronger for more intense fluctuations and showed a divergent response whereby photosynthesis is reduced but transpiration rose compared to steady light. [ABSTRACT FROM AUTHOR]

Published

2024

47. Shoot Growth Parameters of Potato Seedlings are Determined by Light and Temperature Conditions.

Author

Kacheyo, Olivia C., Schneider, Hannah M., de Vries, Michiel E., and Struik, Paul C.

Subjects

*POTATO seeds, *PLANT adaptation, *PLANT performance, *LEAF area, *LIGHT intensity, *TRANSPLANTING (Plant culture)

Abstract

Raising quality hybrid potato true seedlings — derived from hybrid true potato seeds (TPS) — for field transplanting is a critical aspect contributing to the success in cultivating field-transplanted hybrid potato seedling-based crops. Various critical seedling vigour attributes must be defined and enhanced to improve plant performance as well as plant response and adaptation to field conditions after field transplanting. Moreover, additional attributes besides leaf number and stem length should be defined to design selection criteria for "transplantability" of potato seedlings. To assess these attributes and their robustness under different environmental conditions, seedlings of hybrid genotypes were raised under contrasting daylengths, light intensities and temperature regimes, and combinations of these factors, and the effects of these factors (or factor combinations) on seedling vigour and its attributes were quantified. Increased light intensity and daylight integral (DLI) enhanced leaf parameters and increased biomass under long-day conditions, but seedlings did not show conclusive responses under short-day conditions in most attributes. Higher temperatures increased biomass and constant day and night temperatures enhanced compaction of shoot architecture as did higher light intensities — to a greater extent. These results highlight additional seedling vigour attributes including leaf area parameters and seedling biomass which should be utilised to determine "transplantability" of hybrid potato seedlings. Additionally, the results provide a starting point for further research on optimising hybrid seedling production for field transplanting. [ABSTRACT FROM AUTHOR]

Published

2024

48. Preparation of oil‐in‐water emulsions stabilized by faba bean protein–grape leaf polyphenol conjugates: pH‐, salt‐, heat‐, and freeze–thaw‐stability.

Author

Dursun Capar, Tugba, Iscimen, Elif Meltem, McClements, David Julian, Yalcin, Hasan, and Hayta, Mehmet

Subjects

*SODIUM caseinate, *EMULSIONS, *FAVA bean, *GRAPES, *PLANT proteins, *IONIC strength, *PLANT performance, *LIGHT scattering

Abstract

BACKGROUND: Plant proteins are being increasingly utilized as functional ingredients in foods because of their potential health, sustainability, and environmental benefits. However, their functionality is often worse than the synthetic or animal‐derived ingredients they are meant to replace. The functional performance of plant proteins can be improved by conjugating them with polyphenols. In this study, the formation and stability of oil‐in‐water emulsions prepared using faba bean protein–grape leaf polyphenol (FP‐GLP) conjugates as emulsifiers. Initially, FP‐GLP conjugates were formed using an ultrasound‐assisted alkali treatment. Then, corn oil‐in‐water emulsions were prepared using high‐intensity sonication (60% amplitude, 10 min) and the impacts of conjugate concentration, pH, ionic strength, freezing–thawing, and heating on their physicochemical properties and stability were determined. RESULTS: Microscopy and light scattering analysis showed that oil‐in‐water emulsions containing small oil droplets could be formed at conjugate concentrations of 2% and higher. The addition of salt reduced the electrostatic repulsion between the droplets, which increased their susceptibility to aggregation. Indeed, appreciable droplet aggregation was observed at ≥ 50 mmol/L sodium chloride. The freeze–thaw stability of emulsions prepared with protein–polyphenol conjugates was better than those prepared using the proteins alone. In addition, the emulsions stabilized by the conjugates had a higher viscosity than those prepared by proteins alone. CONCLUSION: This study showed that FP‐GLP conjugates are effective plant‐based emulsifiers for forming and stabilizing oil‐in‐water emulsions. Indeed, emulsions formed using these conjugates showed improved resistance to pH changes, heating, freezing, and salt addition. © 2024 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

49. Grapevine Pinot gris virus spreads in infected vineyards: latent infections have no direct impact on grape production.

