Blue light induces major changes in the gene expression profile of the cyanobacterium <scp><i>Synechocystis</i></scp> sp. PCC 6803

Luimstra, Veerle M.; Schuurmans, J. Merijn; Hellingwerf, Klaas J.; Matthijs, H.C.P.; Huisman, Jef

doi:10.1111/ppl.13086

Cited by 22 publications

(32 citation statements)

References 97 publications

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“…It is a question, whether the special redistribution of PSI at L-D cycle is favorable for larger NADPH production (formed in photosynthesis) that is preferentially used (more than NADH) as a reductant source for ROS detoxification (Flores and Herrero, 2005). The similar light-induced response on PSI level is visible also for cyanobacterial cells acclimated to highlight (Kopečná et al, 2012) or to a light of different quality (El Bissati and Kirilovsky, 2001;Luimstra et al, 2020). It is well know that a shift from low-light to high-light growth conditions stimulates decrease in the PSI to PSII ratio due to selective suppression of the amount of functional PSI (Murakami and Fujita, 1993;Murakami et al, 1997).…”

Section: Discussionmentioning

confidence: 99%

“…In light with the above-mentioned results, we tend to suggest that also TM plasticity, as we saw it based on PSI/PSII and PBS co-localization ( Figure 2 ), is controlled by PSI to PSII ratio. The change in the ratio is induced by light and includes regulation of several genes ( Luimstra et al, 2020 ). However, it is still not clear whether PSI to PSII ratio is a redox-control ( El Bissati and Kirilovsky, 2001 ) or a photoreceptor control process.…”

Section: Discussionmentioning

confidence: 99%

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Plasticity of Cyanobacterial Thylakoid Microdomains Under Variable Light Conditions

2020

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Photosynthetic light reactions proceed in thylakoid membranes (TMs) due to the activity of pigment–protein complexes. These complexes are heterogeneously organized into granal/stromal thylakoids (in plants) or into recently identified cyanobacterial microdomains (MDs). MDs are characterized by specific ratios of photosystem I (PSI), photosystem II (PSII), and phycobilisomes (PBS) and they are visible as sub-micrometer sized areas with different fluorescence ratios. In this report, the process of long-term plasticity in cyanobacterial thylakoid MDs has been explored under variable growth light conditions using Synechocystis sp. PCC6803 expressing YFP tagged PSI. TM organization into MDs has been observed for all categorized shapes of cells independently of their stage in cell cycle. The heterogeneous PSI, PSII, and PBS thylakoid areas were also identified under two types of growth conditions: at continuous light (CL) and at light-dark (L-D) cycle. The acclimation from CL to L-D cycle changed spatial distribution of photosystems, in particular PSI became more evenly distributed in thylakoids under L-D cycle. The process of the spatial PSI (and partially also PSII) redistribution required 1 week and was accompanied by temporal appearance of PBS decoupling probably caused by the re-organization of photosystems. The overall acclimation we observed was defined as TM plasticity as it resembles higher plants grana/stroma reorganization at variable growth light conditions. In addition, we observed large cell to cell variability in the actual MDs organization. It leads us to suggest that the plasticity, and cell to cell variability in MDs could be a manifestation of phenotypic heterogeneity, a recently broadly discussed phenomenon for prokaryotes.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Plasticity of Cyanobacterial Thylakoid Microdomains Under Variable Light Conditions

2020

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“…For example, photosynthesis in cyanobacteria can be negatively influenced by blue light. Luimstra et al (2018Luimstra et al ( , 2020 showed that there is a major imbalance in electron transport between photo system (PS)I and PSII in the cyanobacterial genus Synechocystis. Cyanobacteria have more chlorophyll in PSI than in PSII.…”

Section: Drastic Shift In Natural Phytoplankton Communitiesmentioning

confidence: 99%

“…Complementary to chlorophyll-a, cyanobacteria have accessory pigments (phycobilins) allowing them efficiently to use light within the green gap of chlorophyll-a and -b (Britton, 1983). Luimstra et al (2020) showed in their laboratory study that cyanobacteria growth under blue light decreases because of low photosynthetic efficiency, when phycobilins are present.…”

Section: Introductionmentioning

confidence: 99%

Community shifts from eukaryote to cyanobacteria dominated phytoplankton: The role of mixing depth and light quality

et al. 2021

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1. Lake stratification strengthens with increasing surface water temperatures, thereby reducing the depth of the mixed layer. Phytoplankton communities are not only exposed to different nutrient availability within a mixed water column, but also to different light quality. We conducted controled laboratory and mesocosm experiments to investigate phytoplankton, especially cyanobacteria, responses to different light quality and mixing depths.2. Our mesocosm experiment allowed the manipulation of mixing depth in situ by a mesocosm approach and to follow the effects of changing mixing depth on the phytoplankton community composition. Our laboratory experiment allowed the

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“…Light intensity is positively correlated with both the number of β-carboxysomes per cell and the carbon fixation capacity [ 120 ], and is essential for maximising biomass accumulation [ 121 – 123 ]. However, cyanobacteria are known to experience light-induced stress dependent on the light intensity [ 121 ] and wavelength [ 124 ]. A common mechanism of adaptation to changes in light intensity is the alteration of flux between the synthesis and use of glycogen and other carbon sinks [ 125 ].…”

Section: Environmental Stressmentioning

confidence: 99%

Combinatorial use of environmental stresses and genetic engineering to increase ethanol titres in cyanobacteria

Andrews

Faulkner

Toogood

et al. 2021

Biotechnol Biofuels

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Current industrial bioethanol production by yeast through fermentation generates carbon dioxide. Carbon neutral bioethanol production by cyanobacteria uses biological fixation (photosynthesis) of carbon dioxide or other waste inorganic carbon sources, whilst being sustainable and renewable. The first ethanologenic cyanobacterial process was developed over two decades ago using Synechococcus elongatus PCC 7942, by incorporating the recombinant pdc and adh genes from Zymomonas mobilis. Further engineering has increased bioethanol titres 24-fold, yet current levels are far below what is required for industrial application. At the heart of the problem is that the rate of carbon fixation cannot be drastically accelerated and carbon partitioning towards bioethanol production impacts on cell fitness. Key progress has been achieved by increasing the precursor pyruvate levels intracellularly, upregulating synthetic genes and knocking out pathways competing for pyruvate. Studies have shown that cyanobacteria accumulate high proportions of carbon reserves that are mobilised under specific environmental stresses or through pathway engineering to increase ethanol production. When used in conjunction with specific genetic knockouts, they supply significantly more carbon for ethanol production. This review will discuss the progress in generating ethanologenic cyanobacteria through chassis engineering, and exploring the impact of environmental stresses on increasing carbon flux towards ethanol production.

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Blue light induces major changes in the gene expression profile of the cyanobacterium Synechocystis sp. PCC 6803

Cited by 22 publications

References 97 publications

Plasticity of Cyanobacterial Thylakoid Microdomains Under Variable Light Conditions

Plasticity of Cyanobacterial Thylakoid Microdomains Under Variable Light Conditions

Community shifts from eukaryote to cyanobacteria dominated phytoplankton: The role of mixing depth and light quality

Combinatorial use of environmental stresses and genetic engineering to increase ethanol titres in cyanobacteria

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