Measuring the dynamic response of the thylakoid architecture in plant leaves by electron microscopy

Li, Meng; Mukhopadhyay, R.; Svoboda, Václav; Oung, Hui Min Olivia; Mullendore, Daniel L.; Kirchhoff, Helmut

doi:10.1002/pld3.280

Cited by 30 publications

(44 citation statements)

References 74 publications

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“…In contrast, P700 relative oxidation dynamics (Supplementary Materials Fig.SM-6.4) was always lacking this feature and roughly followed the oscillating light dynamics. Considering that PC was proposed to be responsible for long-distance transfer between cyt b 6 f and PSI along the thylakoid membrane, one may expect that the putative light-induced reorganization of the membrane 82,83 might be causing changes in the dynamical equilibrium between PC and P700 oxidation states. This in turn, can be accounting for the different dynamics of PC and P700 (Figs.3 and 4).…”

Section: Resultsmentioning

confidence: 99%

“…The ratio between the redox of PC and P700 is, thus, influenced by a factor that is changing in the range of minutes. With the trends in the PC dynamics changing at the oscillation phase with Chl-F extremes, we tentatively propose that the PC dynamics, unlike P700 dynamics is modulated by a factor that connects both photosystems, such as photosynthesis control 57,81 and/or systemic properties such as thylakoid topology 82,83 that may influence the diffusion of PC.…”

Section: Light Modulationmentioning

confidence: 89%

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Plants cope with fluctuating light by frequency-dependent non-photochemical quenching and cyclic electron transport

Niu

Lazár

Holzwarth

et al. 2022

Preprint

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Plants are often exposed in nature to light fluctuations with characteristic periods of several seconds to minutes. Photosynthetically active irradiance fluctuates typically in the range of several hundreds of micromol(photons).m-2.s-1. The photosynthetic regulatory networks that are necessary for minimizing damage by the dynamic load between redox reactions in fluctuating light are poorly understood. Arbitrary light fluctuations can be represented by a sum of harmonic oscillations and, to resolve the elemental components of any complex light patterns, we aimed at characterizing photosynthetic reactions in light that oscillated as an elemental sinus function. Chlorophyll fluorescence yield and optical transmission proxies of P700, plastocyanin, and ferredoxin were measured in Arabidopsis thaliana under oscillating light of various frequencies and amplitudes. The role of non-photochemical quenching (NPQ) and of cyclic electron transport around Photosystem I (CET) was studied by comparing the dynamics in wild-type plants with mutants that were deficient in NPQ (npq1 and npq4) or CET (crr2-2 and pgrl1ab). The study revealed a highly contrasting response in the mutants compared to wild type documenting relevance of non-photochemical quenching and cyclic electron transport for the functioning of plants in a dynamic light environment. The mutants deficient in the non-photochemical quenching constituents exhibited forced oscillations of much higher amplitude than those found in the wild types. The contrast was used to identify the range of frequencies (f < 1/60s) in which the non-photochemical quenching was highly effective. The frequency-domain analysis revealed complex resonance behaviors with the 1/30 s-1 and 1/60 s-1 frequencies that were absent in the npq4 mutant and reduced in the npq1 mutant. This contrast suggests an anomalous dynamic behavior of thylakoid acidification and PsbS-dependent feedback downregulation of Photosystem II light-harvesting at these frequencies. The mutants incapacitated in the cyclic electron transport exhibited a distinct dynamic response. The crr2-2 mutant lacks the activity of photosynthetic NADH dehydrogenase-like complex and typically exhibits wild-type-like induction during a dark-light transition and differs in the light-to-dark relaxation in the time domain. It showed a distinct dynamic signature in oscillating light that involved both rising and declining light phases. The pgrl1ab mutant exhibited a contrasting anomalous response to oscillating light, particularly in the redox reactions involving plastocyanin, P700, and ferredoxin. These findings thus suggest a crucial role of cyclic electron transport in the dynamic properties and regulation of the plants in fluctuating irradiance. The finding of contrasting frequency-dependent modes may explain the existence of multiple, seemingly redundant regulatory mechanisms, each presumably protecting the plant in a different frequency range. The study moreover documented that the harmonically oscillating light can serve, in addition to identifying the photosynthetic dynamics in natural fluctuating light, for revealing unique dynamic features in mutants, and, likely, for sensing plant stress. Furthermore, the sensing by harmonic forcing does not require dark-acclimation and may, thus, conveniently monitor the status of photosynthesis of plants in phenotyping platforms, in greenhouses, and in-field.

