Your search keyword '"Photosynthesis"' showing total 30,032 results

1. Impact of zinc and molybdenum, in bulk and nano forms, on red bean: photosynthesis, root traits, nitrate reduction, antioxidant enzymes, and yield under drought stress.

Author

Jahangirinia, Elham, Eisvand, Hamid Reza, Daneshvar, Mashala, Akbarpour, Omidali, and Nasrollahi, Ali Heidar

Subjects

*NITRATE reductase, *PHASE transitions, *PLANT nutrition, *DENITRIFICATION, *PLANT nutrients, *MOLYBDENUM, *DROUGHT management

Abstract

The limitation of water and unfavorable soil conditions for plant's nutrient absorption present a hurdle to the growth and yield of red beans under drought stress conditions. Micronutrients, particularly zinc and molybdenum, show promise in mitigating drought effects. Various irrigation levels (100% and 70% of field capacity) and nutrient application methods were tested in the field (two locations) and the greenhouse in 2022. Parameters such as photosynthesis, gas exchange, root characteristics, nitrate reductase, antioxidant enzymes, and yield were evaluated. The combination of nano zinc priming (NZnP 150 mg L−1) and foliar spraying of nano zinc (FSNZn 0.04 mg L−1) at 100% field capacity resulted in the highest photosynthesis, gas exchange, and yield. Water stress increased the activity of antioxidant enzymes. In greenhouse test, NZnP (150 mg L−1) + FSNZn (0.04 mg L−1) at 100% field capacity promoted maximum root length and nitrate reductase activity. Overall, NZnP + FSNZn at 100% field capacity proved most effective for morphological and biochemical root characteristics and yield. Drought stress reduced red bean yield, but NZnP + FSNZn mitigated some adverse effects. Nano forms of zinc and molybdenum were more effective in mitigating drought stress. Location significantly influenced plant development, with lower temperatures delaying reproductive phase transition, leading to better vegetative and reproductive traits compared to the location with higher temperature. [ABSTRACT FROM AUTHOR]

Published

2024

2. Identifying the gene responsible for non‐photochemical quenching reversal in Phaeodactylum tricornutum.

Author

Ware, Maxwell A., Paton, Andrew J., Bai, Yu, Kassaw, Tessema, Lohr, Martin, and Peers, Graham

Abstract

SUMMARY Algae such as diatoms and haptophytes have distinct photosynthetic pigments from plants, including a novel set of carotenoids. This includes a primary xanthophyll cycle comprised of diadinoxanthin and its de‐epoxidation product diatoxanthin that enables the switch between light harvesting and non‐photochemical quenching (NPQ)‐mediated dissipation of light energy. The enzyme responsible for the reversal of this cycle was previously unknown. Here, we identified zeaxanthin epoxidase 3 (ZEP3) from Phaeodactylum tricornutum as the candidate diatoxanthin epoxidase. Knocking out the ZEP3 gene caused a loss of rapidly reversible NPQ following saturating light exposure. This correlated with the maintenance of high concentrations of diatoxanthin during recovery in low light. Xanthophyll cycling and NPQ relaxation were restored via complementation of the wild‐type ZEP3 gene. The zep3 knockout strains showed reduced photosynthetic rates at higher light fluxes and reduced specific growth rate in variable light regimes, likely due to the mutant strains becoming locked in a light energy dissipation state. We were able to toggle the level of NPQ capacity in a time and dose dependent manner by placing the ZEP3 gene under the control of a β‐estradiol inducible promoter. Identification of this gene provides a deeper understanding of the diversification of photosynthetic control in algae compared to plants and suggests a potential target to improve the productivity of industrial‐scale cultures. [ABSTRACT FROM AUTHOR]

Published

2024

3. Harnessing microbes as sun cream against high light stress.

Author

Villano, Filippo, Balestrini, Raffaella, Nerva, Luca, and Chitarra, Walter

Abstract

Summary Plants rely on solar energy for growth through photosynthesis, yet excessive light intensity can induce physiological damage. Despite the considerable harm, inadequate attention has been directed toward understanding how plant‐associated microorganisms mitigate this stress, and the impact of high light intensity on plant microbial communities remains underexplored. Through this Viewpoint, we aim to highlight the potential of microbial communities to enhance plant resilience and understand how light stress can shape plant microbiome. A full understanding of these dynamics is essential to design strategies that take advantage of microbial assistance to plants under light stress and to effectively manage the impact of changing light conditions on plant–microbe interactions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Photosynthetic characteristics and genetic mapping of a yellow-green leaf mutant jym165 in soybean.

Author

Zhao, Yu, Zhu, Mengxue, Gao, Hongtao, Zhou, Yonggang, Yao, Wenbo, Zhao, Yan, Zhang, Wenping, Feng, Chen, Li, Yaxin, Jin, Yan, and Xu, Keheng

Abstract

Background: Leaves are important sites for photosynthesis and can convert inorganic substances into organic matter. Photosynthetic performance is an important factor affecting crop yield. Leaf colour is closely related to photosynthesis, and leaf colour mutants are considered an ideal material for studying photosynthesis. Results: We obtained a yellow-green leaf mutant jym165, using ethyl methane sulfonate (EMS) mutagenesis. Physiological and biochemical analyses indicated that the contents of chlorophyll a, chlorophyll b, carotenoids, and total chlorophyll in the jym165 mutant decreased significantly compared with those in Jiyu47 (JY47). The abnormal chloroplast development of jym165 led to a decrease in net photosynthetic rate and starch content compared with that of JY47. However, quality traits analysis showed that the sum of oil and protein contents in jym165 was higher than that in JY47. In addition, the regional yield (seed spacing: 5 cm) of jym165 increased by 2.42% compared with that of JY47 under high planting density. Comparative transcriptome analysis showed that the yellow-green leaf phenotype was closely related to photosynthesis and starch and sugar metabolism pathways. Genetic analysis suggests that the yellow-green leaf phenotype is controlled by a single recessive nuclear gene. Using Mutmap sequencing, the candidate regions related of leaf colour was narrowed to 3.44 Mb on Chr 10. Conclusions: Abnormal chloroplast development in yellow-green mutants leads to a decrease in the photosynthetic pigment content and net photosynthetic rate, which affects the soybean photosynthesis pathway and starch and sugar metabolism pathways. Moreover, it has the potentiality to increase soybean yield under dense planting conditions. This study provides a useful reference for studying the molecular mechanisms underlying photosynthesis in soybean. [ABSTRACT FROM AUTHOR]

Published

2024

5. Fast dehydration reduces bundle sheath conductance in C4 maize and sorghum.

Author

Bellasio, Chandra, Stuart‐Williams, Hilary, Farquhar, Graham D., and Flexas, Jaume

Subjects

*WATER efficiency, *COMPOSITION of water, *WATER-gas, *PHYSIOLOGY, *BIOCHEMICAL models

Abstract

Summary In the face of anthropogenic warming, drought poses an escalating threat to food production. C4 plants offer promise in addressing this threat. C4 leaves operate a biochemical CO2 concentrating mechanism that exchanges metabolites between two partially isolated compartments (mesophyll and bundle sheath), which confers high‐productivity potential in hot climates boosting water use efficiency. However, when C4 leaves experience dehydration, photosynthesis plummets. This paper explores the physiological mechanisms behind this decline. In a fast dehydration experiment, we measured the fluxes and isotopic composition of water and CO2 in the gas exchanged by leaves, and we interpreted results using a novel biochemical model and analysis of elasticity. Our findings show that, while CO2 supply to the mesophyll and to the bundle sheath persisted during dehydration, there was a decrease in CO2 conductance at the bundle sheath‐mesophyll interface. We interpret this as causing a slowdown of intercellular metabolite exchange – an essential feature of C4 photosynthesis. This would impede the supply of reducing power to the bundle sheath, leading to phosphoglycerate accumulation and feedback inhibition of Rubisco carboxylation. The interplay between this rapid sensitivity and the effectiveness of coping strategies that C4 plants deploy may be an overlooked driver of their competitive performance. [ABSTRACT FROM AUTHOR]

Published

2024

6. Insights into physiological roles of flavonoids in plant cold acclimation.

Author

Kitashova, Anastasia, Lehmann, Martin, Schwenkert, Serena, Münch, Maximilian, Leister, Dario, and Nägele, Thomas

Subjects

*PLANT photorespiration, *FLAVONOIDS, *PROTEIN stability, *PLANT metabolites, *ARABIDOPSIS thaliana

Abstract

SUMMARY Flavonoids represent a diverse group of plant specialised metabolites which are also discussed in the context of dietary health and inflammatory response. Numerous studies have revealed that flavonoids play a central role in plant acclimation to abiotic factors like low temperature or high light, but their structural and functional diversity frequently prevents a detailed mechanistic understanding. Further complexity in analysing flavonoid metabolism arises from the different subcellular compartments which are involved in biosynthesis and storage. In the present study, non‐aqueous fractionation of Arabidopsis leaf tissue was combined with metabolomics and proteomics analysis to reveal the effects of flavonoid deficiencies on subcellular metabolism during cold acclimation. During the first 3 days of a 2‐week cold acclimation period, flavonoid deficiency was observed to affect pyruvate, citrate and glutamate metabolism which indicated a role in stabilising C/N metabolism and photosynthesis. Also, tetrahydrofolate metabolism was found to be affected, which had significant effects on the proteome of the photorespiratory pathway. In the late stage of cold acclimation, flavonoid deficiency was found to affect protein stability, folding and proteasomal degradation, which resulted in a significant decrease in total protein amounts in both mutants. In summary, these findings suggest that flavonoid metabolism plays different roles in the early and late stages of plant cold acclimation and significantly contributes to establishing a new protein homeostasis in a changing environment. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effects of combined application of phosphorus and zinc on growth and physiological characteristics of apple rootstock M9-T337 seedlings (Malus domestica Borkh.).

Author

Xian, Xulin, Sun, Wentai, Zhang, Zhongxing, Gao, Yanlong, Li, Cailong, Ding, Liang, and Wang, Yanxiu

Abstract

Background: Balancing nutrient application is crucial for plant growth. However, excessive fertilizer use, especially imbalanced applications of macronutrients such as phosphate (P), can hinder plant uptake of micronutrients. Balanced P and zinc (Zn) are vital for apple yield and quality, and apple trees are highly sensitive to deficiencies in these nutrients. Therefore, this study was conducted in May 2022, employed a sand culture experiment to investigate the effects of varying P and Zn levels on the growth phenotype, photosynthetic capacity, antioxidant enzyme activity, sugar composition, endogenous hormone levels, and nutrient absorption and utilization of M9-T337 seedlings. Three levels of P (low, medium, high) and three levels of Zn (low, medium, high) were combined to create a total of nine distinct treatment. Results: The results indicate that combined P and Zn fertilization at various levels exerts either synergistic or antagonistic effects on the growth, nutrient absorption, and utilization of M9-T337 seedlings. Compared to low and medium levels of P, a combination of high P (4 mmol·L−1) and an adequate amount of Zn significantly enhanced plant growth, root system development, and the microstructure of leaves. Notably, seedlings treated with high P and low Zn (HPLZn) reached a height 1.54 times that of the medium P and medium Zn (MPMZn, control). Physiological indicators under HP conditions revealed significant increases in antioxidant enzyme activity, leaf water retention, photosynthetic pigment concentration, osmotic adjustment substances, and the contents of glucose, sucrose, fructose, endogenous hormones, as well as P and Zn accumulation in the leaves, compared to the control. However, an increase in Zn application led to a declining trend in these parameters. Specifically, the HPLZn treatment exhibited substantial increases in Net photosynthetic rate (Pn), Total chlorophyll (Chl a + b), glucose, fructose, sucrose, and Auxin(IAA), with increments of 7.12%, 27.32%, 11.40%, 23.20%, 16.67%, and 55.11%, respectively, compared to the control. Conclusion: Based on the comprehensive ranking from principal component analysis, the combination of HP (4 mmol·L−1) and LZn (0.5 µmol·L−1) was found to be the most effective in enhancing the antioxidant capacity, sugar accumulation, osmotic regulation ability, photosynthetic capacity, endogenous hormone levels, as well as P and Zn nutrient absorption and utilization in M9-T337 seedlings. [ABSTRACT FROM AUTHOR]

