Project description:Multi-walled carbon nanotubes (MWCNTs) are among the most promising nanomaterials because of their physical and chemical properties. However, since they are biopersistent fiber-like materials which share similarities with asbestos, concerns have arisen about their health effects. With their various industrial usages, occupational exposure to MWCNTs may occur mainly by inhalation as these nanomaterials can get aerosolised. The number of toxicological studies on CNTs has steadily increased for the last decades. Different works showed that MWCNT exposure by inhalation or intratracheal instillation could lead to pulmonary toxicity, such as lung inflammation, genotoxicity, fibrosis or lung cancer (Kasai et al. 2015, Kasai et al. 2016, Porter et al. 2013, Suzui et al. 2016). To date, only one MWCNT (MWNT-7) has been classified as possibly carcinogen to human (Group 2B) while the others have not been as classifiable as to their carcinogenicity to humans (Group 3) because of the lack of data on their carcinogenic potential (IARC 2017). Because of the wide variety of CNTs with various length, diameter or functionalisation, additional effort is required to assess their pulmonary toxicity. As a complementary approach to conventional toxicological assays, the omics methods are useful technologies for the mechanistic understanding of the toxicological effects observed following exposure to chemicals and particulate matters. Importantly, they can also be used as predictive tools for identifying the mode of action of other particles with similar physical and chemical characteristics. These molecular approaches may also be used for the discovery of exposure markers or early markers of adverse effects, before the appearance of clinical signs of a disease (Rahman et al. 2017). Several studies assessed gene expression alteration following in vivo exposure to CNTs (Poulsen et al. 2015, Snyder-Talkington et al. 2013, Ellinger-Ziegelbauer and Pauluhn 2009). These omics approaches were used to identify genes and pathways modulated in response to exposure. However, there are still too few studies to assess the link between MWCNT physico-chemical properties, global gene or protein expression profiles, and long-term effects. In a previous study, we showed that inhalation of two pristine MWCNTs, the long and thick NM-401, and the short and thin NM-403, induced alveolar neutrophilic granulocyte influx, a hallmark of inflammation, which was proportional to the lung CNT BET surface deposited dose (Gate et al. 2019). However, due to their different physical and chemical properties, one could assume that these two CNTs may have diverse toxicological profiles, but the conventional toxicology approaches used in this early work were probably not sensitive enough to identify such differences. In order to gain additional insight about their toxicological properties, in the current study, we compare the alteration induced by the two MWCNTs on the transcriptome in the lung tissue and the proteome in the broncho-alveolar lavage fluid (BALF) after rat exposure by inhalation. The omics analyses were performed from 3 days up to 180 days.

Project description:The main constituents of electronic cigarette liquids are nicotine, propylene glycol (PG), and vegetable glycerin (VG), together with distilled water and flavors. To assess the toxicity of PG/VG mixtures with and without nicotine as basic components of liquids used in e-cigarettes, a 90-day rat inhalation study according to the Organization for Economic Co-operation and Development test guideline 413 was conducted. Sprague-Dawley (SD) rats were nose-only exposed, 6 h/day, 5 days/week to filtered air, or nebulized vehicle (saline), or three concentrations of PG/VG (0.174 mg PG/l + 0.210 mg VG/l; 0.520 mg PG/l + 0.630 mg VG/l; 1.520 mg PG/l + 1.890 mg VG/l) – with (test item) and without (reference item) 23 µg nicotine/L. Standard toxicological endpoints were complemented by molecular analyses using transcriptomics, proteomics, and lipidomics. Compared to vehicle exposure, the tested PG/VG aerosols showed only very limited biological effects with no signs of toxicity, both for the standard toxicological endpoints (e.g., histopathology, clinical chemistry) and the systems toxicological analyses (transcriptomics, proteomics, and lipidomics). The addition of nicotine to the PG/VG aerosols (23 µg/l) resulted in effects in line with nicotine effects in previous studies. These included up-regulation of xenobiotic enzymes (Cyp1a1 and Fmo3) in the lung and metabolic effects, e.g., reduction in serum lipid concentrations and changes in the expression of metabolic enzymes in the liver. Signs of a generalized stress response to nicotine exposure such as decreased thymus weights were observed; and likely, a subset of the observed metabolic alterations was interlinked with this generalized stress response. Under the conditions of this 90-day SD rat inhalation study, no toxicologically relevant effects of PG/VG aerosols (up to 1.520 mg PG/l + 1.890 mg VG/l) were observed, and the no observed adverse effect level (NOAEL) for PG/VG/nicotine was determined to be 438/544/6.7 mg/kg/day. Further the study demonstrated how complementary systems toxicology analyses can reveal, also in the absence of observable adverse effects, subtoxic and adaptive responses to pharmacologically active compounds such as nicotine.

