Transgenic zebrafish larvae as a non-rodent alternative model to assess pro-inflammatory (neutrophil) responses to nanomaterials

Abstract Hazard studies for nanomaterials (NMs) commonly assess whether they activate an inflammatory response. Such assessments often rely on rodents, but alternative models are needed to support the implementation of the 3Rs principles. Zebrafish (Danio rerio) offer a viable alternative for screening NM toxicity by investigating inflammatory responses. Here, we used non-protected life stages of transgenic zebrafish (Tg(mpx:GFP)i114) with fluorescently-labeled neutrophils to assess inflammatory responses to silver (Ag) and zinc oxide (ZnO) NMs using two approaches. Zebrafish were exposed to NMs via water following a tail fin injury, or NMs were microinjected into the otic vesicle. Zebrafish were exposed to NMs at 3 days post-fertilization (dpf) and neutrophil accumulation at the injury or injection site was quantified at 0, 4, 6, 8, 24, and 48 h post-exposure. Zebrafish larvae were also exposed to fMLF, LTB4, CXCL-8, C5a, and LPS to identify a suitable positive control for inflammation induction. Aqueous exposure to Ag and ZnO NMs stimulated an enhanced and sustained neutrophilic inflammatory response in injured zebrafish larvae, with a greater response observed for Ag NMs. Following microinjection, Ag NMs stimulated a time-dependent neutrophil accumulation in the otic vesicle which peaked at 48 h. LTB4 was identified as a positive control for studies investigating inflammatory responses in injured zebrafish following aqueous exposure, and CXCL-8 for microinjection studies that assess responses in the otic vesicle. Our findings support the use of transgenic zebrafish to rapidly screen the pro-inflammatory effects of NMs, with potential for wider application in assessing chemical safety (e.g. pharmaceuticals).

[1]  Hae-Chul Park,et al.  Transgenic fluorescent zebrafish lines that have revolutionized biomedical research , 2021, Laboratory animal research.

[2]  W. Wohlleben,et al.  Variation in dissolution behavior among different nanoforms and its implication for grouping approaches in inhalation toxicity. , 2021, NanoImpact.

[3]  M. Goodfellow,et al.  Functional brain imaging in larval zebrafish for characterising the effects of seizurogenic compounds acting via a range of pharmacological mechanisms , 2021, British journal of pharmacology.

[4]  David M. Brown,et al.  Neutrophil activation by nanomaterials in vitro: comparing strengths and limitations of primary human cells with those of an immortalized (HL-60) cell line , 2020, Nanotoxicology.

[5]  J. Mullins,et al.  Live Imaging of Heart Injury in Larval Zebrafish Reveals a Multi-Stage Model of Neutrophil and Macrophage Migration , 2020, Frontiers in cell and developmental biology.

[6]  Matthew Boyles,et al.  A Method to Assess the Relevance of Nanomaterial Dissolution during Reactivity Testing , 2020, Materials.

[7]  P. Proost,et al.  Neutrophil chemoattractant receptors in health and disease: double-edged swords , 2020, Cellular & Molecular Immunology.

[8]  A. Nemmar,et al.  Health Impact of Silver Nanoparticles: A Review of the Biodistribution and Toxicity Following Various Routes of Exposure , 2020, International journal of molecular sciences.

[9]  W. Peijnenburg,et al.  Understanding Dissolution Rates via Continuous Flow Systems with Physiologically Relevant Metal Ion Saturation in Lysosome , 2020, Nanomaterials.

[10]  J. Freeman,et al.  Use of Zebrafish in Drug Discovery Toxicology. , 2020, Chemical research in toxicology.

[11]  M. Tang,et al.  Toxicological study of metal and metal oxide nanoparticles in zebrafish , 2019, Journal of applied toxicology : JAT.

[12]  N. Durán,et al.  Silver nanoparticles: Toxicity in model organisms as an overview of its hazard for human health and the environment. , 2019, Journal of hazardous materials.

[13]  R. van den Bos,et al.  Early Life Glucocorticoid Exposure Modulates Immune Function in Zebrafish (Danio rerio) Larvae , 2019, bioRxiv.

[14]  T. Kudoh,et al.  New insights into organ-specific oxidative stress mechanisms using a novel biosensor zebrafish. , 2019, Environment international.

