Enhancing carotenogenesis in terrestrial microalgae by UV-A light stress

Mutschlechner, Mira; Walter, Andreas; Colleselli, Lucia; Griesbeck, Christoph; Schöbel, Harald

doi:10.1007/s10811-022-02772-5

Cited by 12 publications

(7 citation statements)

References 44 publications

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“…For beta diversity, the slopes reached a plateau at higher light levels for both algae and bacteria, indicating homogeneous communities at higher light conditions. This suggests that the algal and bacterial communities become less rich but are potentially adapted to higher light conditions, for example, through the synthesis of carotenoid compounds [ 89 ]. Although many fungi employ strategies to limit damage from UV radiation, making them potentially more resistant to high light stress [ 90 ], we detected high rates of change under high light conditions for fungi.…”

Section: Discussionmentioning

confidence: 99%

Biotic interactions outweigh abiotic factors as drivers of bark microbial communities in Central European forests

Dreyling,

Penone,

Schenk

et al. 2024

ISME Communications

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Bark surfaces are extensive areas within forest ecosystems, that provide an ideal habitat for microbial communities, through their longevity and seasonal stability. Here we provide a comprehensive account of the bark surface microbiome of living trees in Central European forests, and identify drivers of diversity and community composition. We examine algal, fungal and bacterial communities and their interactions using metabarcoding on samples from over 750 trees collected in the Biodiversity Exploratories in northern, central and southern Germany. We show that mutual biotic influence is more important than the abiotic environment with regard to community composition, whereas abiotic conditions and geography are more important for alpha diversity. Important abiotic factors are the relative humidity and light availability, which decrease the algal and bacterial alpha diversity, but strongly increase fungal alpha diversity. In addition, temperature is important in shaping the microbial community, with higher temperature leading to homogeneous communities of dominant fungi, but high turnover in bacterial communities. Changes in the community dissimilarity of one organismal group occurs in close relation to changes in the other two, suggesting that there are close interactions between the three major groups of the bark surface microbial communities, which may be linked to beneficial exchange. To understand the functioning of the forest microbiome as a whole, we need to further investigate the functionality of interactions within the bark surface microbiome and combine these results with findings from other forest habitats such as soil or canopy.

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Section: Discussionmentioning

confidence: 99%

Biotic interactions outweigh abiotic factors as drivers of bark microbial communities in Central European forests

Dreyling,

Penone,

Schenk

et al. 2024

ISME Communications

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“…LED technologies are used among others for UV disinfection purposes (Song et al 2016 ; Li et al 2017 ) or in photomedicine, like dental applications (Wiggins et al 2004 ), in dermatology (Jagdeo et al 2018 ) or for photodynamic therapy (Hempstead et al 2015 ; Fiala et al 2021 ). Regarding biomass and metabolite production in plants (Bantis et al 2018 ; Ju et al 2022 ), microalgae (Moreira et al 2021 ; Mutschlechner et al 2022 ) and cyanobacteria (Oren et al 2021 ) artificial lighting based on LED technology is to be on the rise.…”

Section: Current Status In Bio-illuminationmentioning

confidence: 99%

Shed light on photosynthetic organisms: a physical perspective to correct light measurements

Walter

Schöbel

2023

Photosynth Res

Self Cite

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The requirements for novel and innovative production systems expedite research on light emitting diode-based illumination in a life science context. In course of these rapid developments, the scientific community is in need of a consensus regarding to the characterization and presentation of the applied lighting conditions. This publication aims to establish a basic understanding of photon physics and propose guidelines for the conclusive usage of light related quantities. To illustrate the challenges in data handling, six different light sources were measured and characterized. Furthermore, a stepwise conversion within and in-between physical systems is presented, and an opportunity to extract information from weak data sets is demonstrated. The proposed calculations indicated flexibility in data handling, but revealed partial inaccuracy for colored light emitting diodes with spectral power distribution maxima far-off 550 nm compared to spectrometer-based measurements and conversions. Furthermore, it could be shown, that when comparing light properties, the determination of photometric quantities is incorrect to describe lighting systems for photosynthetic organism and the usage of luxmeter or similar photometric sensors should be avoided. The presented guidelines shall support scientists in applying a consistent and precise characterization of their illumination regimes, tailored to their requirements to avoid ambiguous communication and the generation of incorrect and thus incomparable data based on wrong quantities and units, such as lumen or lux, in future research.

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“…Microalgae, the minuscule powerhouses of the aquatic and terrestrial environment, are revolutionizing various scientific disciplines with their diverse applications [ 1 , 2 , 3 , 4 ]. Despite their microscopic size, they play a critical role in Earth’s ecosystem and offer opportunities to solve global challenges [ 5 , 6 , 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Laboratory-Based and Spectroscopic Methods Used to Estimate the Algal Density of Chlorella vulgaris

Fekete,

Sebők,

Klátyik

et al. 2024

Microorganisms

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Chlorella vulgaris is of great importance in numerous exploratory or industrial applications (e.g., medicals, food, and feed additives). Rapid quantification of algal biomass is crucial in photobioreactors for the optimization of nutrient management and the estimation of production. The main goal of this study is to provide a simple, rapid, and not-resource-intensive estimation method for determining the algal density of C. vulgaris according to the measured parameters using UV–Vis spectrophotometry. Comparative assessment measurements were conducted with seven different methods (e.g., filtration, evaporation, chlorophyll a extraction, and detection of optical density and fluorescence) to determine algal biomass. By analyzing the entire spectra of diluted algae samples, optimal wavelengths were determined through a stepwise series of linear regression analyses by a novel correlation scanning method, facilitating accurate parameter estimation. Nonlinear formulas for spectrometry-based estimation processes were derived for each parameter. As a result, a general formula for biomass concentration estimation was developed, with recommendations for suitable measuring devices based on algae concentration levels. New values for magnesium content and the average single-cell weight of C. vulgaris were established, in addition to the development of a rapid, semiautomated cell counting method, improving efficiency and accuracy in algae quantification for cultivation and biotechnology applications.

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Enhancing carotenogenesis in terrestrial microalgae by UV-A light stress

Cited by 12 publications

References 44 publications

Biotic interactions outweigh abiotic factors as drivers of bark microbial communities in Central European forests

Biotic interactions outweigh abiotic factors as drivers of bark microbial communities in Central European forests

Shed light on photosynthetic organisms: a physical perspective to correct light measurements

Comparative Analysis of Laboratory-Based and Spectroscopic Methods Used to Estimate the Algal Density of Chlorella vulgaris

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