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Main Authors: Cvjetinovic, Julijana, Bedoshvili, Yekaterina D, Davidovich, Nickolai A, Maksimov, Eugene G, Prikhozhdenko, Ekaterina S, Todorenko, Daria A, Bodunova, Daria V, Davidovich, Olga I, Sergeev, Igor S, Gorin, Dmitry A
Format: Artículo científico
Language:en
Published: Scientific reports 2024
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Online Access:https://pubmed.ncbi.nlm.nih.gov/39738413/
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author Cvjetinovic, Julijana
Bedoshvili, Yekaterina D
Davidovich, Nickolai A
Maksimov, Eugene G
Prikhozhdenko, Ekaterina S
Todorenko, Daria A
Bodunova, Daria V
Davidovich, Olga I
Sergeev, Igor S
Gorin, Dmitry A
author_facet Cvjetinovic, Julijana
Bedoshvili, Yekaterina D
Davidovich, Nickolai A
Maksimov, Eugene G
Prikhozhdenko, Ekaterina S
Todorenko, Daria A
Bodunova, Daria V
Davidovich, Olga I
Sergeev, Igor S
Gorin, Dmitry A
Cvjetinovic, Julijana
Bedoshvili, Yekaterina D
Davidovich, Nickolai A
Maksimov, Eugene G
Prikhozhdenko, Ekaterina S
Todorenko, Daria A
Bodunova, Daria V
Davidovich, Olga I
Sergeev, Igor S
Gorin, Dmitry A
collection PubMed - marine biology
contents Exploring salinity induced adaptations in marine diatoms using advanced photonic techniques. Cvjetinovic, Julijana Bedoshvili, Yekaterina D Davidovich, Nickolai A Maksimov, Eugene G Prikhozhdenko, Ekaterina S Todorenko, Daria A Bodunova, Daria V Davidovich, Olga I Sergeev, Igor S Gorin, Dmitry A Diatoms Salinity Adaptation, Physiological Microscopy, Fluorescence Photoacoustic Techniques Chlorophyll Photonic-based methods are crucial in biology and medicine due to their non-invasive nature, allowing remote measurements without affecting biological specimens. The study of diatoms using advanced photonic methods remains a relatively underexplored area, presenting significant opportunities for pioneering discoveries. This research provides a comprehensive analysis of marine diatoms, specifically Nitzschia sp., across varying salinity levels, integrating fluorescence lifetime imaging microscopy (FLIM), combined photoacoustic and fluorescence tomographies (PAFT), and ultrastructural examinations using transmission electron microscopy. Key findings include a systematic shift in the mean fluorescence lifetime from 570 ps at 20‰ to 940 ps at 80‰, indicating functional adaptations in chlorophyll molecules within light-harvesting complexes. At 60‰ salinity, anomalies are observed in the development of silica valves and polysaccharide layers, suggesting abnormalities in valve morphogenesis. Lipid droplets within the cells display a minimum diameter at 40‰, indicating metabolic adjustments to osmotic stress. The intensity of both fluorescence and photoacoustic signals increases with increasing salinity levels. These insights enhance understanding of the ecological implications of salinity stress on diatom communities and pave the way for future research on leveraging the unique adaptive mechanisms of microalgae for environmental monitoring and sustainable biotechnological applications.
format Artículo científico
id pubmed_39738413
institution PubMed
language en
publishDate 2024
publisher Scientific reports
record_format pubmed
spellingShingle Exploring salinity induced adaptations in marine diatoms using advanced photonic techniques.
Cvjetinovic, Julijana
Bedoshvili, Yekaterina D
Davidovich, Nickolai A
Maksimov, Eugene G
Prikhozhdenko, Ekaterina S
Todorenko, Daria A
Bodunova, Daria V
Davidovich, Olga I
Sergeev, Igor S
Gorin, Dmitry A
Diatoms
Salinity
Adaptation, Physiological
Microscopy, Fluorescence
Photoacoustic Techniques
Chlorophyll
Exploring salinity induced adaptations in marine diatoms using advanced photonic techniques. Cvjetinovic, Julijana Bedoshvili, Yekaterina D Davidovich, Nickolai A Maksimov, Eugene G Prikhozhdenko, Ekaterina S Todorenko, Daria A Bodunova, Daria V Davidovich, Olga I Sergeev, Igor S Gorin, Dmitry A Diatoms Salinity Adaptation, Physiological Microscopy, Fluorescence Photoacoustic Techniques Chlorophyll Photonic-based methods are crucial in biology and medicine due to their non-invasive nature, allowing remote measurements without affecting biological specimens. The study of diatoms using advanced photonic methods remains a relatively underexplored area, presenting significant opportunities for pioneering discoveries. This research provides a comprehensive analysis of marine diatoms, specifically Nitzschia sp., across varying salinity levels, integrating fluorescence lifetime imaging microscopy (FLIM), combined photoacoustic and fluorescence tomographies (PAFT), and ultrastructural examinations using transmission electron microscopy. Key findings include a systematic shift in the mean fluorescence lifetime from 570 ps at 20‰ to 940 ps at 80‰, indicating functional adaptations in chlorophyll molecules within light-harvesting complexes. At 60‰ salinity, anomalies are observed in the development of silica valves and polysaccharide layers, suggesting abnormalities in valve morphogenesis. Lipid droplets within the cells display a minimum diameter at 40‰, indicating metabolic adjustments to osmotic stress. The intensity of both fluorescence and photoacoustic signals increases with increasing salinity levels. These insights enhance understanding of the ecological implications of salinity stress on diatom communities and pave the way for future research on leveraging the unique adaptive mechanisms of microalgae for environmental monitoring and sustainable biotechnological applications.
title Exploring salinity induced adaptations in marine diatoms using advanced photonic techniques.
topic Diatoms
Salinity
Adaptation, Physiological
Microscopy, Fluorescence
Photoacoustic Techniques
Chlorophyll
url https://pubmed.ncbi.nlm.nih.gov/39738413/