Author

Messmer, Noemi, Bohnert, Patricia, Askani, Lars, Schumacher, Stefan, Voegele, Ralf T., and Fuchs, René

Subjects

*LATENT infection, *PINOT gris, *CREDIT spread, *PLANT performance, *VIRAL transmission

Abstract

Background: Grapevine Pinot gris virus (GPGV) infects grapevines worldwide and causes symptoms such as chlorotic mottling and deformations on leaves, stunted shoots and short panicles, or none of these symptoms if it appears as latent infection. So far, the consequences of GPGV infections for winegrowers are difficult to assess since important information such as plant performance at different GPGV infection levels and symptom expression are not fully clarified. Methods: In order to investigate the course of GPGV spread, annual visual evaluations and ELISA tests were conducted over 3–4 consecutive years in four GPGV-infected vineyards in southern Germany: GEM, HEC, NIM, and REI. The program PATCHY was used to analyze spatial disease patterns. Sanger sequencing was used to determine virus isolates in vines at different GPGV infection levels, to test their respective influence on symptom expression. Yield and GrapeScan (FTIR) analyses were conducted to test the impact of different GPGV infection levels and isolates on fruit quantity and quality. Results: GPGV infections significantly increased in all four vineyards (GEM 22–32%, HEC 50–99%, NIM 83–90%, REI 56–76%) with significant spreading patterns across and along rows. Specific symptom progression patterns were not observed. According to our results, the virus isolate has an influence on whether symptoms develop during a GPGV infection. While yield analyses revealed that yield losses only occur in symptomatic vines and range from 13 to 96% depending on the severity of symptoms, latent infections have no impact on grape production. No relevant effects of GPGV infections on must quality were observed. Conclusions: Secondary spread of GPGV was observed in all vineyards monitored, indicating vector-borne transmission that is likely to be accelerated by human viticultural management. GPGV should be further monitored to prevent the accumulation of detrimental symptomatic isolates. The results of this study can be used to assess the risk of GPGV to viticulture and should be considered when developing management strategies against the virus. [ABSTRACT FROM AUTHOR]

Published

2024

50. Best practices, errors, and perspectives of half a century of plant translocation in Italy.

Author

D'Agostino, Martina, Cao Pinna, Luigi, Carboni, Marta, Assini, Silvia, Bacchetta, Gianluigi, Bartolucci, Fabrizio, Brancaleoni, Lisa, Buldrini, Fabrizio, Carta, Angelino, Cerabolini, Bruno, Ceriani, Roberta Maria, Clementi, Umberto, Cogoni, Donatella, Conti, Fabio, Crosti, Roberto, Cuena‐Lombraña, Alba, De Vitis, Marcello, Di Giustino, Attilio, Fabrini, Giuseppe, and Farris, Emanuele

Subjects

*PLANT translocation, *AGAVES, *BEST practices, *GENE flow, *PLANT performance

Abstract

Conservation translocations are becoming common conservation practice, so there is an increasing need to understand the drivers of plant translocation performance through reviews of cases at global and regional levels. The establishment of the Italian Database of Plant Translocation (IDPlanT) provides the opportunity to review the techniques used in 186 plant translocation cases performed in the last 50 years in the heart of the Mediterranean Biodiversity Hotspot. We described techniques and information available in IDPlanT and used these data to identify drivers of translocation outcomes. We tested the effect of 15 variables on survival of translocated propagules as of the last monitoring date with binomial logistic mixed‐effect models. Eleven variables significantly affected survival of transplants: life form, site protection, material source, number of source populations, propagation methods, propagule life stage, planting methods, habitat suitability assessment, site preparation, aftercare, and costs. The integration of vegetation studies in the selection of suitable planting sites significantly increased the success of translocation efforts. Although posttranslocation watering had a generally positive effect on translocation outcome, other aftercare techniques did not always increase transplant survival. Finally, we found that how funds were spent appeared to be more important than the actual amount spent. Plant translocations in Italy and in the Mediterranean area should account for the complexity of speciation, gene flow, and plant migrations that has led to local adaptations and has important implications for the choice and constitution of source material. [ABSTRACT FROM AUTHOR]

Published

2024