Project description:The objective of this study was to compare the biological and toxicological response of apolipoprotein E-deficient (Apoe-/-) mice to 3R4F mainstream smoke exposure for 2 months in whole-body exposure chambers (WBEC) and nose-only exposure chambers (NOEC). Female ApoE-/- mice were randomized into four groups: two Sham groups, exposed to filtered air, and two 3R4F groups, exposed to CS from the 3R4F reference cigarette (550 µg TPM/L). Half the number of mice in the Sham- and CS-exposed groups were exposed in WBECs and the other half in NOECs. The exposure phase lasted 9 weeks and included 1 week of adaption, during which exposure in both chamber types was escalated in dose and duration to a maximum of 4 h per day. The TPM concentration and exposure duration in WBECs were matched to those in NOECs on the basis of the regimen that the mice tolerated, as determined by in-life findings on acute signs of nicotine toxicity. Fresh air breaks were introduced during the exposure period to maintain carboxyhemoglobin (COHb) concentrations at acceptable levels. More frequent and longer fresh air breaks were required for exposure in the WBEC than in the NOEC because of the greater internal volume—and, consequently, the longer duration—required to clear smoke from the WBEC than from the NOEC. For animals in NOECs, a 30-min fresh air break was introduced after 2 and 3 h of exposure. For animals in WBECs, a 30-min fresh air break was introduced after 1 and 2 h of exposure and a 60-min fresh air break after the third hour of exposure. The general condition and health of the mice following exposure were monitored throughout the study. Full necropsy was performed 16-20 h after the last exposure without prior fasting, in accordance with previously described methods (Vanscheeuwijck et al., 2002). Differences between WBEC and NOEC expsoure were analyzed with regard to aerosol uptake, disease endpoints (adaptive changes in nasal epithelia, changes in lung function and inflammatory parameters, plasma cholesterol/triglyceride levels in lipoprotein fractions, and atherosclerosis plaque development), and systems biology endpoints (changes in the lung proteome and liver, nasal epithelial, and heart transcriptomes). All procedures involving animals were performed in a facility accredited by the Association for Assessment and Accreditation of Laboratory Animal Care International and licensed by the Agri-Food & Veterinary Authority of Singapore, with approval from an Institutional Animal Care and Use Committee and in compliance with the National Advisory Committee for Laboratory Animal Research Guidelines on the Care and Use of Animals for Scientific Purposes (NACLAR, 2004). Here, the protein expression data for lung tissue assessed by iTRAQ®-based quantitative proteomics will be described.

Project description:Toll like receptor 4 (TLR4), an innate immunity gene, is involved in responses to several pulmonary agonists including endotoxin (LPS; Poltorak et al.,1998), ozone (O3 ,Kleeberger et. al., 2001), Pseudomonas aeruginosa (Faure et al, 2004), and hyperoxia (Zhang et al, 2005). TLR4 appears to partially mediate the response to LPS- and O3-induced lung injury, however, TLR4 is protective for prevention of injury in Pseudomonas aeruginosa infection and against acute lung injury (hyperoxia). The mechanism behind this protection is unclear. We previously demonstrated that TLR4 was also protective against BHT-induced chronic inflammation and tumor promotion (Bauer et al, 2005). C.C3H-Tlr4Lps-d (BALBLps-d) mice, congenic for a 10 cM region of C3H/HeJ chromosome 4 that contains Tlr4 (Vogel et al, 1994), have a missence mutation that renders TLR4 dysfunctional. The Tlr4 mutation likely abrogates signaling by disrupting a direct point of contact with other signaling molecules (Akira S, Takeda K. Toll-like receptor signalling. Nat Rev Immunol 2004;4(7):499-511.). Bronchoalveolar lavage fluid (BALF) alveolar macrophages, lymphocytes, and total protein content were significantly elevated in BALBLps-d mice compared to BALB/c (BALB; Tlr4 sufficient) mice following chronic BHT (Bauer et al., 2005). BALBLps-d mice also had a significant increase in tumor multiplicity (60%) over that of BALB mice in response to an MCA/BHT tumor promotion protocol. While this was the first model to demonstrate a protective role for TLR4 in chronic lung inflammation and tumorigenesis, the downstream mechanism regulating this protective response remains unknown. Using Affymetrix microarray analysis followed by GeneSpring and Ingenuity pathway analyses, we herein identified known and novel downstream pathways and their interactions that may be involved in the protective mechanism elicited by TLR4. We therefore hypothesize that these pathways and interactions amongst the genes identified during the tumor promotion/chronic inflammation stage are in part influencing the differential strain response observed during tumorigenesis. Keywords: time course, tumor study Protocol 1 - 3 biological replicates after chronic dosing in each mouse strain Protocol 2 - multiple replicates after MCA/BHT tumor progression model used