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Section: Resultsmentioning

confidence: 99%

Section: Light Modulationmentioning

confidence: 89%

Plants cope with fluctuating light by frequency-dependent non-photochemical quenching and cyclic electron transport

Niu

Lazár

Holzwarth

et al. 2022

Preprint

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“…The number of thylakoids per granum was also determined (e.g., Brangeon, 1973;Mostowska, 1986). Such basic parameters are also frequently assessed in current microscopy studies using digital micrographs and image analysis software of choice, followed by different approaches in data presentation and appropriate statistical analyses (e.g., Rozak et al, 2002;Anderson et al, 2012;Pietrzykowska et al, 2014;Pribil et al, 2018;Wood et al, 2018;Nicol et al, 2019;Li et al, 2020).…”

Section: Grana Ultrastructural Parametersmentioning

confidence: 99%

“…SRD might also be measured directly through manual or semi-automated segmentation of particular granum elements (membrane, lumen, and partition gap) using high magnifications. Various semi-automated approaches based on pixel gradient and power spectrum analyses were applied by different authors (Kirchhoff et al, 2011;Tsabari et al, 2015;Wood et al, 2018;Li et al, 2020; for details, see Figure 2B). It should be noted that all detailed analyses of granum layers require high-quality images of grana stacks cut parallelly to the vertical granum direction (Figure 2C).…”

Section: Grana Ultrastructural Parametersmentioning

confidence: 99%

How to Measure Grana – Ultrastructural Features of Thylakoid Membranes of Plant Chloroplasts

2021

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Granum is a basic structural unit of the thylakoid membrane network of plant chloroplasts. It is composed of multiple flattened membranes forming a stacked arrangement of a cylindrical shape. Grana membranes are composed of lipids and tightly packed pigment-protein complexes whose primary role is the catalysis of photosynthetic light reactions. These membranes are highly dynamic structures capable of adapting to changing environmental conditions by fine-tuning photochemical efficiency, manifested by the structural reorganization of grana stacks. Due to a nanometer length scale of the structural granum features, the application of high-resolution electron microscopic techniques is essential for a detailed analysis of the granum architecture. This mini-review overviews recent approaches to quantitative grana structure analyses from electron microscopy data, highlighting the basic manual measurements and semi-automated workflows. We outline and define structural parameters used by different authors, for instance, granum height and diameter, thylakoid thickness, end-membrane length, Stacking Repeat Distance, and Granum Lateral Irregularity. This article also presents insights into efficient and effective measurements of grana stacks visualized on 2D micrographs. The information on how to correctly interpret obtained data, taking into account the 3D nature of grana stacks projected onto 2D space of electron micrograph, is also given. Grana ultrastructural observations reveal key features of this intriguing membrane arrangement, broadening our knowledge of the thylakoid network’s remarkable plasticity.

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“…1-200 nm in near in vivo conditions and is widely applied in structural biology and soft matter sciences. Small-angle scattering complements various microscopic techniques, such as TEM (Menke, 1960;Paolillo and Paolillo, 1970;Staehelin, 1986;Austin and Staehelin, 2011;Armbruster et al, 2013;Heinz et al, 2016;Kowalewska et al, 2016;Wood et al, 2018;Kowalewska et al, 2019;Wood et al, 2019;Li et al, 2020), scanning electron microscopy (Mustárdy and Jánossy, 1979;Armbruster et al, 2013), cryo-EM (Ford et al, 2002;Kirchhoff et al, 2011;Engel et al, 2015), cryoelectron tomography (Shimoni et al, 2005;Austin and Staehelin, 2011;Daum and Kühlbrandt, 2011;Kouřil et al, 2011;Ford and Holzenburg, 2014;Bussi et al, 2019;Rast et al, 2019), atomic force microscopy (Kaftan et al, 2002;Sturgis et al, 2009;Sznee et al, 2011;Grzyb et al, 2013;Onoa et al, 2014), confocal laser scanning microscopy (Kowalewska et al, 2016;Mazur et al, 2019), and live cell imaging (Iwai et al, 2014;Iwai et al, 2016). The first scattering studies on photosynthetic membranes were performed in 1953 by Finean et al (1953) and has continued ever since.…”

Section: Introductionmentioning

confidence: 99%

Small-Angle X-Ray and Neutron Scattering on Photosynthetic Membranes

et al. 2021

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Ultrastructural membrane arrangements in living cells and their dynamic remodeling in response to environmental changes remain an area of active research but are also subject to large uncertainty. The use of noninvasive methods such as X-ray and neutron scattering provides an attractive complimentary source of information to direct imaging because in vivo systems can be probed in near-natural conditions. However, without solid underlying structural modeling to properly interpret the indirect information extracted, scattering provides at best qualitative information and at worst direct misinterpretations. Here we review the current state of small-angle scattering applied to photosynthetic membrane systems with particular focus on data interpretation and modeling.

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Measuring the dynamic response of the thylakoid architecture in plant leaves by electron microscopy

Cited by 30 publications

References 74 publications

Plants cope with fluctuating light by frequency-dependent non-photochemical quenching and cyclic electron transport

Plants cope with fluctuating light by frequency-dependent non-photochemical quenching and cyclic electron transport

How to Measure Grana – Ultrastructural Features of Thylakoid Membranes of Plant Chloroplasts

Small-Angle X-Ray and Neutron Scattering on Photosynthetic Membranes

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