Investigation of ratio of carbon to hydrogen (C/H ratio) in agricultural plants for further estimation of their productivity of organically bound tritium

Factors regulating the accumulation efficiency of organically bound tritium in plants across species, parts, and environmental conditions: Investigation using the C/H ratio in plant organic matter

Tritium (3H), the only radioisotope of hydrogen, is a major radionuclide released anthropogenically from nuclear facilities into the environment. It is subsequently and partially accumulated in the organically bound tritium (OBT) of plants during primary production. In this study, variations in OBT accumulation efficiency of plants across species, parts, and seasons were investigated through seasonal measurements of the ratio of carbon to hydrogen (C/H ratio) in the organic matter (OM) of plants. A high C/H ratio indicates a low OBT accumulation efficiency in the OM, because a high ratio implies a low hydrogen content, which is the base element of 3H, in the plant OM. Four plant species (Japanese black pine saplings, rice, Japanese mustard spinach, and orchardgrass), which are typical Japanese trees and herbs, were selected. The C/H ratio observed in this study ranged from 5.6 to 7.7 as weight ratio. The C/H ratio in Japanese black pine was higher than that in the other species for all plant parts, suggesting that the OBT accumulation efficiency of woody plants was lower than that of other plant species. In terms of plant parts, the C/H ratio in the roots was generally higher for all plant species. This suggests that OBT accumulation efficiency in the roots is lower than that in other plant parts. Seasonal C/H ratios were fairly constant regardless of the plant species and part, indicating that the OBT accumulation efficiency in plants scarcely varied seasonally. The influence of light intensity during cultivation did not significantly change the C/H ratios in Japanese black pine, rice, and orchardgrass.

Effects of tritium pollution on photosynthesis, respiration and redox of microalgae under rising temperature

Due to rising sea surface temperatures and thermal emissions from nuclear power plants, temperature has been recognized as a significant factor in evaluating the potential biological effect of tritium. In this work, tritium pollution in a freshwater system was simulated, and the dynamic changes of microalgal growth in semi-natural state were monitored in real time. The effects of tritium exposure on photosynthesis and respiration of Chlamydomonas reinhardtii (C. reinhardtii) were further analyzed in the context of rising temperatures. It was found that under tritium exposure (3.7 × 106 Bq/L, 12.17 μGy/h, resulting in a dose for 96 h of exposure is about 1 mGy), elevated temperature promoted the accumulation of organically bound tritium (OBT) and reactive oxygen species (ROS), which damaged the cell structure, reduced the photosynthetic performance and photosynthetic energy transfer efficiency, and interfered with the energy levels and redox states in C. reinhardtii. At the transcriptional level, elevated temperature exacerbated the inhibition of tritium exposure on key metabolic pathways related to photosynthetic system and respiratory metabolism of C. reinhardtii, while simultaneously causing double-stranded DNA damage in algal cells. Under the low-dose of tritium exposure with elevated temperature, the accumulation of ROS may lead to the disruption of algae's defense mechanisms, subsequently reducing their ability to resist genetic damage. This study provides insights for reassessing the potential risks to aquatic ecosystem considering the discharge of low-level tritium-containing wastewater in the context of global warming.

Analysis of environmental biological effects and OBT accumulation potential of microalgae in freshwater systems exposed to tritium pollution

The ecological risk of tritiated wastewater into the environment has attracted much attention. Assessing the ecological risk of tritium-containing pollution is crucial by studying low-activity tritium exposure's environmental and biological effects on freshwater micro-environment and the enrichment potential of organically bound tritium (OBT) in microalgae and aquatic plants. The impact of tritium-contaminated wastewater on the microenvironment of freshwater systems was analyzed using microcosm experiments to simulate tritium pollution in freshwater systems. Low activity tritium pollution (105 Bq/L) induced differences in microbial abundance, with Proteobacteria, Bacteroidota, and Desulfobacterota occupying important ecological niches in the water system. Low activity tritium (105-107 Bq/L) did not affect the growth of microalgae and aquatic plants, but OBT was significantly enriched in microalgae and two aquatic plants (Pistia stratiotes, Spirodela polyrrhiza), with the enrichment coefficients of 2.08-3.39 and 1.71-2.13, respectively. At the transcriptional level, low-activity tritium (105 Bq/L) has the risk of interfering with gene expression in aquatic plants. Four dominant cyanobacterial strains (Leptolyngbya sp., Synechococcus elongatus, Nostoc sp., and Anabaena sp.) were isolated and demonstrated good environmental adaptability to tritium pollution. Environmental factors can modify the tritium accumulation potential in cyanobacteria and microalgae, theoretically enhancing food chain transfer.

Evaluating production rates of particulate organic hydrogen by marine phytoplankton for estimating phytoplanktonic productivity of organically bound tritium

To estimate the production potential of organically bound tritium (OBT) by phytoplankton from tritiated water in coastal areas adjacent to the Fukushima Daiichi Nuclear Power Plant (FDNPP), phytoplanktonic production rates of particulate organic hydrogen (POH) were evaluated in laboratory and field experiments using stable isotope tracers (2H and 13C). In the laboratory experiment, the production rate of POH was evaluated for five types of phytoplankton cultivated cultures (two diatoms, Haptophyceae, Chlorophyceae, and Cryptophyceae) at two temperatures (15 °C and 25 °C) and two 2H concentrations in the medium (1 and 5%). Additionally, the production rate of POH was especially focused on non-exchangeable POH (NE-POH) which is the chemical form of hydrogen connected tightly to organic matter. The production rates of NE-POH in the laboratory experiment varied (0.10 to 36 μmol L-1 d-1 μg-Chl a-1) with the productivity of particulate organic carbon, phytoplankton species, and temperature, with negligible influence of 2H concentrations. In the field experiment, in situ incubation of coastal seawater at water depths of 1 and 20 m with isotope tracers under light and dark conditions, respectively, was performed thrice (November 2021, May 2022, and October 2022) on the Pacific coastal ocean approximately 2 km from the land of northeast Japan. We observed variation in the production rate of POH (0.21 to 3.1 μmol L-1 d-1 μg-Chl a-1), which was theoretically explained by the data in the laboratory experiment. Using the phytoplanktonic production rate of POH obtained in this study, OBT production by phytoplankton and the subsequent accumulation potential of OBT in sediments in the coastal area adjacent to FDNPP were tentatively estimated, results of which suggested this potential to be small.

Tritium and Carbon-14 Contamination Reshaping the Microbial Community Structure, Metabolic Network, and Element Cycle in the Seawater Environment

The potential ecological risks caused by entering radioactive wastewater containing tritium and carbon-14 into the sea require careful evaluation. This study simulated seawater's tritium and carbon-14 pollution and analyzed the effects on the seawater and sediment microenvironments. Tritium and carbon-14 pollution primarily altered nitrogen and phosphorus metabolism in the seawater environment. Analysis by 16S rRNA sequencing showed changes in the relative abundance of microorganisms involved in carbon, nitrogen, and phosphorus metabolism and organic matter degradation in response to tritium and carbon-14 exposure. Metabonomics and metagenomic analysis showed that tritium and carbon-14 exposure interfered with gene expression involving nucleotide and amino acid metabolites, in agreement with the results seen for microbial community structure. Tritium and carbon-14 exposure also modulated the abundance of functional genes involved in carbohydrate, phosphorus, sulfur, and nitrogen metabolic pathways in sediments. Tritium and carbon-14 pollution in seawater adversely affected microbial diversity, metabolic processes, and the abundance of nutrient-cycling genes. These results provide valuable information for further evaluating the risks of tritium and carbon-14 in marine environments.