Project description:There is an emerging concern that particulate air pollution increases the risk of cranial nerve disease onset. Small nanoparticles, mainly derived from diesel exhaust particles reach the olfactory bulb by their nasal depositions. It has been reported that diesel exhaust inhalation causes inflammation of the olfactory bulb and other brain regions. However, these toxicological studies have not evaluated animal rearing environment. We hypothesized that rearing environment can change mice phenotypes and thus might alter toxicological study results. In this study, we exposed mice to diesel exhaust inhalation at 90 micro g/m3, 8 hours/day, for 28 consecutive days after rearing in a standard cage or environmental enrichment conditions. Microarray analysis found that expression levels of 112 genes were changed by diesel exhaust inhalation. Functional analysis using Gene Ontology revealed that the dysregulated genes were involved in inflammation and immune response. This result was supported by pathway analysis. Quantitative RT-PCR analysis confirmed 10 genes. Interestingly, background gene expression of the olfactory bulb of mice reared in a standard cage environment was changed by diesel exhaust inhalation, whereas there was no significant effect of diesel exhaust exposure on gene expression levels of mice reared with environmental enrichment. The results indicate for the first time that the effect of diesel exhaust exposure on gene expression of the olfactory bulb was influenced by rearing environment. Rearing environment, such as environmental enrichment, may be an important contributive factor to causation in evaluating still undefined toxic environmental substances such as diesel exhaust. RNA sample was taken from olfactory bulb of 56-day-old mouse received diesel exhaust (DE) inhalation at 90 micro g/m3, 8 hours/day, for 28 consecutive days, while control RNA was taken from mouse received clean air, after rearing in a standard cage or environmental enrichment conditions. Comparisons among groups were made by one-color method with normalized data from Cy3 channels for data analysis.

Project description:Propylene glycol (PG) is a common carrier in e-vapor formulations and its properties have been extensively studied. In this 13-week subchronic nose-only inhalation study, Sprague Dawley rats were exposed to filtered air (sham control group), propylene glycol/water (PG/W; 90:10) or a propylene glycol/vegetable glycerin/water (PG/VG/W; 50:40:10) reference. The reference containing vegetable glycerin group was added at the high dose to observe any changes that might be associated with a carrier more in line with e-vapor products. The objectives of this study were to increase the PG exposure above the concentrations tested by Suber et al. and use a systems toxicology analysis of lung tissue to further our understanding of molecular events after PG exposures (Suber et al. 1989). Macroscopic examinations at necropsy as well as terminal organ weights revealed no observations that were associated with exposure to PG/W or reference. Food consumption and body weights were unaffected by PG/W or reference when compared to the sham. No exposure related alterations were observed in serum chemistry, hematology, coagulation, urinalysis or BALF cytology and clinical chemistry. Although clinical observations of dried red material around the nose in the high dose PG/W group were reported, histopathology of the nasal cavity showed no nasal hemorrhaging. There were non-adverse PG/W and reference related findings of minimal mucus cell hyperplasia noted in nasal cavity section II. These findings were considered non-adverse as they were also found to a lesser extent in the filtered air controls. No other exposure-related findings were noted in the primary or recovery necropsies. A systems toxicology analysis on lung tissue showed no statistically-significant differentially expressed transcripts or proteins compared to the sham group. The endpoints measured from the PG/W high dose group did not differ significantly from those in the more common carrier PG/VG/W. Accordingly, the highest PG exposure (5 mg/L, 6 hrs/day) was regarded as the no observed adverse effect concentration (NOAEC), corresponding to a PG delivered dose of 1,152 mg/kg/day in rats.

