Project description:The Nanopig™ model is an emerging non-rodent platform for (bio)pharmaceutical safety assessment, with potential advantages for translational research. Here, we report initial characterization results using whole genome sequencing (WGS) and tissue-based proteomics, focusing on drug metabolism and immune system relevance. WGS produced a high-quality Nanopig™ genome assembly (2.8–2.9 Gb), with >98 % alignment to the Duroc pig reference genome, and identified key metabolic and immune-related genes, including 47 cytochrome P450 (CYP450) genes with high homology to human CYP450 families. Proteomic profiling of 15 pharmaceutically relevant tissues revealed human orthologous drug metabolism enzymes and transporters (DMETs), as well as immune-related proteins, indicating similarities to human CYP450 enzyme abundance and tissue distribution. Functional evaluation of hepatic CYP450 activity yielded kinetic parameters (Km, Vmax) in the range observed in humans and beagle dogs. These early findings represent a foundational multi-omics dataset for the Nanopig™, suggesting its future use as a translational model in preclinical safety assessment. This work provides an early framework for species selection strategies and model optimization, with the long-term goal of reducing reliance on traditional non-rodent species in drug development.

Project description:he Nanopig™ model is an emerging non-rodent platform for (bio)pharmaceutical safety assessment, with potential advantages for translational research. Here, we report initial characterization results using whole genome sequencing (WGS) and tissue-based proteomics, focusing on drug metabolism and immune system relevance. WGS produced a high-quality Nanopig™ genome assembly (2.8–2.9 Gb), with >98 % alignment to the Duroc pig reference genome, and identified key metabolic and immune-related genes, including 47 cytochrome P450 (CYP450) genes with high homology to human CYP450 families. Proteomic profiling of 15 pharmaceutically relevant tissues revealed human orthologous drug metabolism enzymes and transporters (DMETs), as well as immune-related proteins, indicating similarities to human CYP450 enzyme abundance and tissue distribution. Functional evaluation of hepatic CYP450 activity yielded kinetic parameters (Km, Vmax) in the range observed in humans and beagle dogs. These early findings represent a foundational multi-omics dataset for the Nanopig™, suggesting its future use as a translational model in preclinical safety assessment. This work provides an early framework for species selection strategies and model optimization, with the long-term goal of reducing reliance on traditional non-rodent species in drug development.

Project description:In vitro prediction of developmental toxicity during early discovery phases of drug development has the potential to guide decision-making toward prioritizing candidate drugs that are less likely to later show teratogenicity in vivo. Such screening would reduce animal use in preclinical studies, including full-scale regulatory reproductive toxicology. we evaluate an assay format based on short-term toxicogenomic responses in pluripotent embryonic stem cells (ESC). We exposed attached undifferentiated cells of the mouse ESC cell line R1 for 6h to 10 known teratogenic and 9 non-teratogenic pharmaceutical drugs . We used microarry to access genome-wide gene expression response and identify gene signatures to classify teratogens and non-teratogens.

Project description:Like many per- or polyfluorinated alkyl substances (PFAS), toxicity studies with HFPO-DA (ammonium, 2,3,3,3-tetrafluoro-2-(heptafluoropropoxy)-propanoate; CASRN 62037-80-3), a short-chain PFAS used in the manufacture of some types of fluorinated polymers, indicate that the liver is the primary target of toxicity in rodents following oral exposure. Although the current weight of evidence supports the PPARa mode of action (MOA) for liver effects in HFPO-DA-exposed mice, alternate MOAs have also been hypothesized including PPARg or cytotoxicity. To further evaluate the MOA for HFPO-DA in rodent liver, transcriptomic analyses were conducted on samples from primary mouse, rat and pooled human hepatocytes treated for 12, 24 or 72 hours with various concentrations of HFPO-DA, or established agonists of PPARa (GW7647), PPARg (rosiglitazone), or cytotoxic agents (i.e., acetaminophen or d-galactosamine). Concordance analyses of enriched pathways across chemicals within each species demonstrated greatest concordance between HFPO-DA and PPARa agonist GW7647-treated hepatocytes compared to the other chemicals evaluated. These findings were supported by benchmark concentration modeling and predicted upstream regulator results. In addition, transcriptomic analyses across species demonstrated a greater transcriptomic response in rodent hepatocytes treated with HFPO-DA or agonists of PPARa or PPARg, indicating rodent hepatocytes are more sensitive to HFPO-DA or PPARa/g agonist treatment. These results are consistent with previously published transcriptomic analyses and further support that liver effects in HFPO-DA-exposed rodents are mediated through rodent-specific PPARa signaling mechanisms as part of the MOA for PPARa activator-induced rodent hepatocarcinogenesis.

Project description:It has been reported that Cryptosporidium parvum, a species of a protozoan frequently isolated from humans and animals, is able to induce digestive adenocarcinoma in a rodent model. Consistently, some epidemiological studies have reported an association with cryptosporidiosis in patients with colorectal adenocarcinoma. However, the correlation between cryptosporidiosis and human digestive cancer remains unclear at this time, and it is not known whether this intracellular parasite, considered an opportunistic agent, is able to induce gastrointestinal malignancies in humans. In order to add new arguments for a probable association between cryptosporidiosis and digestive human cancer, the main aim of this study is to determine prevalence and to identify species of Cryptosporidium among a French digestive cancer population.