Published

2024

8. Effect of Macronutrients on Recombinant mCherry Production by Microalga.

Author

Arias, Cesar Andres Diaz, Matsudo, Marcelo Chuei, Ferreira‐Camargo, Livia Seno, Molino, João Vitor Dutra, Mayfield, Stephen Patrick, and de Carvalho, João Carlos Monteiro

Subjects

*RECOMBINANT proteins, *CHLAMYDOMONAS reinhardtii, *CELL growth, *EXPERIMENTAL design, *ACETATES, *CHLAMYDOMONAS

Abstract

This study sought to evaluate the influence of five macronutrients (acetate, calcium, sulfate, nitrogen, and phosphate) on the cell growth and heterologous mCherry protein production by Chlamydomonas reinhardtii. In the first step, three nitrogen (N) sources were tested (NH4NO3, NaNO3, and NH4Cl), and NH4NO3 was selected as N source for the following step, due to the best results for mCherry protein production. In the second step, a central composite design 25 was employed to evaluate the effect of the five macronutrients. Although all nutrients had effect on maximum biomass concentration, only acetate, nitrogen, and phosphate showed to influence mCherry protein production. By employing the experimental design with small‐scale culture in multiplates and multivariable regression, it was possible to achieve 12 % increase for recombinant protein production. [ABSTRACT FROM AUTHOR]

Published

2024

9. Towards chlorocytes for therapeutic intravascular photosynthesis.

Author

Vargas-Torres, Valentina, Becerra, Daniela, Boric, Mauricio P., and Egaña, José Tomás

Subjects

*CARDIOPULMONARY system, *AEROBIC metabolism, *CARBON dioxide, *LOCAL government, *MICROALGAE

Abstract

Aerobic metabolism relies on external oxygen production through photosynthesis and its subsequent transport into each cell of the body via the cardiorespiratory system. This mechanism has successfully evolved over millions of years, enabling animals to inhabit most environments on Earth. However, the insufficient oxygen supply leads to several clinical problems, ranging from non-healing wounds to tumor resistance to therapy. Given that photosynthetic microorganisms are capable of producing oxygen and removing carbon dioxide from the environment, over the last decade, several groups worldwide have proposed their potential use as an alternative tissue oxygenation approach. While most studies have demonstrated safety and efficacy after local tissue administration, recent studies have also suggested that systemic administration could trigger intravascular photosynthesis. If successful, the development of a new generation of circulating cells, known as chlorocytes, may partially replace the role of erythrocytes in gas exchange within the body, without relying on external supply and vascular flow. This work reviews the existing literature on local and systemic administration of photosynthetic microorganisms, highlighting the main challenges in the field and potential solutions to unleash the enormous potential clinical impact of chlorocytes and intravascular photosynthesis. Key points: • Circulating photosynthetic microorganisms could deliver oxygen to tissues • Microalgae and cyanobacteria have shown safety and efficacy for oxygen delivery • Several key challenges need to be addressed for the clinical success of chlorocytes [ABSTRACT FROM AUTHOR]

Published

2024

10. A protein blueprint of the diatom CO2-fixing organelle.

Author

Nam, Onyou, Musiał, Sabina, Demulder, Manon, McKenzie, Caroline, Dowle, Adam, Dowson, Matthew, Barrett, James, Blaza, James N., Engel, Benjamin D., and Mackinder, Luke C.M.

Subjects

*CARBON fixation, *CARBON dioxide, *CONVERGENT evolution, *PROTEIN-protein interactions, *DIATOMS

Abstract

Diatoms are central to the global carbon cycle. At the heart of diatom carbon fixation is an overlooked organelle called the pyrenoid, where concentrated CO 2 is delivered to densely packed Rubisco. Diatom pyrenoids fix approximately one-fifth of global CO 2 , but the protein composition of this organelle is largely unknown. Using fluorescence protein tagging and affinity purification-mass spectrometry, we generate a high-confidence spatially defined protein-protein interaction network for the diatom pyrenoid. Within our pyrenoid interaction network are 10 proteins with previously unknown functions. We show that six of these form a shell that encapsulates the Rubisco matrix and is critical for pyrenoid structural integrity, shape, and function. Although not conserved at a sequence or structural level, the diatom pyrenoid shares some architectural similarities to prokaryotic carboxysomes. Collectively, our results support the convergent evolution of pyrenoids across the two main plastid lineages and uncover a major structural and functional component of global CO 2 fixation. [Display omitted] • A spatial interaction network reveals 10 previously unknown diatom pyrenoid proteins • Six Shell proteins encapsulate the pyrenoids of diatoms • Shell1/2 and Shell4 are essential for efficient CO 2 fixation and pyrenoid architecture • Shell proteins are widely conserved in major phytoplankton primary producers A conserved family in the protein interaction network of the CO 2 -fixing pyrenoid of diatoms forms a pyrenoid-encapsulating layer that is essential for organelle architecture and efficient CO 2 fixation. [ABSTRACT FROM AUTHOR]

Published

2024

11. Diatom pyrenoids are encased in a protein shell that enables efficient CO2 fixation.

Author

Shimakawa, Ginga, Demulder, Manon, Flori, Serena, Kawamoto, Akihiro, Tsuji, Yoshinori, Nawaly, Hermanus, Tanaka, Atsuko, Tohda, Rei, Ota, Tadayoshi, Matsui, Hiroaki, Morishima, Natsumi, Okubo, Ryosuke, Wietrzynski, Wojciech, Lamm, Lorenz, Righetto, Ricardo D., Uwizeye, Clarisse, Gallet, Benoit, Jouneau, Pierre-Henri, Gerle, Christoph, and Kurisu, Genji

Subjects

*CARBON fixation, *FOCUSED ion beams, *CARBON dioxide, *MARINE algae, *PROTEOMICS, *PHAEODACTYLUM tricornutum

Abstract

Pyrenoids are subcompartments of algal chloroplasts that increase the efficiency of Rubisco-driven CO 2 fixation. Diatoms fix up to 20% of global CO 2 , but their pyrenoids remain poorly characterized. Here, we used in vivo photo-crosslinking to identify pyrenoid shell (PyShell) proteins, which we localized to the pyrenoid periphery of model pennate and centric diatoms, Phaeodactylum tricornutum and Thalassiosira pseudonana. In situ cryo-electron tomography revealed that pyrenoids of both diatom species are encased in a lattice-like protein sheath. Single-particle cryo-EM yielded a 2.4-Å-resolution structure of an in vitro TpPyShell1 lattice, which showed how protein subunits interlock. T. pseudonana TpPyShell1/2 knockout mutants had no PyShell sheath, altered pyrenoid morphology, and a high-CO 2 requiring phenotype, with reduced photosynthetic efficiency and impaired growth under standard atmospheric conditions. The structure and function of the diatom PyShell provide a molecular view of how CO 2 is assimilated in the ocean, a critical ecosystem undergoing rapid change. [Display omitted] • Identification of the PyShell, a protein sheath that surrounds diatom pyrenoids • Multiscale imaging of PyShell lattices from in situ architecture to in vitro structure • PyShell knockout disrupts pyrenoid morphology and function, impairing cell growth • The PyShell is widely conserved, enabling much of the ocean's CO 2 fixation Identification and characterization of a protein lattice around the pyrenoid compartments of diatoms reveals that these prolific marine algae evolved a distinct pyrenoid architecture to promote Rubisco's CO 2 -fixing activity. [ABSTRACT FROM AUTHOR]

Published

2024

12. Hydrogen isotope fractionation in plants with C3, C4, and CAM CO2 fixation.

Author

Schuler, Philipp, Rehmann, Oliver, Vitali, Valentina, Saurer, Matthias, Oettli, Manuela, Cernusak, Lucas A., Gessler, Arthur, Buchmann, Nina, and Lehmann, Marco M.

Subjects

*CRASSULACEAN acid metabolism, *HYDROGEN isotopes, *ORGANIC compounds, *PLANT metabolism, *ISOTOPIC fractionation

Abstract

Summary: Measurements of stable isotope ratios in organic compounds are widely used tools for plant ecophysiological studies. However, the complexity of the processes involved in shaping hydrogen isotope values (δ2H) in plant carbohydrates has limited its broader application.To investigate the underlying biochemical processes responsible for 2H fractionation among water, sugars, and cellulose in leaves, we studied the three main CO2 fixation pathways (C3, C4, and CAM) and their response to changes in temperature and vapor pressure deficit (VPD).We show significant differences in autotrophic 2H fractionation (εA) from water to sugar among the pathways and their response to changes in air temperature and VPD. The strong 2H depleting εA in C3 plants is likely driven by the photosynthetic H+ production within the thylakoids, a reaction that is spatially separated in C4 and strongly reduced in CAM plants, leading to the absence of 2H depletion in the latter two types. By contrast, we found that the heterotrophic 2H‐fractionation (εH) from sugar to cellulose was very similar among the three pathways and is likely driven by the plant's metabolism, rather than by isotopic exchange with leaf water.Our study offers new insights into the biochemical drivers of 2H fractionation in plant carbohydrates. [ABSTRACT FROM AUTHOR]

Published

2024

13. Modulating Yeager Adsorption Configuration of O2 Through Cd Doping in Zn3In2S6 for Photosynthesis of H2O2.

Author

Jiao, Dongxu, Ding, Chunsheng, Xu, Minghua, Ruan, Xiaowen, Ravi, Sai Kishore, and Cui, Xiaoqiang

Abstract

The photocatalytic oxygen reduction reaction (ORR) is a key pathway for producing hydrogen peroxide (H2O2). While most previous studies have focused on the two‐step 2e− ORR process, the one‐step two‐electron ORR route offers thermodynamic and kinetic advantages that can significantly enhance 2e− ORR activity and selectivity. In this study, a photocatalyst design is reported by incorporating cadmium into vacancy‐rich Zn3In2S6 (Cd‐SV/ZIS). This catalyst enables H2O2 production via a one‐step 2e− ORR process without the use of sacrificial agents, achieving a high H2O2 yield of 39.42 µmol g−1 min−1 under UV–vis light irradiation, outperforming most reported ZIS‐based photocatalysts. Theoretical simulations and experimental results demonstrate that Cd doping improves the carrier kinetics of the catalyst, broadens its light absorption range, and promotes the Yeager adsorption configuration of O2, leading to highly active and selective H2O2 generation. This study provides insights into the design of efficient ZIS‐based photocatalysts for H2O2 production. [ABSTRACT FROM AUTHOR]

Published

2024

14. Protective effects of the exogenous application of salicylic acid and chitosan on chromium-induced photosynthetic capacity and osmotic adjustment in Aconitum napellus.

