Photosynthesis: basics, history and modelling

Makowski

et al. 2020

IJMS

Ceylon leadwort (Plumbago zeylanica) is ornamental plant known for its pharmacological properties arising from the abundant production of various secondary metabolites. It often grows in lead polluted areas. The aim of presented study was to evaluate the survival strategy of P. zeylanica to lead toxicity via photosynthetic apparatus acclimatization. Shoots of P. zeylanica were cultivated on media with different Pb concentrations (0.0, 0.05, and 0.1 g Pb∙l−1). After a four-week culture, the efficiency of the photosynthetic apparatus of plants was evaluated by Chl a fluorescence measurement, photosynthetic pigment, and Lhcb1, PsbA, PsbO, and RuBisCo protein accumulation, antioxidant enzymes activity, and chloroplast ultrastructure observation. Plants from lower Pb concentration revealed no changes in photosynthetic pigments content and light-harvesting complex (LHCII) size, as well as no limitation on the donor side of Photosystem II Reaction Centre (PSII RC). However, the activity and content of antioxidant enzymes indicated a high risk of limitation on the acceptor side of Photosystem I. In turn, plants from 0.1 g Pb∙l−1 showed a significant decrease in pigments content, LHCII size, the amount of active PSII RC, oxygen-evolving complex activity, and significant remodeling of chloroplast ultrastructure indicated limitation of PSII RC donor side. Obtained results indicate that P. zeylanica plants acclimate to lead toxicity by Pb accumulation in roots and, depending on Pb concentration, by adjusting their photosynthetic apparatus via the activation of alternative (cyclic and pseudocyclic) electron transport pathways.

Section: Discussionmentioning

confidence: 99%

Can Ceylon Leadwort (Plumbago zeylanica L.) Acclimate to Lead Toxicity?—Studies of Photosynthetic Apparatus Efficiency

Makowski

et al. 2020

IJMS

“…Portanto, a dinâmica de crescimento das plantas em um sistema de produção será em relação à intensidade das alterações da quantidade e qualidade da luz. A radiação solar que chega ao nível do solo é utilizada pelas plantas via fotossíntese para converter o carbono atmosférico em componentes essenciais para o seu crescimento, desenvolvimento e demais processos metabólicos como respiração e reprodução (STIRBET et al, 2019).…”

Section: Revisão Bibliográfica 21 Ambiente Luminosounclassified

“…A eficiência de conversão da energia luminosa em energia química determina a produção final de matéria seca de uma planta (BELLASIO; GRIFFITHS, 2014). A energia luminosa utilizada nessa conversão por meio da fotossíntese está restrita ao comprimento de onda do espectro da RFA, com picos de absorção em 680 e 700 nm (STIRBET et al, 2019).…”

Section: Revisão Bibliográfica 21 Ambiente Luminosounclassified

“…Elétrons contidos nos fotossistemas das moléculas dos pigmentos fotossintetizantes (i.e., clorofila a, principalmente) passam por uma sequência de reações até a produção de ATP. As moléculas de clorofila e os demais pigmentos fotossintetizantes utilizam a RFA dos comprimentos de ondas, desse modo a quantidade da radiação incidente determina a máxima eficiência fotossintética da planta (STIRBET et al, 2019).…”

Section: Revisão Bibliográfica 21 Ambiente Luminosounclassified

See 1 more Smart Citation

Efeito Do Ambiente Luminoso Em Forrageiras De Clima Tropical Em Sistemas Silvipastoris

