Multigenerational exposure of cadmium trans-generationally impairs locomotive and chemotactic behaviors in Caenorhabditis elegans

Cadmium disrupted homeostasis of proximal renal tubular cells via targeting ATF4-CHOP complex into the nucleus

Cadmium, a ubiquitous toxic metal and environmental pollutant, is associated with several renal metabolic disorders and disrupts the homeostasis of kidneys in humans and animals. However, the precise molecular mechanism remains poorly elucidated. The present study investigated the role of the ATF4-CHOP nuclear transcriptional axis and its interactions with cellular pathways in cadmium-induced nephrotoxicity. We acquired 120 one-day-old chickens, randomly divided them into four groups (Con, Cd35, Cd70, Cd140), and were treated with graded cadmium doses for 90 days. The kidney tissues were collected for comprehensive histopathological, biochemical, and molecular analyses using western blotting, qRT-PCR, immunofluorescence, and tunel assay. Subsequently, we revealed that cadmium exposure induced ER stress, significantly upregulated CHOP expression, and activated pro-apoptotic ATF4-CHOP axis. Our findings revealed a complex interplay, where ER stress activated inflammation. Concurrently, mitochondrial disruption elevated ROS production and oxidative stress, which impaired renal homeostasis. Moreover, inhibition of autophagy and mitophagy led to the accumulation of damaged cell organelles, further exacerbating apoptotic signaling. Our results elucidate that an integrated network of cellular stress pathways mediates cadmium-induced renal toxicity, with the ATF4-CHOP axis acting as a crucial pro-apoptotic pathway. This study provides critical insights into the mechanisms of cadmium-induced nephrotoxicity and potential therapeutic interventions to mitigate heavy metal-induced renal homeostasis disruption and renal damage.

Multi-omics Reveals The Hepatic Metabolic Mechanism of Neurological Symptoms Caused by Selenium Exposure in Przewalski's Gazelle (Procapra przewalskii)

Neurological symptoms resulting from selenium(Se) exposure significantly impact the health and conservation of Przewalski's gazelle. In this study, we performed proteomic and metabolomic analyses of the liver in Przewalski's gazelle for the first time, aiming to reveal the hepatic metabolic mechanisms underlying the neurological symptoms caused by Se exposure. We identified 89 differentially expressed proteins and 30 metabolites with altered regulation. Using multi-omics integrated analysis, we identified a neurofunctional regulation network composed of three metabolic pathways, with (S)-3-amino-2-methylpropionate transaminase being the key enzyme in the regulatory network. Molecular docking revealed that the binding of selenocysteine to (S)-3-amino-2-methylpropionate transaminase may act as a key factor in activating this regulatory network. Consequently, these findings provide important insights into the molecular mechanisms of neurological symptoms caused by Se exposure and have significant implications for the conservation in Przewalski's gazelle.

Toxicity of isolated and mixed metals to a native Amazonian ostracod and ecological risk assessment

In recent decades the Amazonian ecosystem has received large amounts of domestic and industrial effluents, as well as mining-related waste contributing significant quantities of metal to water bodies. Thus, the main objective of the study was to verify the sensitivity of a native Amazonian ostracod (Strandesia rondoniensis) species to isolated and mixed metal salts (CuSO4; ZnCl2; CdCl2 and HgCl2). The sensitivity will be compared to other species using species sensitivity distributions (SSDs) for an ecological risk assessment (ERA). The experiment consisted of simultaneously exposing each metal alone and in mixture, through a factorial design for toxicity with 25 different combinations for 48 h. For the ERA, metal concentrations measured in the water of various aquatic environments in the Amazon basin were considered based on the risk quotient values. The results showed that the metal toxicity gradient was Cd>Hg>Cu>Zn, respectively. The toxicity in the mixture showed that the combination of Cu-Cd and Cu-Zn better fit the model (CA), indicating mainly synergism when copper predominated in the mixture. Meanwhile, the Cu-Hg interaction fit the model better (IA), again indicating synergism when copper was at a higher concentration. The ERA showed a high risk (RQ > 1) for the Cd, Cu, and Hg metals.

Plants buffer some of the effects of a pair of cadmium-exposed zebrafish on the un-exposed majority

Certain individuals have a disproportionate effect on group responses. Characteristics may include susceptibility to pollutants, such as cadmium (Cd), a potent trace metal. Here, we show how a pair of Cd-exposed individuals can impact the behavior of unexposed groups. We used behavioral assessments to characterize the extent of the effects of the Cd-exposed individuals on group boldness, cohesion, foraging, activity, and responses to plants. We found that groups with a pair of Cd-exposed fish remained closer to novel stimuli and plants than did groups with untreated (control) fish. The presence of plants reduced Cd-induced differences in shoal cohesion and delays feeding in male shoals. Shoals with Cd- and water-treated fish were equally active. The results suggest that fish acutely exposed to environmentally relevant Cd concentrations can have profound effects on the un-exposed majority. However, the presence of plants may mitigate the effects of contaminants on some aspects of social behavior.

Effect of Cd(II) shock loading on performance, microbial enzymatic activity and microbial community in a sequencing batch reactor

The performance, microbial enzymatic activity and microbial community of a sequencing batch reactor (SBR) were explored under instantaneous Cd(II) shock loading. After a 24-h Cd(II) shock loading of 100 mg/L, the chemical oxygen demand and NH₄⁺-N removal efficiencies decreased significantly from 92.73% and 99.56% on day 22 to 32.73% and 43% on day 24, respectively, and then recovered to the normal values gradually. The specific oxygen utilization rate (SOUR), specific ammonia oxidation rate (SAOR), specific nitrite oxidation rate (SNOR), specific nitrite reduction rate (SNIRR) and specific nitrate reduction rate (SNRR) decreased by 64.81%, 73.28%, 77.77%, 56.84% and 52.46% on day 23 in comparison with the absence of Cd(II) shock loading, respectively, and they gradually returned to the normal levels. The changing trends of their associated microbial enzymatic activities including dehydrogenase, ammonia monooxygenase, nitrite oxidoreductase, nitrite reductase and nitrate reductase were in accordance with SOUR, SAOR, SNOR, SNIRR and SNRR, respectively. Cd(II) shock loading promoted the microbial reactive oxygen species production and lactate dehydrogenase release, indicating that instantaneous shock caused oxidative stress and damaged to cell membranes of the activated sludge. The microbial richness and diversity, and the relative abundance of Nitrosomonas and Thauera obviously decreased under the stress of Cd(II) shock loading. PICRUSt prediction showed that Cd (II) shock loading significantly affected Amino acid biosynthesis, Nucleoside and nucleotide biosynthesis. The present results are conducive to take adequate precautions to reduce the adverse effect on bioreactor performance in wastewater treatment systems.