Project description:Drug-induced liver injury (DILI) is a leading cause of acute liver failure and the major reason for withdrawal of drugs from the market. Preclinical evaluation of drug candidates has failed to detect about 40% of potentially hepatotoxic compounds in humans. At the onset of liver injury in humans, currently used biomarkers have difficulty differentiating severe DILI from mild, and/or predict the outcome of injury for individual subjects. Therefore, new biomarker approaches for predicting and diagnosing DILI in humans are urgently needed. Recently, circulating microRNAs (miRNAs) such as miR-122 and miR-192 have emerged as promising biomarkers of liver injury in preclinical species and in DILI patients. In this study, we focused on examining global circulating miRNA profiles in serum samples from subjects with liver injury caused by accidental acetaminophen (APAP) overdose. Upon applying next generation high-throughput sequencing of small RNA libraries, we identified 36 miRNAs, including 3 novel miRNA-like small nuclear RNAs, which were enriched in the serum of APAP overdosed subjects. The set comprised miRNAs that are functionally associated with liver-specific biological processes and relevant to APAP toxic mechanisms. Although more patients need to be investigated, our study suggests that profiles of circulating miRNAs in human serum might provide additional biomarker candidates and possibly mechanistic information relevant to liver injury.

Project description:Drug-induced liver injury (DILI) remains a major challenge in drug development and inter-species differences in potential liver toxicity are one area where comparative analyses may inform pre-clinical safety study design. In vitro testing for species-specific liver effects, especially in complex models such as microphysiological systems (MPS) may help predict toxicity before advancing from animal to human studies or de-risk spurious findings in pre-clinical species. This study assessed the utility of the perfusion-based PhysioMimix® LC12 MPS for evaluating species-specific DILI using primary hepatocytes from human, monkey, rat, and dog. First, functional, phenotypic, and transcriptional profiles were established over 2 weeks in cell culture. Then, cells were exposed to species-specific DILI compounds – chlorpromazine (CPZ), bosentan (BOS), and fialuridine (FIAU) – in both PhysioMimix® LC12 and traditional 2D cultures. Hepatocytes in PhysioMimix® LC12 showed more stable albumin and urea production for up to 14 days as compared to 2D cultures. Concentration-response studies with CPZ, BOS, or FIAU were performed in 2D; then, prolonged exposures (10 days) to sub-100× Cmax concentrations were tested in PhysioMimix® LC12. Species-specific differences in cellular and molecular effects of the drugs were observed in both models; data from PhysioMimix® LC12 were more reflective of the expected effects in whole animals or humans. Still, variability and low throughput are limitations of the MPS for prospective studies of species-specific responses. Overall, this study confirms the utility of liver safety studies using MPS, but also provides suggestions for experimental designs to overcome the limitations of more complex test systems.

Project description:Modern 21st century toxicity testing makes use of omics technologies to address critical questions in toxicology and chemical management. Of interest are questions relating to chemical mechanisms of toxicity, differences in species sensitivity, and translation of molecular effects to observable apical endpoints. Our study addressed these questions by comparing apical outcomes and multiple omics responses in early-life stage exposure studies with Japanese quail (JQ; Coturnix japonica) and double crested cormorant (DCCO; Phalacrocorax auritus), representing a model and ecological species, respectively. Specifically, we investigated the dose-dependent response of apical outcomes, transcriptomics, and metabolomics in the liver in each species exposed to chlorpyrifos (CPF), a widely used organophosphate pesticide. Our results revealed a clear pattern of dose-dependent disruption of gene expression and metabolic profiles in JQ but not DCCO at similar CPF exposure concentrations. The difference in effect sensitivity between species was likely due to higher metabolic transformation of CPF in the precocial JQ compared to the more altricial DCCO. The most impacted biological pathways after CPF exposure in JQ included hepatic metabolism, oxidative stress, endocrine disruption (steroid and non-steroid hormones), and metabolic disease (lipid and fatty acid metabolism). Importantly, we show consistent responses across biological scales, suggesting that significant disruption at the level of gene expression and metabolite profiles leads to observable apical responses at the organism level. Our study demonstrates the utility of evaluating effects at multiple biological levels of organization to understand how modern toxicity testing relates to outomes of regulatory relevance, while also highlighting important, yet poorly understood, species differences in sensitivity to chemical exposure.

Project description:New approach methodologies (NAMs) are advancing the reduction of animal testing by promoting human-relevant safety assessments across diverse applications, including cosmetics, pharmaceuticals, and environmental chemicals. Among these methodologies, computational models like quantitative systems toxicology (QST) have emerged as powerful tools, enabling the simulation of mechanisms underlying drug (or chemical) induced toxicity to predict potential adverse outcomes. Valproic acid (VPA), a treatment for epilepsy, convulsions and bipolar disorder, is associated with a risk of drug-induced liver injury. The mechanism of hepatotoxicity is not fully understood, although VPA’s competitive inhibition of fatty acid metabolism via carnitine palmitoyl transferase 1 (CPT1) in the liver is a leading hypothesis. In this study, we employed a QST approach by integrating a human physiologically-based pharmacokinetic model of VPA with the large-scale liver metabolism model HEPATOKIN1 to evaluate whether simulated VPA dosing with increasing CPT1 inhibition predicted relevant clinical markers for hepatotoxicity. The integrated model predicted a dose-dependent increase in hepatic triaclyglyceride as a result of the competitive inhibition of CPT1 by VPA, consistent with clinical observations. Notably, explicitly including PPARα-mediated regulatory effects on key liver enzymes was essential to ensure biologically consistent outcomes in liver metabolism. These results highlight the necessity of including relevant regulatory pathways in QST applications to achieve credible and physiologically relevant safety predictions.

Project description:Assessing concordance of drug-induced transcriptional response in rodent liver and cultured hepatocytes