Santos

Gomes

Ximenes³

et al. 2020

NAT

Alterações no ambiente luminoso provocam mudanças adaptativas nas plantas, na tentativa de manter o seu crescimento e desenvolvimento. Objetivou-se com esta revisão investigar e descrever o efeito do ambiente luminoso no crescimento e desenvolvimento de forrageiras de clima tropical em sistemas silvipastoris. A compreensão da influência do ambiente luminoso e, das mudanças biológicas que as diferentes intensidades do sombreamento podem causar nas forrageiras de clima tropical, possibilita fundamentar as alterações metabólicas das respostas das plantas na tentativa de se manterem persistentes em sistemas sombreados. A partir disso, entender quais são os níveis aceitáveis de radiação para que os sistemas de produção sombreados não entrem em colapso é fundamental para que tomadas de decisões sejam realizadas no tempo hábil do ciclo biológico das espécies vegetais. Em sistemas silvipastoris, a redução da luz incidente em forrageiras de clima tropical provoca alterações como aumento da área foliar específica, redução na densidade populacional de perfilhos e na relação raízes: parte aérea da planta. Cada espécie ou cultivar apresenta características adaptativas específicas ao sombreamento com a finalidade de aproveitar os recursos disponíveis em tecidos fotossintéticos e de suporte. No entanto, ainda assim o sombreamento intenso (>40%) afeta negativamente a produção forrageira de acordo com a variabilidade climática. Palavras-chave: adaptação morfofisiológica; fotossíntese; luz; plantas C4. EFFECT OF THE LIGHT ENVIRONMENT IN TROPICAL CLIMATE FORAGES IN SILVOPASTORAL SYSTEMS ABSTRACT: Changes in the light environment cause adaptive changes in plants, to maintain their growth and development. The aim of this review is to investigate and describe the light environment effect on the growth and development of tropical forages in silvopastoral systems. The understanding of the influence of the light environment and the biological changes that different shading intensities can cause in tropical forages, makes it possible to substantiate the metabolic alterations of plant responses to remain persistent in shaded systems. From this, understanding what are the acceptable levels of radiation so that the systems do not collapse is essential for decision-making to be carried out in a timely manner in the plant's biological cycle. In silvopastoral systems, a light incidence reduction on tropical forages causes changes such as an increase in the leaf area index, reduction in the tiller population density, and shoot: root ratio. Each species or cultivar has adaptive characteristics specific to shading to take advantage of the resources available in photosynthetic and support tissue. However, even so, the intense shading (> 40%) negatively affects forage production according to climatic variability. Keywords: morphophysiological adaptation; photosynthesis; light; C4 plants.

“…Here, we have assumed that differences in the initial Chl fluorescence (FO) (measured with direct light) from the blue grama grass cells are mainly due to differences in Chl concentration between the samples (see e.g., Strasser et al 2004). This is a reasonable assumption since the PQ pool is expected to be all in the oxidized state (see discussion in Stirbet et al 2019;cf. Feild et al 1998 for information on chlororespiration that could, in principle, affect it).…”

Section: Chl Fluorescence Induction Datamentioning

confidence: 99%

Special issue in honour of Prof. Reto J. Strasser - A comparative chlorophyll a fluorescence study on isolated cells and intact leaves of Bouteloua gracilis (blue grama grass)

Jiménez-Francisco¹,

Stirbet²,

Campos³

et al. 2020

Photosynt.

Bouteloua gracilis (blue grama grass) is one of the most drought and grazing tolerant plants in the short-grass ecosystem. To obtain information on their photosystem activities, we measured the fast (< 1 s) chlorophyll a fluorescence transient (the OJIP curve) from their leaves, and isolated cells grown photoautotrophically in suspension in a culture medium, or with added sucrose. One of our goals was to study the effect of different sucrose concentrations (0, 0.15, 0.3, and 3%) on PSII activity in isolated cells. Our results on cells suspended in culture medium, using the JIP-test, showed a decrease in PSII activity at increasing sucrose concentrations, while the photoautotrophic cells showed an optimal PSII activity, close to that of the leaves. Further, our data on cells grown in 0, 0.15, and 0.3% sucrose, but with added CO2, and measured while the cells were deposited on filter paper, indicate that supplementary CO2 can increase the PSII activity in the presence of sucrose, although further research is necessary to understand these results. Additional key words: kinetic parameters of the O-J, J-I, and I-P phases; osmotic stress; performance index. (G. Govindjee), catre@colpos.mx (C. Trejo) Abbreviations: Area (as related to chlorophyll a fluorescence induction curve) -area between the OJIP transient and the horizontal line at maximum fluorescence, FM; Chl -chlorophyll; ChlFI -chlorophyll a fluorescence induction; DCMU (diuron) -3-(3,4-dichlorophenyl)-1,1-dimethylurea; FK, FJ (fluorescence at the J level), FI (fluorescence at the I level), and FP (fluorescence at the P level) -chlorophyll a fluorescence at 0.3, 2, 30 ms, and at the peak P of chlorophyll a fluorescence induction, respectively; FM -maximum Chl a fluorescence; FO -minimum Chl a fluorescence (fluorescence at the O level); FV -the (maximum) variable fluorescence, which is FM -FO; OEC -oxygen-evolving complex; OJIP transient -the Chl a fluorescence transient from FO to FP; PQ -plastoquinone; PSI -photosystem I; PSII -photosystem II; QA and QB -primary and secondary plastoquinone electron acceptors of the photosystem II.Acknowledgements: Govindjee thanks the staff of Information Technology in Life Sciences at the University of Illinois at Urbana-Champaign (UIUC) for their help with the use of computers; he is also grateful to the staff of the