Altered Transcriptome Response in PBMCs of Czech Adults Linked to Multiple PFAS Exposure: B Cell Development as a Target of PFAS Immunotoxicity

A critical review of sensors for detecting per- and polyfluoroalkyl substances: Focusing on diverse molecular probes

Per and Polyfluoroalkyl Substances (PFASs) pose a severe threat to the ecological environment and human health due to their persistence, bioaccumulation, and potential toxicity in the environment. Currently, the detection methods of PFASs generally rely on the combination of chromatographic techniques and mass spectrometry, which are typically suitable for laboratory testing. To meet the requirements of on-site detection, there is an urgent need to develop convenient and efficient detection methods. Sensors, as the preferred alternative, have been widely studied. In order to deeply investigate the mechanism of sensors in recognizing PFASs, this review, from the unique perspective of molecular probes, summarizes the construction and recognition mechanisms of four molecular probes: antibodies, aptamers, synthesized micromolecules, and synthesized polymers for PFASs. This review focuses on PFOA and PFOS as representative perfluoroalkyl substances and systematically investigates their properties and effects. It also analyzes the respective advantages, disadvantages, and applicable scenarios, and discusses the future development trends.

Distinct binding affinity of perfluoroalkyl acids to plant and animal proteins revealed by dialysis experiments, fluorescence spectroscopy, and QSAR modeling

Understanding the binding dynamics between perfluoroalkyl acids (PFAAs) and proteins is crucial for risk assessment, as protein binding plays a vital role in the bioaccumulation of PFAAs. This study employed dialysis experiments to measure the protein-water partition coefficient of PFAAs with representative plant and animal proteins, including standard bovine serum albumin, soy protein isolate, and C-phycocyanin. Fluorescence spectroscopy was investigated to elucidate the binding affinity of PFAAs on bovine serum albumin (BSA). Additionally, through the construction of the quantitative structure-activity relationship (QSAR) model, this research comprehensively analyzed the binding characteristics of various PFAAs to proteins, offering insights into the molecular mechanisms of PFAAs-protein interactions. The results revealed that the binding capacity of bovine serum albumin for PFAAs was significantly superior to that of C-phycocyanin and soy protein isolate. Electrostatic attraction was the predominant factor influencing the interaction between proteins and PFAAs. The binding of PFAAs to proteins was chiefly mediated by tryptophan residues, and there was no notable change in the protein conformation pre- and post-binding. Finally, the QSAR models, constructed with energy gap (Egap) between the highest occupied and the lowest unoccupied molecular orbitals, the net charge of the most negative atom (q), and ionic volume as descriptors, suggested that the hydrophobic interactions, electrostatic interactions, and the stability of PFAA molecule are key factors affecting PFAA-protein binding. This study enhances our comprehension of the binding capacity of animal and plant proteins to PFAAs, while also establishing a foundation for future research on the binding of emerging PFAA alternatives to proteins.

A comparative review of the toxicity mechanisms of perfluorohexanoic acid (PFHxA) and perfluorohexanesulphonic acid (PFHxS) in fish

Industrial and consumer goods contain diverse perfluoroalkyl substances (PFAS). These substances, like perfluorohexanoic acid (PFHxA) and perfluorohexanesulphonic acid (PFHxS), are under increased scrutiny due to their potential toxicity to aquatic organisms. However, our understanding of their biological impacts and mechanisms of action remains limited. The objectives of this review were to compare data for levels of PFHxA and PFHxS in aquatic environments and fish tissues, as well as toxicity mechanisms related to morphological, endocrine, metabolic, and behavioral endpoints. A computational assessment was also performed to identify putative mechanisms of toxicity and to characterize exposure biomarkers. Studies have shown that both PFHxA and PFHxS residues are present in diverse marine and freshwater fish tissues, suggesting the importance of monitoring these PFAS in aquatic organisms. In fish tissues, these chemicals have been reported to be as high as 37.5 ng/g for PFHxA and 1290 ng/g for PFHxS, but their persistence in aquatic environments and degradation in tissues requires further study. In terms of mechanisms of toxicity, both oxidative stress and endocrine disruption have been reported. Based on evidence for endocrine disruption, we modeled interactions of estrogen and androgen receptors of several fish species with PFHxA and PFHxS. Molecular docking revealed that PFHxS has a stronger affinity for interacting with the estrogen and androgen receptors of fish compared to PFHxA and that estrogen and androgen receptors of fathead minnow, zebrafish, Atlantic salmon, and largemouth bass show comparable binding affinities for each chemical except for salmon Esr2b, which was predicted to have lower affinity for PFHxA relative to Esr2a. While mechanistic data are lacking in fish in general for these chemicals, a computational approach revealed that PFHxA can perturb the endocrine system, nervous system, and is linked to changes in kidney and liver weight. Proteins associated with PFHxA and PFHxS exposures in fish include those related to lipid and glucose regulation, reproductive proteins like KISS metastasis suppressor, and proteins associated with the immune system (specifically RAG1, RAG2), all of which are potential biomarkers of exposure. Taken together, we synthesize current knowledge regarding the environmental fate and ecotoxicology of PFHxA/PFHxS in fish species.

Exposure to per- and polyfluoroalkyl substances and high-throughput proteomics in Hispanic youth

BACKGROUND

Strong epidemiological evidence shows positive associations between exposure to per- and polyfluoroalkyl substances (PFAS) and adverse cardiometabolic outcomes (e.g., diabetes, hypertension, and dyslipidemia). However, the underlying cardiometabolic-relevant biological activities of PFAS in humans remain largely unclear.

AIM

We evaluated the associations of PFAS exposure with high-throughput proteomics in Hispanic youth.

MATERIAL AND METHODS

We included 312 overweight/obese adolescents from the Study of Latino Adolescents at Risk (SOLAR) between 2001 and 2012, along with 137 young adults from the Metabolic and Asthma Incidence Research (Meta-AIR) between 2014 and 2018. Plasma PFAS (i.e., PFOS, PFOA, PFHxS, PFHpS, PFNA) were quantified using liquid-chromatography high-resolution mass spectrometry. Plasma proteins (n = 334) were measured utilizing the proximity extension assay using an Olink Explore Cardiometabolic Panel I. We conducted linear regression with covariate adjustment to identify PFAS-associated proteins. Ingenuity Pathway Analysis, protein-protein interaction network analysis, and protein annotation were used to investigate alterations in biological functions and protein clusters.

RESULTS

Results after adjusting for multiple comparisons showed 13 significant PFAS-associated proteins in SOLAR and six in Meta-AIR, sharing similar functions in inflammation, immunity, and oxidative stress. In SOLAR, PFNA demonstrated significant positive associations with the largest number of proteins, including ACP5, CLEC1A, HMOX1, LRP11, MCAM, SPARCL1, and SSC5D. After considering the mixture effect of PFAS, only SSC5D remained significant. In Meta-AIR, PFAS mixtures showed positive associations with GDF15 and IL6. Exploratory analysis showed similar findings. Specifically, pathway analysis in SOLAR showed PFOA- and PFNA-associated activation of immune-related pathways, and PFNA-associated activation of inflammatory response. In Meta-AIR, PFHxS-associated activation of dendric cell maturation was found. Moreover, PFAS was associated with common protein clusters of immunoregulatory interactions and JAK-STAT signaling in both cohorts.

CONCLUSION

PFAS was associated with broad alterations of the proteomic profiles linked to pro-inflammation and immunoregulation. The biological functions of these proteins provide insight into potential molecular mechanisms of PFAS toxicity.