Author

Ramzan, Musarrat, javed, Tayyaba, Hassan, Ariba, Ahmed, Muhammad Zaheer, Ashraf, Hina, Shah, Anis Ali, Iftikhar, Muhammad, El-Sheikh, Mohamed A., and Raja, Vaseem

Abstract

Chitosan (CTS) is recognized for enhancing a plant’s resilience to various environmental stresses, such as salinity and drought. Moreover, salicylic acid (SA) is acknowledged as a growth regulator involved in addressing metal toxicity. However, the effectiveness of both compounds in mitigating Cr-induced stress has remained relatively unexplored, especially in the case of Aconitum napellus, a medicinally and floricultural important plant. Therefore, the primary objective of this study was to investigate the potential of CTS and SA in alleviating chromium (Cr)-induced stress in A. napellus. To address these research questions, we conducted a controlled experiment using potted plants to evaluate the individual and combined impacts of CTS and SA on plants exposed to Cr stress. Foliar application of CTS (0.4 g/L) or SA (0.25 mmol/L) led to significant improvements in the growth, chlorophyll content, fluorescence, and photosynthetic traits of A. napellus plants under Cr stress. The most notable effects were observed with the combined application of CTS and SA, resulting in increases in various morphological parameters, such as shoot length (2.89% and 7.02%) and root length (27.75% and 3.36%) under the Cr 1 and Cr 2 treatments, respectively. Additionally, several physiological parameters, such as chlorophyll a (762.5% and 145.56%), chlorophyll b (762.5% and 145.56%), carotenoid (17.03% and 28.57%), and anthocyanin (112.01% and 47.96%) contents, were notably improved under the Cr 1 and Cr 2 treatments, respectively. Moreover, the combined treatment of CTS and SA improved the fluorescence parameters while decreasing the levels of enzymatic antioxidants such as catalase (27.59% and 43.79%, respectively). The application also notably increased osmoprotectant parameters, such as the total protein content (54.11% and 20.07%) and the total soluble sugar content (78.17% and 49.82%) in the leaves of A. napellus in the Cr 1 and 2 treatments, respectively. In summary, these results strongly suggest that the simultaneous use of exogenous CTS and SA is an effective strategy for alleviating the detrimental effects of Cr stress on A. napellus. This integrated approach opens promising avenues for further exploration and potential implementation within agricultural production systems.Key message: This explains the interactive role of chitosan and salicylic acid in alleviating chromium stress in Aconitum napellus. [ABSTRACT FROM AUTHOR]

Published

2024

15. Climate change and exotic pathogens shift carbon allocation in Mediterranean mixed forests.

Author

Gaytán, Álvaro, Matías, Luis, Godoy, Óscar, Pérez‐Ramos, Ignacio M., Homet, Pablo, Moreira, Xoaquín, and Gómez‐Aparicio, Lorena

Subjects

*CARBON cycle, *RAINFALL, *ECOLOGICAL disturbances, *CORK oak, *MIXED forests

Abstract

Forecasting the effects of global change drivers on ecosystems is one of the most pressing challenges for scientists worldwide. Particularly, climate change and exotic pathogens might have a large impact on plant community dynamics and ecosystem functioning through changes in carbon uptake and sinks. Nevertheless, we still have a poor understanding of the combined effects of these two drivers on plant communities. Here, we explored the impact of rainfall reduction and exotic pathogens on the carbon balance of Mediterranean tree species. For this, we performed a 3‐year field experiment taking advantage of rainfall exclusion infrastructures (30% exclusion) installed in the southernmost European oak forests invaded by the aggressive exotic pathogen Phytophthora cinnamomi. We measured a set of 10 variables representative of tree carbon sources (photosynthetic rates) and sinks (primary production, reproduction, defence, and reserves) in adult trees of three species in two forest types: closed forests of Quercus suber and Q. canariensis, and open woodlands of Q. suber and Olea europaea. We found a large variability in the sensitivity of the different carbon sources and sinks to the effects of drought and pathogens, from variables highly sensitive to both factors (carbon fixation and reproduction, root chemistry) to variables only responsive to drought (litter production) or totally unresponsive (tree trunk, leaf chemistry). Although negative effects predominated, positive effects of rainfall exclusion were also detected in wet years, likely due to a reduction of pathogen abundance in drier soil. Trade‐offs between carbon sinks appeared in all tree species, but rainfall exclusion only modified trade‐offs in Q. suber, the species most susceptible to P. cinnamomi. Synthesis. We provide evidence on the complexity of the combined effects of abiotic (drought) and biotic (pathogens) global change drivers on carbon source and sinks of adult trees, including both negative direct effects and positive indirect effects. Our results showed that these effects varied among co‐existing species, particularly for carbon sinks directly related to tree demography (reproduction). Therefore, long‐term changes in the structure of Mediterranean mixed forests might be expected towards the dominance of species highly resistant to both drought and pathogens. [ABSTRACT FROM AUTHOR]

Published

2024

16. Protective effects of the exogenous application of salicylic acid and chitosan on chromium-induced photosynthetic capacity and osmotic adjustment in Aconitum napellus.

Author

Ramzan, Musarrat, javed, Tayyaba, Hassan, Ariba, Ahmed, Muhammad Zaheer, Ashraf, Hina, Shah, Anis Ali, Iftikhar, Muhammad, El-Sheikh, Mohamed A., and Raja, Vaseem

Subjects

*MONKSHOODS, *GROWTH regulators, *POTTED plants, *RESEARCH questions, *HEAVY metals, *SALICYLIC acid, *CHLOROPHYLL spectra

Abstract

Chitosan (CTS) is recognized for enhancing a plant's resilience to various environmental stresses, such as salinity and drought. Moreover, salicylic acid (SA) is acknowledged as a growth regulator involved in addressing metal toxicity. However, the effectiveness of both compounds in mitigating Cr-induced stress has remained relatively unexplored, especially in the case of Aconitum napellus, a medicinally and floricultural important plant. Therefore, the primary objective of this study was to investigate the potential of CTS and SA in alleviating chromium (Cr)-induced stress in A. napellus. To address these research questions, we conducted a controlled experiment using potted plants to evaluate the individual and combined impacts of CTS and SA on plants exposed to Cr stress. Foliar application of CTS (0.4 g/L) or SA (0.25 mmol/L) led to significant improvements in the growth, chlorophyll content, fluorescence, and photosynthetic traits of A. napellus plants under Cr stress. The most notable effects were observed with the combined application of CTS and SA, resulting in increases in various morphological parameters, such as shoot length (2.89% and 7.02%) and root length (27.75% and 3.36%) under the Cr 1 and Cr 2 treatments, respectively. Additionally, several physiological parameters, such as chlorophyll a (762.5% and 145.56%), chlorophyll b (762.5% and 145.56%), carotenoid (17.03% and 28.57%), and anthocyanin (112.01% and 47.96%) contents, were notably improved under the Cr 1 and Cr 2 treatments, respectively. Moreover, the combined treatment of CTS and SA improved the fluorescence parameters while decreasing the levels of enzymatic antioxidants such as catalase (27.59% and 43.79%, respectively). The application also notably increased osmoprotectant parameters, such as the total protein content (54.11% and 20.07%) and the total soluble sugar content (78.17% and 49.82%) in the leaves of A. napellus in the Cr 1 and 2 treatments, respectively. In summary, these results strongly suggest that the simultaneous use of exogenous CTS and SA is an effective strategy for alleviating the detrimental effects of Cr stress on A. napellus. This integrated approach opens promising avenues for further exploration and potential implementation within agricultural production systems. Key message: This explains the interactive role of chitosan and salicylic acid in alleviating chromium stress in Aconitum napellus. [ABSTRACT FROM AUTHOR]

Published

2024

17. Symbiodiniaceae‐Derived Fatty Acids Are Stored Differentially Across Giant Clam Species and Organs.

Author

Neves, Júlia R., Taniguchi, Satie, Bícego, Márcia C., Sumida, Paulo Y. G., and Mies, Miguel

Subjects

*CORAL reefs & islands, *FATTY acids, *GAS chromatography, *CORALS, *FOOD supply

Abstract

ABSTRACT Giant clams are invertebrates that form mutualistic associations with Symbiodiniaceae dinoflagellates. Despite their ecological significance, gaps persist regarding our understanding of their trophic ecology. Specifically, it is unknown whether Symbiodiniaceae‐derived photosynthates are metabolized differently according to species and organ. Therefore, we maintained Tridacna derasa and T. noae for 3 months in a well‐lit recirculated system without food supply. Samples were taken from eight organs and underwent lipid extraction and fatty acid esterification before analysis of three symbiont‐derived fatty acids (stearidonic acid, docosapentaenoic acid, and docosahexaenoic acid—SDA, DPA, and DHA, respectively) using gas chromatography. Results show considerable variation in fatty acids concentration among species and organs. SDA was found in higher concentrations in T. noae, especially in the adductor muscle. DPA was detected in low concentrations across T. noae organs and absent for T. derasa. DHA did not vary significantly among species and organs. Our findings indicate that Symbiodiniaceae supply clams with fatty acids, which are stored differentially according to species and organs. This demonstrates that these compounds are translocated to multiple organs throughout the complex giant clam anatomical system, in contrast to simpler hosts like corals. These results advance our understanding of the physiological dynamics of the mollusk‐algae association. [ABSTRACT FROM AUTHOR]

Published

2024

18. Red-light-dependent chlorophyll synthesis kindles photosynthetic recovery of chlorotic dormant cyanobacteria using a dark-operative enzyme.

Author

Xu, Hai-Feng, Yu, Chen, Bai, Yang, Zuo, Ai-Wei, Ye, Ying-Tong, Liu, Yan-Ru, Li, Zheng-Ke, Dai, Guo-Zheng, Chen, Min, and Qiu, Bao-Sheng

Subjects

*TRANSCRIPTION factors, *EXTREME environments, *CHLOROSIS (Plants), *CYANOBACTERIA, *CHLOROPHYLL

Abstract

Chlorosis dormancy resulting from nitrogen starvation and its resuscitation upon available nitrogen contributes greatly to the fitness of cyanobacterial population under nitrogen-fluctuating environments. The reinstallation of the photosynthetic machinery is a key process for resuscitation from a chlorotic dormant state; however, the underlying regulatory mechanism is still elusive. Here, we reported that red light is essential for re-greening chlorotic Synechocystis sp. PCC 6803 (a non-diazotrophic cyanobacterium) after nitrogen supplement under weak light conditions. The expression of dark-operative protochlorophyllide reductase (DPOR) governed by the transcriptional factor RpaB was strikingly induced by red light in chlorotic cells, and its deficient mutant lost the capability of resuscitation from a dormant state, indicating DPOR catalyzing chlorophyll synthesis is a key step in the photosynthetic recovery of dormant cyanobacteria. Although light-dependent protochlorophyllide reductase is widely considered as a master switch in photomorphogenesis, this study unravels the primitive DPOR as a spark to activate the photosynthetic recovery of chlorotic dormant cyanobacteria. These findings provide new insight into the biological significance of DPOR in cyanobacteria and even some plants thriving in extreme environments. [Display omitted] • Red light activates photosynthesis of dormant cyanobacteria in nitrogen chlorosis • DPOR is required for weak red-light-induced resuscitation of chlorotic cells • The transcription factor RpaB regulates photosynthetic recovery • RpaB induction of the DPOR subunit ChlL is required for recovery Xu et al. unravel the key role of red light and the dark-operative protochlorophyllide reductase (DPOR) in the re-greening of dormant cyanobacteria in nitrogen chlorosis. These findings provide new insight into the biological significance of DPOR in cyanobacteria and some plants thriving in extreme environments. [ABSTRACT FROM AUTHOR]

Published

2024

19. Characterization of Low-Temperature Sensitivity and Chlorophyll Fluorescence in Yellow Leaf Mutants of Tomato.

Author

Ji, Shujing, Zhang, Yifan, Xu, Minghua, Zhao, Mingrui, Chen, Huixin, Lu, Yongen, Pang, Shengqun, and Xu, Wei

Abstract

Leaf color mutants serve as valuable models for studying the regulation of plant photosynthesis, alternations in chloroplast structure and function, and the analysis of associated gene functions. A yellow leaf mutant, ylm, was separated from the wild tomato M82, with its yellowing intensity influenced by low temperature. To assess the low-temperature sensitivity of this mutant, the photosynthetic and chlorophyll fluorescence responses of ylm and M82 were examined under different temperature conditions. In this study, the ylm mutant and its wild type, M82, were exposed to three temperature levels, 16, 25, and 30 °C, for 48 h. The impact of these temperature treatments on leaf color change, chlorophyll content, photosynthetic performance, and chlorophyll fluorescence characteristics of mutant ylm was investigated. The results revealed the following: (1) After exposure to 16 °C, the ylm mutant exhibited significant yellowing, a marked reduction in chlorophyll content, and a notable increase in carotenoid content. At 25 °C, the differences were less pronounced, and at 30 °C, the differences between ylm and M82 were minimal. (2) The photosynthetic rate of the ylm mutant was lower than that of M82 at 16 °C, with the gap narrowing as temperature increased, eventually converging at higher temperatures. (3) The fluorescence transient curve (OJIP) of the ylm mutant differed significantly from that of M82 at 16 °C, with higher fluorescence intensity at the O point and lower intensity at the J, I, and P points. This difference was decreased at 25 °C and nearly disappeared at 30 °C. Additionally, the Fv/Fm, Fv/Fo, PIabs, PItotal, ABS/CSm, TRo/CSm, and ETo/CSm values of ylm were lower than those of M82 at 16 °C, while the ABS/RC and DIo/RC values were higher, with no significant differences observed at 30 °C. These findings suggest that the ylm mutant is highly sensitive to low temperature, with pronounced yellowing, reduced light energy absorption and capture efficiency, and impaired electron transport at lower temperature. [ABSTRACT FROM AUTHOR]

Published

2024

20. Green Light Drives Embryonic Photosynthesis and Protein Accumulation in Cotyledons of Developing Pea (Pisum sativum L.) Seeds.