Project description:Parasitic diseases of humans and other animals represent a major socioeconomic burden worldwide. In humans, parasitic worms (helminths) that cause neglected tropical diseases (NTDs) affect ~ billion people, equating to a burden of >12 million disability-adjusted life years (DALYs) (Hotez et al., 2014). In other animals, although challenging to quantitate, the disease impact of such helminths is major (Pedersen, et al., 2015; Charlier et al., 2020; Selzer and Epe, 2021), and some of these parasites are also transmissible to humans (i.e. zoonotic) (McCarthy et al., 2000; Gordon et al., 2016). The control of these diseases relies on diagnosis, treatment and management strategies, and anthelmintic treatment is usually a central component of a control campaign, as vaccines are not available for the vast majority of them. These treatments are not always highly efficacious/effective, and the reliance on them, particularly if they are used excessively in an uncontrolled (suppressive) manner, has led to the emergence and spread of anthelmintic resistances in parasitic worms (within 4-X generations; REF), particularly those of animals. Although the resistance status of worms of humans to available compounds is somewhat unclear (Prichard, 2005; Keiser and Utzinger, 2008; Vercruysse et al., 2011), this is not the case for worms of important production animals (e.g., sheep, goats and pigs), where such resistance(s) is/are widespread and essentially worldwide. In recent work, we established a high-throughput whole-organism, phenotypic assay for the screening of relatively large libraries of tens to hundreds of thousands of compounds, the subsequent evaluation of active compounds and structure-activity relationship (SAR) studies to strive toward the optimisation of the activity and potency of analogs, and the minimisation of side effects and toxicity (Taki et al., 2021b; Taki et al., 2021c; Shanley et al., 2022). However, our early discovery work has been hampered by not knowing the target(s) to which compounds might bind and how they might work. In recent years, there have been major advances in the development of methods for identifying drug-target interactions (reviewed by Mateus et al., 2021), which include affinity purification, activity-based protein profiling, kinobeads (for kinases), stability of proteins from rates of oxidation, protein painting, limited proteolysis/drug affinity responsive target stability and thermal proteome profiling (TPP). Published evidence (Savitski et al., 2014; Perrin et al., 2020; Selkrig et al., 2020) demonstrates clearly the exquisite capacity of TPP to define or infer target molecules in projects with a biomedical focus (e.g., cancer, autophagy or infectious disease), but this method has not yet been utilised to define an anthelmintic target. This context provides the very exciting prospect of being able to rapidly provide evidence of drug-target interactions. For these reasons, in the present study, we undertook a high-throughput whole-organism, phenotypic screen of a well-curated compound library, identified ‘hit’ compounds for evaluation, identified one candidate with lead-like characteristics and inferred the target of this promising small molecule in H. contortus.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.

Project description:S. aureus strain JKD6009 RNase III-HTF and USA300 RNase III-HTF were used in our study to capture the RNA-binding proteome in Staphylococcus aureus. Both strains were inoculated in TSB (Tryptone soya broth, Oxioid CM0129) and overnight cultured in 37°C, 200 rpm shaker. Strain JKD6009 RNase III-HTF was sub-cultured into 190 ml LPM (Coombes et al., 2004) (Low phosphate, low magnesium medium, 5 mM KCl, 7.5 mM (NH4)2SO4, 0.5 mM K2SO4, 8 µM MgCl2, 1 M KH2PO4, 16 mM Tris-HCl, 0.1% casamino acids, 0.3% Glycerol) and grew from OD600 0.01 to 1. Overnight cultures of USA300 RNase III-HTF was re-inoculated to 65 ml fresh TSB to OD600 0.05 and left to grow to an OD600 of ~3. Cells were then filtered through 0.45 µm filters using a vacuum filtration device (UVO3; (McKellar et al., JoVe 2020; Van Nues et al., Nature Communications 2017)) shifted to same volume of LPM medium for 15 min at 37ºC and UV irradiated in LPM in the Vari-X-linker (λ =254 nm) (https://www.vari-x-link.com; (McKellar et al., 2020; Van Nues et al., 2017)) with an energy dose of 2J/cm2. In total, 6 replicates were collected (three technical and two biological replicates) for each experiment.