Time-resolved fluorescence measurements on leaves: principles and recent developments

Chukhutsina, Volha U.; Holzwarth, Alfred R.; Croce, Roberta

doi:10.1007/s11120-018-0607-8

Cited by 40 publications

(43 citation statements)

References 87 publications

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“…This lifetime is in agreement with our ensemble spectroscopy data of the extracted thylakoids in solution (<τ> ~ 0.5 ns) and is in good agreement with previous reports of LHCII and PSII within intact chloroplasts and leaves. [58][59][60] This <τ> is much shorter than the lifetime known for isolated LH and PS proteins in detergent (~ 4ns), as expected, due to the quenching effect of protein-protein interactions present in thylakoids. Overall, this shows that our FLIM data on LH membrane samples agree nicely with standard spectroscopy and that the deposition of the membranes on glass surfaces has no apparent impact on the sample.…”

Section: Resultssupporting

confidence: 61%

Understanding the photophysics and structural organization of photosynthetic proteins using model lipid membranes assembled from natural plant thylakoids

Meredith

Yoneda

Hancock

et al. 2020

Preprint

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The light-harvesting (LH) biomembranes from photosynthetic organisms perform solar energy absorption and transfer with high efficiency. There is great interest in the nanoscale biophysics of photosynthesis, however, natural membranes are complex and highly curved so can be challenging to study. Here we present model photosynthetic “hybrid membranes” assembled from a combination of natural LH membranes and synthetic lipids deposited into a patterned polymerized lipid template on glass. This arrangement offers many advantages over previous model systems including: a sufficiently complex mixture of natural proteins to mimic the biological processes, a modular self-assembly mechanism, and a stabilizing template promoting the formation of supported lipid bilayers from complex natural membranes with high protein content (that would not otherwise form). These hybrid membranes can be used as a platform to delineate the complex relationship between LH energy pathways and membrane organization. Atomic force microscopy and fluorescence lifetime microscopy revealed that hybrid membranes have an elongated fluorescence lifetime (∼4 ns) compared to native membranes (∼0.5 ns), a direct consequence of reduced protein density and an uncoupling of protein-protein interactions. We observed the real time self-assembly and migration of LH proteins from natural membrane extracts into the hybrid membranes and monitored the photophysical state of the membranes at each stage. Finally, experiments utilizing our hybrid membranes suggest that assays currently used in the photosynthesis community to test the electron transfer activity of Photosystem II may have non-specific interactions with other proteins, implying that new methods are needed for reliable quantification of electron transfers in photosynthesis.

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Section: Resultssupporting

confidence: 61%

Understanding the photophysics and structural organization of photosynthetic proteins using model lipid membranes assembled from natural plant thylakoids

Meredith

Yoneda

Hancock

et al. 2020

Preprint

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“…The in vitro environments, which employ detergent or crystallization, may introduce additional, non-native conformational changes that could alter or even denature the functional structure of membrane proteins [30][31][32] . In contrast, in vivo spectroscopy on whole leaves provides physiological information [33][34][35] . However, identifying the photophysical pathways in each of the homologous antenna complexes is not possible.…”

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confidence: 99%

Observation of dissipative chlorophyll-to-carotenoid energy transfer in light-harvesting complex II in membrane nanodiscs

et al. 2020

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Plants prevent photodamage under high light by dissipating excess energy as heat. Conformational changes of the photosynthetic antenna complexes activate dissipation by leveraging the sensitivity of the photophysics to the protein structure. The mechanisms of dissipation remain debated, largely due to two challenges. First, because of the ultrafast timescales and large energy gaps involved, measurements lacked the temporal or spectral requirements. Second, experiments have been performed in detergent, which can induce nonnative conformations, or in vivo, where contributions from homologous antenna complexes cannot be disentangled. Here, we overcome both challenges by applying ultrabroadband twodimensional electronic spectroscopy to the principal antenna complex, LHCII, in a near-native membrane. Our data provide evidence that the membrane enhances two dissipative pathways, one of which is a previously uncharacterized chlorophyll-to-carotenoid energy transfer. Our results highlight the sensitivity of the photophysics to local environment, which may control the balance between light harvesting and dissipation in vivo.

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“…Consequently, spectroscopic techniques have been developed that allow measurements with intact leaves or leaf tissues (e.g. Sacksteder et al ., ; Klughammer et al ., ; Chukhutsina et al ., ). Nowadays, the functionalities of all energy‐converting protein complexes as well xanthophyll cycle activities and membrane energization can be measured with commercially available instruments in intact leaves.…”

Section: New Techniques – Better Insightsmentioning

confidence: 99%

Chloroplast ultrastructure in plants

Kirchhoff

2019

New Phytologist

155

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Summary The chloroplast organelle in mesophyll cells of higher plants represents a sunlight‐driven metabolic factory that eventually fuels life on our planet. Knowledge of the ultrastructure and the dynamics of this unique organelle is essential to understanding its function in an ever‐changing and challenging environment. Recent technological developments promise unprecedented insights into chloroplast architecture and its functionality. The review highlights these new methodical approaches and provides structural models based on recent findings about the plasticity of the thylakoid membrane system in response to different light regimes. Furthermore, the potential role of the lipid droplets plastoglobuli is discussed. It is emphasized that detailed structural insights are necessary on different levels ranging from molecules to entire membrane systems for a holistic understanding of chloroplast function.

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Time-resolved fluorescence measurements on leaves: principles and recent developments

Cited by 40 publications

References 87 publications

Understanding the photophysics and structural organization of photosynthetic proteins using model lipid membranes assembled from natural plant thylakoids

Understanding the photophysics and structural organization of photosynthetic proteins using model lipid membranes assembled from natural plant thylakoids

Observation of dissipative chlorophyll-to-carotenoid energy transfer in light-harvesting complex II in membrane nanodiscs

Chloroplast ultrastructure in plants

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