Author

Stepanova, Nataliia, Tarakhovskaya, Elena, Soboleva, Alena, Orlova, Anastasia, Basnet, Aditi, Smolenskaya, Anastasia, Frolova, Nadezhda, Bilova, Tatiana, Kamionskaya, Anastasia, Frolov, Andrej, Medvedev, Sergei, and Smolikova, Galina

Abstract

Photosynthesis is a vital process for seed productivity. It occurs in the leaves and provides developing seeds with the necessary nutrients. Moreover, many crops require photochemical reactions inside the seeds for proper development. The present study aimed to investigate Pisum sativum L. seeds at the middle stage of maturation, which is characterized by the active synthesis of nutrient reserves. Embryonic photosynthesis represents a crucial process to produce cells' NADP(H) and ATP, which are necessary to convert sucrose into reserve biopolymers. However, it remains unclear how the pea embryo, covered by a coat and pericarp, receives sufficient light to provide energy for photochemical reactions. Recent studies have demonstrated that the photosynthetically active radiation reaching the developing pea embryo has a high proportion of green light. In addition, green light can be utilized in foliar photosynthesis by plants cultivated in shaded conditions. Here, we addressed the role of green light in seed development. Pea plants were cultivated under red and blue (RB) LEDs or red, green, and blue (RGB) LEDs. A Chl a fluorescence transient based on OJIP kinetics was detected at the periphery of the cotyledons isolated from developing seeds. Our findings showed that the addition of green light resulted in an increase in photochemical activity. Furthermore, the mature seeds that developed in the RGB module had a significantly higher weight and more storage proteins. Using a metabolomics approach, we also detected significant differences in the levels of organic acids, carbohydrates, nucleotide monophosphates, and nitrogenous substances between the RB and RGB conditions. Under RGB light, the cotyledons contained more ornithine, tryptophan, arginine, and aspartic acid. These changes indicate an impact of green light on the ornithine–urea cycle and polyamine biosynthesis. These results allow for a deeper understanding of the photochemical processes in embryos of developing seeds grown under a low light intensity. The photosynthetic system in the embryo cell adapts to the shade conditions by using green light. [ABSTRACT FROM AUTHOR]

Published

2024

21. The Effect of Nitrogen and Potassium Interaction on the Leaf Physiological Characteristics, Yield, and Quality of Sweet Potato.

Author

Shu, Xing, Jin, Minghuan, Wang, Siyu, Xu, Ximing, Deng, Lijuan, Zhang, Zhi, Zhao, Xu, Yu, Jing, Zhu, Yueming, Lu, Guoquan, and Lv, Zunfu

Abstract

This study selected two sweet potato varieties as research subjects and conducted a field experiment using a two-factor design with two potassium (K) levels (K0 and K1) and five nitrogen (N) levels (N0–N4). The physiological changes in sweet potato leaves under different N and K treatments were measured, and nutrients such as the soluble sugar, protein, and starch content of sweet potato roots were analyzed. The results indicate that the activity of glutamine synthetase (GS) and the soluble protein content in sweet potato leaves increase first and then decrease with increasing N application, while K application can significantly increase the activity of GS and the soluble protein content. The N metabolic capacity of leaves is strongest when the fertilizer ratio is K1N2. The SPAD value of sweet potato leaves increases with increasing N application. The net photosynthetic rate, stomatal conductance, and intercellular CO2 concentration first increase and then decrease with increasing N application. K fertilizer has a significant effect on these parameters. As the N application rate increases, the starch and protein content in the tubers increase, while the soluble sugar content decreases. However, the number of tubers per plant, fresh weight of the tubers, and dry weight of the tubers increase initially and then decrease, while the vine length continuously increases. The application of K fertilizer can significantly increase the number of tubers per plant and stem thickness of sweet potato. In conclusion, the appropriate N–K combined application can promote N metabolism, enhance the photosynthetic capacity of sweet potato, increase yield, and improve quality. [ABSTRACT FROM AUTHOR]

Published

2024

22. Alleviative Effect of Exogenous Application of Fulvic Acid on Nitrate Stress in Spinach (Spinacia oleracea L.).

Author

Han, Kangning, Zhang, Jing, Wang, Cheng, Chang, Youlin, Zhang, Zeyu, and Xie, Jianming

Abstract

Salt stress could be a significant factor limiting the growth and development of vegetables. In this study, Fulvic Acid (FA) (0.05%, 0.1%, 0.15%, 0.2%, and 0.25%) was applied under nitrate stress (150 mM), with normal Hoagland nutrient solution as a control to investigate the influence of foliar spray FA on spinach growth, photosynthesis, and oxidative stress under nitrate stress. The results showed that nitrate stress significantly inhibited spinach growth, while ROS (reactive oxygen species) accumulation caused photosystem damage, which reduced photosynthetic capacity. Different concentrations of FA alleviated the damage caused by nitrate stress in spinach to varying degrees in a concentration-dependent manner. The F3 treatment (0.15% FA + 150 mM NO3−) exhibited the most significant mitigating effect. FA application promoted the accumulation of biomass in spinach under nitrate stress and increased chlorophyll content, the net photosynthetic rate, the maximum photochemical quantum yield of PSII (Photosystem II) (Fv/Fm), the quantum efficiency of PSII photochemistry [Y(II)], the electron transport rate, and the overall functional activity index of the electron transport chain between the PSII and PSI systems (PItotal); moreover, FA decreased PSII excitation pressure (1 − qP), quantum yields of regulated energy dissipation of PSII [Y(NPQ)], and the relative variable initial slope of fluorescence. FA application increased superoxide dismutase, peroxidase, and catalase activities and decreased malondialdehyde, H2O2, and O2− levels in spinach under nitrate stress. FA can enhance plant resistance to nitrate by accelerating the utilization of light energy in spinach to mitigate excess light energy and ROS-induced photosystem damage and increase photosynthetic efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

23. Physiological and Transcriptomic Characterization of Rice Genotypes under Drought Stress.

Author

Zhu, Qian, Hassan, Muhammad Ahmad, Li, Yiru, Fang, Wuyun, Wu, Jingde, and Wang, Shimei

Abstract

Drought is a primary abiotic stress that inhibits rice (Oryza sativa L.) growth and development, and during the reproductive stage it has a negative impact on the rice seed-setting rate. This research study examined two rice lines, La-96 (drought sensitive) and La-163 (drought resistant), for drought stress treatment (with soil moisture at 20% for 7 days) and control (normal irrigation and kept soil moisture ≥40%). To elucidate the photosynthesis and molecular mechanisms underlying drought tolerance in rice, leaf photosynthetic traits and transcriptome sequencing were used to compare differences between two contrasting recombinant inbred lines (RIL) during drought and subsequent recovery at the booting stage. The rice line La-96 showed a significant decrease in seed-setting rate after being treated for seven days' drought stress (from 86.64% to 22.75%), while La-163 was slightly affected (from 89.04% to 79.33%). The photosynthetic activities of both lines significantly decreased under the drought treatment, and these traits of La-163 recovered to a comparable level with the control after three days of rewatering. The transcriptome of both lines in three treatments (the control, drought stress, and subsequent recovery) were tested, and a total of 16,051 genes were identified, among which 10,566 genes were differentially expressed in various treatments and rice lines. Comprehensive gene expression profiles revealed that the specifically identified DEGs were involved in the ribosome synthesis and the metabolic pathway of photosynthesis, starch, and sucrose metabolism. The DEGs that are activated and respond quickly, as seen during recovery in the tolerant rice line, may play essential roles in regulating subsequent growth and development. This study uncovered the molecular genetic pathways of drought tolerance and extended our understanding of the drought tolerance mechanisms and subsequent recovery regulation in rice. [ABSTRACT FROM AUTHOR]

Published

2024

24. The Effect of Short-Term Waterlogging Stress on the Response Mechanism of Photosynthetic Characteristics, Chlorophyll Fluorescence, and Yield Components during the Podding Stage in Peanuts.

Author

Wu, Yujie, Ma, Qingrong, Zhen, Zhigao, Chu, Ronghao, and Hu, Chengda

Abstract

In the context of global climate change, the frequency of waterlogging is increasing. Therefore, to elucidate the effects of waterlogging under real precipitation conditions on the physiological characteristics of peanuts and the underlying mechanics and to provide a theoretical basis for timely protective measures, this study involved a waterlogging disaster simulation experiment in the field environment and a waterlogging stress control experiment in the potting environment. It was found that sufficient water had a positive effect on the growth and development of peanuts (Arachis hypogaea L.) during the 3–5 days period at the beginning of waterlogging. However, as the duration of waterlogging increased, excess water inhibited the growth of peanuts, with a stronger inhibitory effect on the development of pods. A comparison of the two different experimental models found that in the potting environment, water circulation was not smooth, and the intensity of waterlogging was higher than in the field environment experiment, resulting in the effect of waterlogging being advanced by one observation stage (2 days) in the potting environment. Furthermore, using a novel fluorescence imaging system, an analysis of variations in the physiological characteristics of leaf sections demonstrated that the chlorophyll fluorescence in the leaves of the peanut plant exhibited a specific pattern in response to waterlogging stress. [ABSTRACT FROM AUTHOR]

Published

2024

25. Alternative electron pathways of photosynthesis power green algal CO2 capture.

Author

Peltier, Gilles, Stoffel, Carolyne, Findinier, Justin, Madireddi, Sai Kiran, Dao, Ousmane, Epting, Virginie, Morin, Amélie, Grossman, Arthur, Li-Beisson, Yonghua, and Burlacot, Adrien

Subjects

*CHLAMYDOMONAS reinhardtii, *BIOTECHNOLOGY, *CHEMICAL energy, *PHOTOSYNTHESIS, *BIOMASS

Abstract

Microalgae contribute to about half of global net photosynthesis, which converts sunlight into the chemical energy (ATP and NADPH) used to transform CO2 into biomass. Alternative electron pathways of photosynthesis have been proposed to generate additional ATP that is required to sustain CO2 fixation. However, the relative importance of each alternative pathway remains elusive. Here, we dissect and quantify the contribution of cyclic, pseudo-cyclic, and chloroplast-to-mitochondrion electron flows for their ability to sustain net photosynthesis in the microalga Chlamydomonas reinhardtii. We show that (i) each alternative pathway can provide sufficient additional energy to sustain high CO2 fixation rates, (ii) the alternative pathways exhibit cross-compensation, and (iii) the activity of at least one of the three alternative pathways is necessary to sustain photosynthesis. We further show that all pathways have very different efficiencies at energizing CO2 fixation, with the chloroplast–mitochondrion interaction being the most efficient. Overall, our data lay bioenergetic foundations for biotechnological strategies to improve CO2 capture and fixation. Quantifying the contribution of the main electron flow pathways to algal CO2 fixation. [ABSTRACT FROM AUTHOR]

Published

2024

26. Lighting the way: Compelling open questions in photosynthesis research.

Author

Eckardt, Nancy A, Allahverdiyeva, Yagut, Alvarez, Clarisa E, Büchel, Claudia, Burlacot, Adrien, Cardona, Tanai, Chaloner, Emma, Engel, Benjamin D, Grossman, Arthur R, Harris, Dvir, Herrmann, Nicolas, Hodges, Michael, Kern, Jan, Kim, Tom Dongmin, Maurino, Veronica G, Mullineaux, Conrad W, Mustila, Henna, Nikkanen, Lauri, Schlau-Cohen, Gabriela, and Tronconi, Marcos A

Subjects

*ENERGY conversion, *OPEN-ended questions, *RESEARCH personnel, *PHOTOSYNTHESIS, *SUNSHINE

Abstract

Expert commentary on major open questions in photosynthesis research. Photosynthesis—the conversion of energy from sunlight into chemical energy—is essential for life on Earth. Yet there is much we do not understand about photosynthetic energy conversion on a fundamental level: how it evolved and the extent of its diversity, its dynamics, and all the components and connections involved in its regulation. In this commentary, researchers working on fundamental aspects of photosynthesis including the light-dependent reactions, photorespiration, and C4 photosynthetic metabolism pose and discuss what they view as the most compelling open questions in their areas of research. [ABSTRACT FROM AUTHOR]

Published

2024

27. Plastid retrograde signaling: A developmental perspective.

Author

Loudya, Naresh, Barkan, Alice, and López-Juez, Enrique

Subjects

*GENE expression, *GENES, *SIGNALS & signaling, *TRANSCRIPTOMES, *PHOTOSYNTHESIS

Abstract

Chloroplast activities influence nuclear gene expression, a phenomenon referred to as retrograde signaling. Biogenic retrograde signals have been revealed by changes in nuclear gene expression when chloroplast development is disrupted. Research on biogenic signaling has focused on repression of Photosynthesis-Associated Nuclear Genes (PhANGs), but this is just one component of a syndrome involving altered expression of thousands of genes involved in diverse processes, many of which are upregulated. We discuss evidence for a framework that accounts for most of this syndrome. Disruption of chloroplast biogenesis prevents the production of signals required to progress through discrete steps in the program of photosynthetic differentiation, causing retention of juvenile states. As a result, expression of PhANGs and other genes that act late during photosynthetic differentiation is not initiated, while expression of genes that act early is retained. The extent of juvenility, and thus the transcriptome, reflects the disrupted process: lack of plastid translation blocks development very early, whereas disruption of photosynthesis without compromising plastid translation blocks development at a later stage. We discuss implications of these and other recent observations for the nature of the plastid-derived signals that regulate photosynthetic differentiation and the role of GUN1, an enigmatic protein involved in biogenic signaling. [ABSTRACT FROM AUTHOR]

Published

2024

28. Response mechanism of ecosystem gross primary productivity to cloud and aerosol changes in a Chinese winter-wheat cropland.

Author

Bao, Xueyan, Sun, Xiaomin, and Bao, Guirong

Subjects

*VAPOR pressure, *PATH analysis (Statistics), *AEROSOLS, *ATMOSPHERIC temperature, *RADIANCE

Abstract

Changes in clouds and aerosols may alter the quantity of solar radiance and its diffuse components, as well as air temperature (Ta) and vapor pressure deficit (VPD), thereby affecting canopy photosynthesis. Our aim was to determine how ecosystem gross primary productivity (GPP) responds to the cloudiness and aerosol depth changes, as indicated by diffuse light fraction (fDIF). The environmental factors that caused these responses were examined using 2 years of eddy covariance data from a winter-wheat cropland in northern China. The GPP decreased significantly along with the fDIF in a nonlinear pattern, with a determination coefficient of 0.91. Changes in fDIF altered total photosynthetic active radiation (PAR), diffuse PAR, Ta and VPD. The variations in GPP with fDIF in both fDIF change Phase I (fDIF < 0.65) and Phase II (fDIF > 0.65) resulted from the combined effects of multiple environmental factors. Because the driving factors were closely correlated, a path analysis was used to distinguish their respective contribution to the GPP response to fDIF by integrating path coefficients. In Phases I and II, the decreased responses of GPP to fDIF were mainly caused by total PAR and diffuse PAR, respectively, which contributed approximately 49% and 37% to GPP variations, respectively. Our research has certain implications for the necessity to consider fDIF and to incorporate diffuse light into photosynthetic models. [ABSTRACT FROM AUTHOR]

Published

2024

29. Ecological investigations of giant Phaeocystis colonies in Viet Nam: II. Photosynthesis—irradiance characteristics and nitrogen uptake.

Author

Meng, Rui, Smith, Walker O., Cao, Ruobing, Doan‐Nhu, Hai, and Nguyen‐Ngoc, Lam

Subjects

*ALGAL communities, *MARINE phytoplankton, *PHOTOSYNTHETIC rates, *AMMONIUM nitrate, *ACCLIMATIZATION

Abstract

Phaeocystis globosa is a marine phytoplankton species that forms deleterious blooms in temperate and tropical waters. In some locations, "giant" colonies form, although the controls on its size are unknown. During a "giant" colony bloom, measurements were completed to characterize photosynthesis–irradiance relationships, nitrogen uptake kinetics, and nitrogen–irradiance relationships of P. globosa colonies to understand its growth characteristics and their relationship to colony size. The photosynthetic capacity (Fv/Fm) varied from 0.65 to 0.68 among colony sizes ranging from 3.0 to 11.0 mm, indicating that all colonial cells were physiologically robust. The maximum chl a‐specific photosynthetic rates (PmaxB) ranged from 0.89 to 1.92 μg C · μg−1 chl · h−1, were maximal in the mid‐sized colonies (5.5–6.5 mm) and decreased with size. The relatively low PmaxB values may be related to the high cellular chl a of colonial cells and their acclimation to in situ irradiance. Nitrate Vmax and KS values were greater than those of ammonium, although N affinity was greater for ammonium. No differences in light‐limited rates in either nitrate or ammonium uptake among colony sizes were observed, and no dark uptake occurred. Both ammonium and nitrate uptake showed a saturation response as a function of irradiance. While the driving forces for the formation of giant colonies remain unknown, their impacts on coastal systems are substantial and a further assessment of their growth is warranted. [ABSTRACT FROM AUTHOR]

Published

2024

30. Photophysiology of the haploid form of the cryptophyte Teleaulax amphioxeia.

Author

Garric, Sarah, Ratin, Morgane, Gallet, Benoit, Decelle, Johan, Probert, Ian, Rodriguez, Francisco, and Six, Christophe

Subjects

*FLUORESCENCE quenching, *MEMBRANE proteins, *CRYPTOMONADS, *DINOFLAGELLATES, *ACCLIMATIZATION

Abstract

Cryptophytes are abundant and ubiquitous microalgae that constitute a major plastid source for kleptoplastidic ciliates and dinoflagellates. Despite their ecological significance, the understanding of their light preferences and photophysiology remains limited. Here, we provide a comprehensive study of the response of the haploid strain Teleaulax amphioxeia (Cr10EHU) to varying light irradiance. This strain is capable of growing under a wide range of irradiance levels, notably by finely tuning the different pigments bound to the membrane light‐harvesting proteins. Analysis of the luminal phycoerythrin content revealed remarkable flexibility, with phycoerythrin emerging as a pivotal protein facilitating acclimation to varying light levels. Detailed ultrastructure examinations unveiled that this adaptability was supported by the synthesis of large thylakoidal vesicles, likely enhancing the capture of green photons efficiently under low light, a phenomenon previously undocumented. Teleaulax amphioxeia Cr10EHU effectively regulated light utilization by using a cryptophyte state transition‐like process, with a larger amplitude observed under high growth irradiance. Furthermore, our results revealed the establishment of growth irradiance‐dependent non‐photochemical quenching of fluorescence, likely inducing the dissipation of excess light. This study underscores the particularities and the significant photoadaptability of the plastid of the haploid form of T. amphioxeia. It constitutes a comprehensive photophysiological characterization of the Cr10EHU strain that paves the way for future studies of the kleptoplastidy process. [ABSTRACT FROM AUTHOR]

Published

2024

31. Short‐term hyposalinity stress increases dissolved organic carbon (DOC) release by the macroalga Sargassum fallax (Ochrophyta).

Author

Bennett, Eloise, Paine, Ellie R., Hovenden, Mark, Smith, Gregory, Fitzgibbon, Quinn, and Hurd, Catriona L.

Subjects

*DISSOLVED organic matter, *EXUDATION (Botany), *SALINITY, *SARGASSUM, *FUCALES

Abstract

Dissolved organic carbon (DOC) released by macroalgae supports coastal ocean carbon cycling and contributes to the total oceanic DOC pool. Salinity fluctuates substantially in coastal marine environments due to natural and anthropogenic factors, yet there is limited research on how salinity affects DOC release by ecologically important macroalgae. Here we determined the effect of short‐term salinity changes on rates of DOC release by the habitat‐forming fucalean seaweed Sargassum fallax (Ochrophyta). Lateral branches (~4 g) cut at the axes of mature individuals were incubated across a salinity gradient (4–46) for 24 h under a 12:12 light:dark cycle, and seawater was sampled for DOC at 0, 12, and 24 h. Physiological assays (tissue water content, net photosynthesis, respiration, tissue carbon, and nitrogen content) were undertaken at the end of the 24‐h experiment. Dissolved organic carbon release increased with decreasing salinity while net photosynthesis decreased. Dissolved organic carbon release rates at the lowest salinity tested (4) were ~3.3 times greater in the light than in the dark, indicating two potential DOC release mechanisms: light‐mediated active exudation and passive release linked to osmotic stress. Tissue water content decreased with increasing salinity. These results demonstrate that hyposalinity stress alters the osmotic status of S. fallax, reducing photosynthesis and increasing DOC release. This has important implications for understanding how salinity conditions encountered by macroalgae may affect their contribution to the coastal ocean carbon cycle. [ABSTRACT FROM AUTHOR]

Published

2024

32. Novel high‐throughput oxygen saturation measurements for quantifying the physiological performance of macroalgal early life stages.

Author

Veenhof, R. J., Coleman, M. A., Champion, C., Dworjanyn, S. A., Venhuizen, R., Kearns, L., Marzinelli, E. M., and Pettersen, A. K.

Subjects

*OXYGEN saturation, *PHOTOSYNTHETIC rates, *MARINE algae, *GAMETOPHYTES, *ZYGOTES, *OXYGEN consumption, *RESPIRATION

Abstract

Understanding how macroalgal forests will respond to environmental change is critical for predicting future impacts on coastal ecosystems. Although measures of adult macroalgae physiological responses to environmental stress are advancing, measures of early life‐stage physiology are rare, in part due to the methodological difficulties associated with their small size. Here we tested a novel, high‐throughput method (rate of oxygen consumption and production; V̇O2$$ \dot{V}{\mathrm{O}}_2 $$) via a sensor dish reader microplate system to rapidly measure physiological rates of the early life stages of three habitat‐forming macroalgae, the kelp Ecklonia radiata and the fucoids Hormosira banksii and Phyllospora comosa. We measured the rate of O2 consumption (respiration) and O2 production (net primary production) to then calculate gross primary production (GPP) under temperatures representing their natural thermal range. The V̇O2$$ \dot{V}{\mathrm{O}}_2 $$ microplate system was suitable for rapidly measuring physiological rates over a temperature gradient to establish thermal performance curves for all species. The V̇O2$$ \dot{V}{\mathrm{O}}_2 $$ microplate system proved efficient for measures of early life stages of macroalgae ranging in size from approximately 50 μm up to 150 mm. This method has the potential for measuring responses of early life stages across a range of environmental factors, species, populations, and developmental stages, vastly increasing the speed, precision, and efficacy of macroalgal physiological measures under future ocean change scenarios. [ABSTRACT FROM AUTHOR]

Published

2024

33. Estimating the gross primary productivity based on VPM correction model for Xishuangbanna tropical seasonal rainforest.

Author

Feng, Siqi, Tang, Bo-Hui, Chen, Guokun, and Huang, Liang

Subjects

*REMOTE sensing, *SURFACE temperature, *PHOTOSYNTHESIS, *EDDIES

Abstract

Due to the unique climatic characteristics and vegetation features of tropical regions, the correlation R2 of gross primary productivity (GPP) estimation in tropical regions using remote sensing models was generally lower than 0.3. Therefore, for the cloudy and rainy tropical regions, the influence brought by clouds on remote sensing images needed to be considered in GPP estimation. This paper developed a corrected vegetation photosynthesis model (VPM) for estimating GPP under cloudy conditions. It mainly corrected the two parameters, Wscalar and Enhanced Vegetation Index (EVI), which were obtained from remote sensing images and were therefore greatly influenced by clouds in the model. First, the water stress factor Wscalar was replaced by Evaporation Fraction (EF). Secondly, using the good correlation between near surface temperature and EVI, the conversion coefficient between near surface temperature and EVI was fitted to achieve the effective reconstruction of EVI contaminated by clouds. The correction of the two factors improved the estimation accuracy of the VPM model, and the comparison with the observed values of the GPP site in 4 years showed that the correction of EVI had a better improvement, with an increase of 0.22 in R2 compared with the pre-correction, and the correction of Wscalar was increased by 0.11 in R2. To verify the proposed method, the in-situ observation data of Xishuangbanna flux site from 2007 to 2010 were used. The results showed that the proposed method effectively improved the accuracy of GPP estimation by VPM model, especially in 2007 it was strongly influenced by clouds, and the improvement was significant, with R2 increasing from 0.2 to 0.82. In general, the accuracy of GPP estimation by the proposed method had been significantly improved, with RMSE (gC·m−2·8 day−1) decreasing from 15,14.4, 18.1, 14.2 to 8.07, 6.56, 10.33, 11.44, respectively. Therefore, the proposed method can be used to estimate the GPP for tropical seasonal rain forests in Xishuangbanna. [ABSTRACT FROM AUTHOR]

Published

2024

34. Time of day of infection shapes development of a eukaryotic algal-Nucleocytoviricota virocell.

Author

Chase, Emily E, Truchon, Alexander R, Creasey, Brooke A, and Wilhelm, Steven W

Subjects

*ALGAL blooms, *PHOTOSYSTEMS, *CELL physiology, *FLOW cytometry, *PHOTOSYNTHESIS

Abstract

Aureococcus anophagefferens forms a model host-virus system with the "giant virus" Kratosvirus quantuckense. Studies to define its ribocell (uninfected) and virocell (virus-infected) forms are needed as these states co-occur during algal blooms. Previously, a link between light-derived energy, virus particle production, and virocell formation was noted. We explored how the time of day (morning, midday, or late day) of virus-host contact shaped virocell ontogeny. In parallel, we explored the dependence on light-derived energy in this mixotrophic plankter by inhibiting photosystem II, testing the role of heterotrophic energy in infection dynamics. Using flow cytometry and photochemical assessments, we examined the physiology of infected cells and controls, and estimated virus particle production. We observed differences between ribocell and virocell response to treatments, including reductions in virus particle production during reduced light duration) and PSII inhibition (i.e. "forced heterotrophy"). This work demonstrates the importance of light in shaping the fate of infected cells and provides insight into factors that constrain in situ blooms. Most significantly, we show that time of the solar day when a virus and host come into contact influences viral particle production, and therefore bloom dynamics; a factor that needs to be considered in bloom modeling work. [ABSTRACT FROM AUTHOR]

Published

2024

35. Cross-species transcriptomics reveals differential regulation of essential photosynthesis genes in Hirschfeldia incana.

Author

Garassino, Francesco, Luoni, Sofia Bengoa, Cumerlato, Tommaso, Marquez, Francisca Reyes, Harbinson, Jeremy, Aarts, Mark G M, Nijveen, Harm, and Smit, Sandra

Subjects

*PLANT genetics, *GENE expression, *MUSTARD, *PHENOTYPES, *PLANT breeding

Abstract

Photosynthesis is the only yield-related trait not yet substantially improved by plant breeding. Previously, we have established H. incana as the model plant for high photosynthetic light-use efficiency (LUE). Now we aim to unravel the genetic basis of this trait in H. incana , potentially contributing to the improvement of photosynthetic LUE in other species. Here, we compare its transcriptomic response to high light with that of Arabidopsis thaliana , Brassica rapa , and Brassica nigra , 3 fellow Brassicaceae members with lower photosynthetic LUE. We built a high-light, high-uniformity growing environment, in which the plants developed normally without signs of stress. We compared gene expression in contrasting light conditions across species, utilizing a panproteome to identify orthologous proteins. In-depth analysis of 3 key photosynthetic pathways showed a general trend of lower gene expression under high-light conditions for all 4 species. However, several photosynthesis-related genes in H. incana break this trend. We observed cases of constitutive higher expression (like antenna protein LHCB8), treatment-dependent differential expression (as for PSBE), and cumulative higher expression through simultaneous expression of multiple gene copies (like LHCA6). Thus, H. incana shows differential regulation of essential photosynthesis genes, with the light-harvesting complex as the first point of deviation. The effect of these expression differences on protein abundance and turnover, and ultimately the high photosynthetic LUE phenotype is relevant for further investigation. Furthermore, this transcriptomic resource of plants fully grown under, rather than briefly exposed to, a very high irradiance, will support the development of highly efficient photosynthesis in crops. [ABSTRACT FROM AUTHOR]

Published

2024

36. Knockdown of Adenosine 5′-Triphosphate-Dependent Caseinolytic Protease Proteolytic Subunit 6 Enhances Aluminum Tolerance in Peanut Plants (Arachis hypogea L.).

Author

Shi, Yusun, Zhang, Dayue, Liang, Ronghua, Xiao, Dong, Wang, Aiqin, He, Longfei, and Zhan, Jie

Subjects

*ACID soils, *ROOT growth, *ABIOTIC stress, *CHLOROPLASTS, *PHOTOSYNTHESIS

Abstract

Aluminum (Al3+) toxicity in acidic soils reduces root growth and can lead to a considerable reduction in peanut plants (Arachis hypogea L.). The caseinolytic protease (Clp) system plays the key role in abiotic stress response. However, it is still unknown whether it is involved in peanut response to Al3+ stress. The results from this study showed that Adenosine 5′-triphosphate (ATP)-dependent caseinolytic protease proteolytic subunit 6 (AhClpP6) in peanut plants was involved in the Al3 stress response through its effects on leaf photosynthesis. The AhClpP6 expression levels in the leaf and stem significantly increased with the Al3+ treatment times. Knockdown AhClpP6 peanut lines accumulated significantly more Al3+ when exposed to Al3+ stress, which reduced leaf photosynthesis. Furthermore, in response to Al3+ treatment, knockdown of AhClpP6 resulted in a flattened shape of chloroplasts, disordered and flattened thylakoid, and accumulating more starch grains than those of the wild-type (WT) peanut lines. Taken together, our results suggest that AhClpP6 regulates Al3+ tolerance by maintaining chloroplast integrity and enhancing photosynthesis. [ABSTRACT FROM AUTHOR]

Published

2024

37. Effects of Nitrogen Deficiency on the Photosynthesis, Chlorophyll a Fluorescence, Antioxidant System, and Sulfur Compounds in Oryza sativa.

Author

Chen, Ling-Hua, Xu, Ming, Cheng, Zuxin, and Yang, Lin-Tong

Subjects

*SULFUR compounds, *GLUTATHIONE reductase, *SULFUR metabolism, *NITROGEN deficiency, *RICE, *GLUTATHIONE transferase

Abstract

Decreasing nitrogen (N) supply affected the normal growth of Oryza sativa (O. sativa) seedlings, reducing CO2 assimilation, stomatal conductance (gs), the contents of chlorophylls (Chl) and the ratio of Chl a/Chl b, but increasing the intercellular CO2 concentration. Polyphasic chlorophyll a fluorescence transient and relative fluorescence parameters (JIP test) results indicated that N deficiency increased Fo, but decreased the maximum quantum yield of primary photochemistry (Fv/Fm) and the maximum of the IPphase, implying that N-limiting condition impaired the whole photo electron transport chain from the donor side of photosystem II (PSII) to the end acceptor side of PSI in O. sativa. N deficiency enhanced the activities of the antioxidant enzymes, such as ascorbate peroxidase (APX), guaiacol peroxidase (GuPX), dehydro–ascorbate reductase (DHAR), superoxide dismutase (SOD), glutathione peroxidase (GlPX), glutathione reductase (GR), glutathione S-transferase (GST) and O-acetylserine (thiol) lyase (OASTL), and the contents of antioxidant compounds including reduced glutathione (GSH), total glutathione (GSH+GSSG) and non-protein thiol compounds in O. sativa leaves. In contrast, the enhanced activities of catalase (CAT), DHAR, GR, GST and OASTL, the enhanced ASC–GSH cycle and content of sulfur-containing compounds might provide protective roles against oxidative stress in O. sativa roots under N-limiting conditions. Quantitative real-time PCR (qRT-PCR) analysis indicated that 70% of the enzymes have a consistence between the gene expression pattern and the dynamic of enzyme activity in O. sativa leaves under different N supplies, whereas only 60% of the enzymes have a consistence in O. sativa roots. Our results suggested that the antioxidant system and sulfur metabolism take part in the response of N limiting condition in O. sativa, and this response was different between leaves and roots. Future work should focus on the responsive mechanisms underlying the metabolism of sulfur-containing compounds in O. sativa under nutrient deficient especially N-limiting conditions. [ABSTRACT FROM AUTHOR]

Published

2024

38. Estimating Global Gross Primary Production Using an Improved MODIS Leaf Area Index Dataset.

Author

Wang, Shujian, Zhang, Xunhe, Hou, Lili, Sun, Jiejie, and Xu, Ming

Subjects

*ATMOSPHERIC carbon dioxide, *LEAF area index, *ECOLOGICAL models, *CARBON cycle, *REMOTE sensing

Abstract

Remote sensing and process-coupled ecological models are widely used for the simulation of GPP, which plays a key role in estimating and monitoring terrestrial ecosystem productivity. However, most such models do not differentiate the C3 and C4 photosynthetic pathways and neglect the effect of nitrogen content on V max and J max , leading to considerable bias in the estimation of gross primary productivity (GPP). Here, we developed a model driven by the leaf area index, climate, and atmospheric CO 2 concentration to estimate global GPP with a spatial resolution of 0.1° and a temporal interval of 1 day from 2000 to 2022. We validated our model with ground-based GPP measurements at 128 flux tower sites, which yielded an accuracy of 72.3%. We found that the global GPP ranged from 116.4 PgC year − 1 to 133.94 PgC year − 1 from 2000 to 2022, with an average of 125.93 PgC year − 1 . We also found that the global GPP showed an increasing trend of 0.548 PgC year − 1 during the study period. Further analyses using the structure equation model showed that atmospheric CO 2 concentration and air temperature were the main drivers of the global GPP changes, total associations of 0.853 and 0.75, respectively, while precipitation represented a minor but negative contribution to global GPP. [ABSTRACT FROM AUTHOR]

Published

2024

39. Functional variations in efficiency of PSII during leaf ontogeny in the tropical plant Saraca asoca.

Author

Shasmita, Swain, Barsha Bhushan, Mishra, Smrutirekha, Mohapatra, Debasish, Naik, Soumendra Kumar, and Mohapatra, Pradipta Kumar

Subjects

*OXYGEN-evolving complex (Photosynthesis), *LEAF development, *PHOTOSYNTHETIC rates, *PHOTOSYSTEMS, *CHLOROPHYLL spectra

Abstract

Leaf ontogeny of tropical evergreen tree species lasts several months with changes in size, shape, colouration and internal tissue distribution of leaves. Leaf initiation in Saraca asoca generally occurs once in a year during February–April, followed by very limited leafing thereafter. We measured the rate of photosynthesis, chlorophyll a fluorescence, energy quenching and PSII functions during the leaf ontogeny process. Observations were taken up to 35 days after opening of lamina (DAOL). Significant increase in the synthesis and accumulation of photosynthetic pigments but negative net photosynthesis was noticed during initial days of the ontogeny. The leaf moved from heterotrophy to autotrophy with gradual improvement of PSII functions. The ratio of intercellular CO2 (C i) and ambient CO2 (C a) showed significant change at ≥11 DAOL. Increase in the age of the leaf (between 5 and 28 DAOL) caused decrease in O-J rise and corresponding increase in J-I and I-P rise as well as of fluorescence maximum (F M) of the OJIP curve. The improvement of the electron transport components of the donor side of PSII was seen with increase in the functional oxygen evolving complex. The functional improvements of the donor and acceptor side of PSII during leaf ontogeny are discussed. The leaf ontogeny in Saraca asoca usually occurs once in a year and involves variation in PSII function. The developing leaves metabolically switch from heterotrophy to autotrophy. During leaf development, the carotenoids are accumulated earlier than chlorophylls. With the development of leaf, the PSII function improves leading to increased efficiency of oxygen evolving complex and photoelectron transport. [ABSTRACT FROM AUTHOR]

Published

2024

40. Warming triggers stomatal opening by enhancement of photosynthesis and ensuing guard cell CO2 sensing, whereas higher temperatures induce a photosynthesis‐uncoupled response.

Author

Pankasem, Nattiwong, Hsu, Po‐Kai, Lopez, Bryn N. K., Franks, Peter J., and Schroeder, Julian I.

Abstract

Summary Plants integrate environmental stimuli to optimize photosynthesis vs water loss by controlling stomatal apertures. However, stomatal responses to temperature elevation and the underlying molecular genetic mechanisms remain less studied. We developed an approach for clamping leaf‐to‐air vapor pressure difference (VPDleaf) to fixed values, and recorded robust reversible warming‐induced stomatal opening in intact plants. We analyzed stomatal temperature responses of mutants impaired in guard cell signaling pathways for blue light, abscisic acid (ABA), CO2, and the temperature‐sensitive proteins, Phytochrome B (phyB) and EARLY‐FLOWERING‐3 (ELF3). We confirmed that phot1‐5/phot2‐1 leaves lacking blue‐light photoreceptors showed partially reduced warming‐induced stomatal opening. Furthermore, ABA‐biosynthesis, phyB, and ELF3 were not essential for the stomatal warming response. Strikingly, Arabidopsis (dicot) and Brachypodium distachyon (monocot) mutants lacking guard cell CO2 sensors and signaling mechanisms, including ht1, mpk12/mpk4‐gc, and cbc1/cbc2 abolished the stomatal warming response, suggesting a conserved mechanism across diverse plant lineages. Moreover, warming rapidly stimulated photosynthesis, resulting in a reduction in intercellular (CO2). Interestingly, further enhancing heat stress caused stomatal opening uncoupled from photosynthesis. We provide genetic and physiological evidence that the stomatal warming response is triggered by increased CO2 assimilation and stomatal CO2 sensing. Additionally, increasing heat stress functions via a distinct photosynthesis‐uncoupled stomatal opening pathway. [ABSTRACT FROM AUTHOR]

Published

2024

41. Evolution of Thylakoid Structural Diversity.

Author

Perez-Boerema, Annemarie, Engel, Benjamin D., and Wietrzynski, Wojciech

Abstract

Oxygenic photosynthesis evolved billions of years ago, becoming Earth's main source of biologically available carbon and atmospheric oxygen. Since then, phototrophic organisms have diversified from prokaryotic cyanobacteria into several distinct clades of eukaryotic algae and plants through endosymbiosis events. This diversity can be seen in the thylakoid membranes, complex networks of lipids, proteins, and pigments that perform the light-dependent reactions of photosynthesis. In this review, we highlight the structural diversity of thylakoids, following the evolutionary history of phototrophic species. We begin with a molecular inventory of different thylakoid components and then illustrate how these building blocks are integrated to form membrane networks with diverse architectures. We conclude with an outlook on understanding how thylakoids remodel their architecture and molecular organization during dynamic processes such as biogenesis, repair, and environmental adaptation. [ABSTRACT FROM AUTHOR]

Published

2024

42. Interactive effects of ocean acidification and nitrate on Ulva lactuca.

Author

Ji, Yan, Jiang, Yingying, Jin, Peng, and Xia, Jianrong

Abstract

The global ocean is undergoing gradual acidification and eutrophication which may have significant impacts on macroalgal communities. However, little is known regarding the interactive effects of ocean acidification (OA) and nitrate on Ulva lactuca, a primary producer widely distributed in coastal waters. This study focuses on the possible interactive effects of OA and elevated nitrate levels on physiological parameters of U. lactuca. Higher nitrate levels may increase growth, photosynthesis, respiration, pigment synthesis, Fv/Fm and Effective Quantum Yield, whereas CO2 enrichment may result in a reduction in photosynthesis, pigment content, Fv/Fm and Effective Quantum Yield. Higher nitrate levels increase NO3- uptake rate and nitrate reductase activity, which are further amplified by elevated CO2 levels. However, the stimulation of high nitrate towards pigment synthesis and photosynthesis is negatively affected by elevated CO2 levels. Our results suggest that U. lactuca could potentially increase its biomass in coastal eutrophic waters, and OA in the future is not expected to promote the growth of U. lactuca, but it can enhance its potential biofiltration to remove nitrate from coastal ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

43. Growth, photosynthetic and nutrition characteristics of Pyropia haitanensis in response to the effects of increased CO2 and chloramphenicol.

Author

Liu, Chunxiang, Min, Susu, Ji, Lei, Zou, Dinghui, Liu, Zhiwei, Wang, Yaqi, and Zhou, Xiaomeng

Abstract

Pyropia haitanensis was cultured under two CO2 (410 (LC), 1000 (HC) μL L-1) concentrations and six chloramphenicol (CAP)-methanol solutions (0, 0+methanol, 10, 50, 100, 250 μg mL-1) to investigate the effects of elevated CO2 and CAP on its growth, photosynthesis and biochemical characteristics. HC had no obvious effects on the growth rate (RGR) with CAP in the range of 10 to 100 μg mL-1, but the decrease of RGR by HC was statistically significant with the CAP dosage at 250 μg mL-1. HC had no significant effect on net photosynthetic rates (Pn) in the present of CAP (10-250 μg mL-1). CAP greatly reduced net photosynthesis as well as the maximal photochemical yield (Fv/Fm) and photosynthetic efficiency (αETR). In contrast, the maximum relative electron transport rates (rETRm) were almost constant with the CAP dosage from 10 to 100 μg mL-1. HC significantly increased the energy fluxes (per RC) for absorption (ABS/RC), trapping (TRo/RC) and transport fluxes (ETo/RC) with the dosage of CAP at 250 μg mL-1. Principal component analysis (PCA) indicated that CAP was positively correlated with the synthesis of free amino acids (FAA), contents of umami-, sweet- and essential AA were significantly enhanced with the interaction of HC and higher CAP dosage at 100 μg mL-1, which led to the variation of flavor in algae. Furthermore, phycobiliproteins and soluble protein (SP) contents were remarkably reduced by CAP. Contents of chlorophyll a (Chl a), carotenoids (Car), soluble carbohydrates (SC) and C/N ratios were almost unchanged among treatments. The study indicates that future ocean acidification has no obvious effects on the biomass productivity of P. haitanensis, maintained steady photosynthetic activities with the CAP (within 100 μg mL-1) and induces better flavor. The data obtained have important theoretical relevance for in-depth understanding of algal responses to global changes and oceanic contamination. [ABSTRACT FROM AUTHOR]

Published

2024

44. Seasonal timing of fluorescence and photosynthetic yields at needle and canopy scales in evergreen needleleaf forests.

Author

Pierrat, Zoe Amie, Magney, Troy, Maguire, Andrew, Brissette, Logan, Doughty, Russell, Bowling, David R., Logan, Barry, Parazoo, Nicholas, Frankenberg, Christian, and Stutz, Jochen

Subjects

*FLUORESCENCE yield, *SNOW cover, *CHLOROPHYLL spectra, *CLOUDINESS, *REMOTE sensing

Abstract

The seasonal timing and magnitude of photosynthesis in evergreen needleleaf forests (ENFs) has major implications for the carbon cycle and is increasingly sensitive to changing climate. Earlier spring photosynthesis can increase carbon uptake over the growing season or cause early water reserve depletion that leads to premature cessation and increased carbon loss. Determining the start and the end of the growing season in ENFs is challenging due to a lack of field measurements and difficulty in interpreting satellite data, which are impacted by snow and cloud cover, and the pervasive "greenness" of these systems. We combine continuous needle‐scale chlorophyll fluorescence measurements with tower‐based remote sensing and gross primary productivity (GPP) estimates at three ENF sites across a latitudinal gradient (Colorado, Saskatchewan, Alaska) to link physiological changes with remote sensing signals during transition seasons. We derive a theoretical framework for observations of solar‐induced chlorophyll fluorescence (SIF) and solar intensity‐normalized SIF (SIFrelative) under snow‐covered conditions, and show decreased sensitivity compared with reflectance data (~20% reduction in measured SIF vs. ~60% reduction in near‐infrared vegetation index [NIRv] under 50% snow cover). Needle‐scale fluorescence and photochemistry strongly correlated (r2 = 0.74 in Colorado, 0.70 in Alaska) and showed good agreement on the timing and magnitude of seasonal transitions. We demonstrate that this can be scaled to the site level with tower‐based estimates of LUEP and SIFrelative which were well correlated across all sites (r2 = 0.70 in Colorado, 0.53 in Saskatchewan, 0.49 in Alaska). These independent, temporally continuous datasets confirm an increase in physiological activity prior to snowmelt across all three evergreen forests. This suggests that data‐driven and process‐based carbon cycle models which assume negligible physiological activity prior to snowmelt are inherently flawed, and underscores the utility of SIF data for tracking phenological events. Our research probes the spectral biology of evergreen forests and highlights spectral methods that can be applied in other ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

45. Evaluation of heavy metal accumulation and tolerance in oxalic acid-treated Phragmites australis wetlands for textile effluent remediation.

Author

Alghanem, Suliman Mohammed Suliman, Alsudays, Ibtisam Mohammed, Farid, Mujahid, Sarfraz, Wajiha, Ishaq, Hafiz Khuzama, Farid, Sheharyaar, Zubair, Muhammad, Khalid, Noreen, Aslam, Muhammad Arslan, Abbas, Mohsin, and Abeed, Amany H. A.

Subjects

*INDUSTRIAL wastes, *WATER purification, *PHRAGMITES australis, *OXALIC acid, *POLLUTANTS

Abstract

Water contamination with metals poses significant environmental challenges. The occurrence of heavy metals (HMs) prompts modifications in plant structures, emphasizing the necessity of employing focused safeguarding measures. Cadmium (Cd), lead (Pb), and chromium (Cr) emerge as particularly menacing toxins due to their high accumulation potential. Increasing the availability of organic acids is crucial for optimizing toxic metal removal via phytoremediation. This constructed wetland system (CWs) was used to determine how oxalic acid (OA) treatments of textile wastewater (WW) effluents affected morpho-physiological characteristics, antioxidant enzyme activity, oxidative stress, and HM concentrations in Phragmites australis. Multiple treatments, comprising the application of OA at a concentration of 10 mM and WW at different dilutions (25%, 50%, 75%, and 100%), were employed, with three replications of each treatment. WW stress decreased chlorophyll and carotenoid content, and concurrently enhanced HMs adsorption and antioxidant enzyme activities. Furthermore, the application of WW was found to elevate oxidative stress levels, whereas the presence of OA concurrently mitigated this oxidative stress. Similarly, WW negatively affected soil-plant analysis development (SPAD) and the total soluble proteins (SP) in both roots and shoots. Conversely, these parameters showed improvement with OA treatments. P. australis showed the potential to enhance HM accumulation under 100% WW stress. Specifically, there is an increase in root SP ranging from 9% to 39%, an increase in shoot SP from 6% to 91%, and an elevation in SPAD values from 4% to 64% compared to their respective treatments lacking OA inclusion. The OA addition resulted in decreased EL contents in the root and shoot by 10%–19% and 13%–15%, MDA by 9%–14% and 9%–20%, and H2O2 by 14%–21% and 9%–17%, in comparison to the respective treatments without OA. Interestingly, the findings further revealed that the augmentation of OA also contributed to an increased accumulation of Cr, Cd, and Pb. Specifically, at 100% WW with OA (10 mM), the concentrations of Cr, Pb, and Cd in leaves rose by 164%, 447%, and 350%, in stems by 213%, 247%, and 219%, and in roots by 155%, 238%, and 195%, respectively. The chelating agent oxalic acid effectively alleviated plant toxicity induced by toxins. Overall, our findings demonstrate the remarkable tolerance of P. australis to elevated concentrations of WW stress, positioning it as an eco-friendly candidate for industrial effluent remediation. This plant exhibits efficacy in restoring contaminants present in textile effluents, and notably, oxalic acid emerges as a promising agent for the phytoextraction of HMs. KEY MESSAGE/HIGHLIGHTS: HMs stress decreased the physiology and morphology of Phragmites australis L. OA improved the photosynthetic pigments and antioxidant enzymes HMs accumulation and bioavailability increased under OA Phragmites australis L. showed higher efficacy for textile effluent treatment under OA NOVELTY: The adoption of ecological or nature-based approaches for treating textile industry wastewater poses significant challenges. Despite laboratory and field demonstrations showcasing the potential of macrophytes for remediating metal-polluted wastewater, this study investigates the Phragmites australis to address heavy metal contamination in wastewater. This research bridges this gap by presenting the outcomes of applying oxalic acid single and in combination with wastewater to Phragmites australis, focusing on the accumulation of cadmium, chromium, and lead from textile wastewater. [ABSTRACT FROM AUTHOR]

Published

2024

46. Assessing thallium phycoremediation by applying Anabaena laxa and Nostoc muscorum and exploring its effect on cellular growth, antioxidant, and metabolic profile.

Author

Fathy, Wael A., Al-Qahtani, Wahidah H., Abdel-Maksoud, Mostafa A., Shaban, Amira M., Khanghahi, Mohammad Y., and Elsayed, Khaled N. M.

Subjects

*METABOLISM, *PHYSIOLOGY, *PHOTOSYNTHETIC rates, *CELL growth, *ANABAENA, *CYANOBACTERIAL toxins

Abstract

Thallium (Tl), a key element in high-tech industries, is recognized as a priority pollutant by the US EPA and EC. Tl accumulation threatens aquatic ecosystems. Despite its toxicity, little is known about its impact on cyanobacteria. This study explores the biochemical mechanisms of Tl(I) toxicity in cyanobacteria, focusing on physiology, metabolism, oxidative damage, and antioxidant responses. To this end, Anabaena and Nostoc were exposed to 400 µg/L, and 800 µg/L of Tl(I) over seven days. Anabaena showed superior Tl(I) accumulation with 7.8% removal at 400 µg/L and 9.5% at 800 µg/L, while Nostoc removed 2.2% and 7.4%, respectively. Tl(I) exposure significantly reduced the photosynthesis rate and function, more than in Nostoc. It also altered primary metabolism, increasing sugar levels and led to higher amino and fatty acids levels. While Tl(I) induced cellular damage in both species, Anabaena was less affected. Both species enhanced their antioxidant defense systems, with Anabaena showing a 175.6% increase in SOD levels under a high Tl(I) dose. This suggests that Anabaena's robust biosorption and antioxidant systems could be effective for Tl(I) removal. The study improves our understanding of Tl(I) toxicity, tolerance, and phycoremediation in cyanobacteria, aiding future bioremediation strategies. NOVELTY STATEMENT: This study presents novel insights into thallium (Tl) phycoremediation using Anabaena laxa and Nostoc muscorum, crucial for addressing the increasing contamination concerns stemming from high-tech industries. Elucidating the tolerance mechanisms and physiological responses of these cyanobacterial species to Tl(I) exposure. It highlights the potential of Anabaena laxa as an effective bio-remediator, offering a sustainable solution to mitigate Tl(I) environmental impact. [ABSTRACT FROM AUTHOR]

Published

2024

47. Unravelling the impact of cassava mosaic disease caused by Sri Lankan cassava mosaic virus infection: Insights from proteomics analysis of photosynthesis‐ and respiration‐related proteins.

Author

Vannatim, Nattachai, Chaowongdee, Somruthai, Malichan, Srihunsa, Roytrakul, Sittiruk, Charoenlappanit, Sawanya, and Siriwan, Wanwisa

Subjects

*CARRIER proteins, *MOSAIC diseases, *PHOTOSYSTEMS, *MOSAIC viruses, *GENE expression, *CASSAVA

Abstract

Sri Lankan cassava mosaic virus (SLCMV) poses a significant threat to global food security by affecting the production of cassava (Manihot esculenta) in South‐east Asia. It causes mosaic patterns on the leaves, disrupts photosynthesis and respiration, and alters carbohydrate accumulation in the tubers. This study aimed to identify proteins associated with cassava mosaic disease symptoms in three cassava cultivars: resistant (TMEB419), tolerant (Kasetsart 50, KU50) and susceptible (Rayong 11, R11) to SLCMV. These cultivars were inoculated with SLCMV using top‐cleft grafting and monitored at 21, 32 and 67 days post‐inoculation (dpi). The disease severity differed among the cultivars following SLCMV inoculation. Liquid chromatography–tandem mass spectrometry (LC–MS/MS)‐based proteomics analysis identified 541 differentially expressed proteins (DEPs), including photosynthesis‐ and respiration‐associated proteins such as RuBisCO large subunit‐binding protein α (LSBP), chlorophyll a‐b binding protein, photosystem I reaction centre subunit III (PSI‐F), glyceraldehyde‐3‐phosphate dehydrogenase (GAPDH) and fructose‐bisphosphate aldolase (FBA). A protein–protein interaction network revealed interactions among PSI, PSII, cytochrome complex proteins and electron transporter proteins. Chlorophyll(ide) b reductase NYC1, upregulated in R11 (susceptible) at 21 and 32 dpi, interacted with chlorophyllase‐related proteins, suggesting that it has a role in altering chlorophyll metabolism. Reverse transcription‐quantitative PCR gene expression analysis confirmed upregulation of genes related to photosynthesis and respiration in KU50 and R11, predominantly at 21 or 32 dpi. These findings provide valuable insights into cassava responses to SLCMV infection, especially at the protein level and are key for developing resistant cultivars and effective disease management strategies in future research. [ABSTRACT FROM AUTHOR]

Published

2024

48. Submerged macrophytes can counterbalance the negative effects of rising temperature and eutrophication by inhibiting the photosynthetic activity of cyanobacteria and adjusting their morphology and physiology.

Author

Zhao, Yu, Wang, Rong, Jeppesen, Erik, and Zhang, Enlou

Subjects

*GLOBAL warming, *LAKES, *FACTORIAL experiment designs, *PHOTOSYSTEMS, *ELECTRON transport, *PHYTOPLANKTON

Abstract

Climate‐driven changes in temperature and high nutrient inputs from anthropogenic activities significantly impact the interactions between submerged macrophytes and phytoplankton, potentially causing regime shifts in shallow freshwater lakes. Cyanobacteria, in particular, are predicted to become dominant among the phytoplankton under climate change, contributing to the collapse of submerged macrophytes. This study aimed to explore how submerged macrophytes and phytoplankton respond to rising temperatures and nutrient addition, how the presence of submerged macrophytes influences the photosynthetic activity of cyanobacteria, and how submerged macrophytes adapt their morphology and physiology to cope with excess phytoplankton. We conducted a fully factorial experiment consisting of two temperature conditions (low and high temperature), two nutrient conditions (with and without nutrient addition) and two plant conditions (plant presence and absence). We analysed changes in phytoplankton biomass and diversity (taxonomic and functional) in response to rising temperatures and nutrient addition. The maximum photochemical efficiency of the photosystem II (Fv/Fm) and the maximum relative electron transport rates (rETRmax) of cyanobacteria were determined. We measured the response of macrophytes to environmental changes by measuring antioxidant enzymes, such as superoxide dismutase (SOD) and catalase (CAT), as well as morphological indicators like plant height, weight, and the relative growth rate. In the absence of submerged macrophytes, rising temperatures led to higher total phytoplankton biomass and cyanobacteria dominance alongside reduced taxonomic and functional diversity. Conversely, when submerged macrophytes were present and no nutrients were added, rising temperatures did not lead to increased phytoplankton biomass. Macrophytes can suppress undesirable cyanobacterial proliferation by competing for nutrients and inhibiting Fv/Fm. Furthermore, under conditions of environmental stress, such as high chlorophyll a concentrations due to nutrient inputs, submerged macrophytes adapted by increasing height and the activity of antioxidant enzymes, such as SOD and CAT. Within the context of climate warming and increased nutrient inputs, phytoplankton growth, especially of cyanobacteria, may be favoured. However, our study demonstrated the critical role of submerged macrophytes in inhibiting phytoplankton, especially when nutrients were controlled. By using these physiological indicators to assess the life activity of organisms, our research provided new insights into macrophyte‐phytoplankton relationships during regime shifts in aquatic ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

49. Photorespiration – emerging insights into photoprotection mechanisms.

Author

Timm, Stefan, Sun, Hu, and Huang, Wei

Subjects

*ADENOSINE triphosphatase, *PHOTOSYNTHESIS, *HYPOTHESIS

Abstract

Two recent studies reinvestigated the phenomenon of photorespiration as a photoprotective mechanism. Smith et al. suggest alleviated negative feedback regulation of chloroplast ATP synthase as an alternative hypothesis. Von Bismarck et al. discuss how photorespiration-impaired mutants cope somewhat better with fluctuating light (FL) environments because of downregulated photosynthesis and complex metabolic re-routing. [ABSTRACT FROM AUTHOR]

Published

2024

50. Distinguishing High Daytime From Nighttime Temperature Effects During Early Vegetative Growth in Cotton.

Author

Parkash, Ved, Snider, John, Awori, Kelvin Jimmy, Katta, Jhansy Reddy, Pilon, Cristiane, and Tishchenko, Viktor

Subjects

*LEAF temperature, *STRAINS & stresses (Mechanics), *TEMPERATURE effect, *HIGH temperatures, *BIOMASS production

Abstract

High‐temperature limits early season vegetative growth of cotton, and the physiological response of cotton (Gossypium hirsutum L.) to high daytime or nighttime temperature needs to be explored. The objectives of the current study were to determine (1) plant growth response, (2) physiological contributors to variation in biomass production and (3) mechanisms driving variation in net photosynthetic rate (AN) in response to different combinations of high daytime and nighttime temperatures. Beginning at planting, cotton was exposed to four different growth temperature regimes: (1) optimum (30/20°C day/night), (2) high nighttime (30/30°C), (3) high daytime (40/20°C) and combined high daytime and nighttime (40/30°C) for 4 weeks. Relative to the 30/20°C treatment, plant growth was positively affected by high nighttime temperature and negatively affected by high daytime temperature and combined high day and night temperature. Increased leaf area mainly contributed to increased biomass production in high nighttime temperature; higher nighttime respiration (RN) drove reductions in biomass in combined high daytime and nighttime temperature; and decreased leaf area and AN and increased RN drove reductions in biomass under high daytime temperature alone. AN was not impacted by high nighttime temperature, while decreased under high daytime temperature and increased with combined high daytime and nighttime temperature. Adjustments in leaf traits contributed to increases in AN in combined high daytime and nighttime temperature, and increased photorespiration and respiration contributed to reductions in AN under high daytime temperature. Overall, early season vegetative growth of cotton exhibited differential responses to high daytime and nighttime temperatures. [ABSTRACT FROM AUTHOR]

Published

2024