[15]  Anders Baun,et al.  Interaction of biologically relevant proteins with ZnO nanomaterials: A confounding factor for in vitro toxicity endpoints. , 2019, Toxicology in vitro : an international journal published in association with BIBRA.

[16]  Yong-Moon Lee,et al.  Anti‐inflammatory effect of a novel synthetic compound 1‐((4‐fluorophenyl)thio)isoquinoline in RAW264.7 macrophages and a zebrafish model , 2019, Fish & shellfish immunology.

[17]  C. Parent,et al.  The LTB4–BLT1 axis regulates the polarized trafficking of chemoattractant GPCRs during neutrophil chemotaxis , 2018, Journal of Cell Science.

[18]  A. Andrianopoulos,et al.  Macrophages protect Talaromyces marneffei conidia from myeloperoxidase-dependent neutrophil fungicidal activity during infection establishment in vivo , 2018, PLoS pathogens.

[19]  Lang Tran,et al.  Adoption of in vitro systems and zebrafish embryos as alternative models for reducing rodent use in assessments of immunological and oxidative stress responses to nanomaterials , 2018, Critical reviews in toxicology.

[20]  H. Karlsson,et al.  Size-dependent genotoxicity of silver, gold and platinum nanoparticles studied using the mini-gel comet assay and micronucleus scoring with flow cytometry , 2018, Mutagenesis.

[21]  T. Kudoh,et al.  Early life exposure to ethinylestradiol enhances subsequent responses to environmental estrogens measured in a novel transgenic zebrafish , 2018, Scientific Reports.

[22]  D. Irimia,et al.  Microstructured Devices for Optimized Microinjection and Imaging of Zebrafish Larvae. , 2017, Journal of visualized experiments : JoVE.

[23]  M. Rahman,et al.  A systematic review on silver nanoparticles-induced cytotoxicity: Physicochemical properties and perspectives , 2017, Journal of Advanced Research.

[24]  Xiangjun Zhou,et al.  Protective Effect of Phillyrin on Lethal LPS-Induced Neutrophil Inflammation in Zebrafish , 2017, Cellular Physiology and Biochemistry.

[25]  K. Kissa,et al.  TNF signaling and macrophages govern fin regeneration in zebrafish larvae , 2017, Cell Death & Disease.

[26]  J. Sauer,et al.  Neutrophil derived LTB4 induces macrophage aggregation in response to encapsulated Streptococcus iniae infection , 2017, PloS one.

[27]  J. Marshall,et al.  Development of a Zebrafish Sepsis Model for High-Throughput Drug Discovery , 2017, Molecular medicine.

[28]  Davalyn R. Powell,et al.  Chemokine Signaling and the Regulation of Bidirectional Leukocyte Migration in Interstitial Tissues. , 2017, Cell reports.

[29]  M. Allende,et al.  In vivo Host-Pathogen Interaction as Revealed by Global Proteomic Profiling of Zebrafish Larvae , 2017, bioRxiv.

[30]  M. Allende,et al.  Live-cell imaging of Salmonella Typhimurium interaction with zebrafish larvae after injection and immersion delivery methods. , 2017, Journal of microbiological methods.

[31]  Z. Shraideh,et al.  Zinc oxide nanoparticles hepatotoxicity: Histological and histochemical study. , 2017, Environmental toxicology and pharmacology.

[32]  D. Irimia,et al.  Microstructured Surface Arrays for Injection of Zebrafish Larvae. , 2017, Zebrafish.

[33]  S. Fischer,et al.  Dose-dependent effects of morphine on lipopolysaccharide (LPS)-induced inflammation, and involvement of multixenobiotic resistance (MXR) transporters in LPS efflux in teleost fish. , 2017, Environmental pollution.

[34]  A. Meijer,et al.  The inflammatory chemokine Cxcl18b exerts neutrophil‐specific chemotaxis via the promiscuous chemokine receptor Cxcr2 in zebrafish , 2017, Developmental and comparative immunology.

[35]  Shareen H. Doak,et al.  The 3Rs as a framework to support a 21st century approach for nanosafety assessment , 2017 .

[36]  C. Haslett,et al.  Genetic and pharmacological inhibition of CDK9 drives neutrophil apoptosis to resolve inflammation in zebrafish in vivo , 2016, Scientific Reports.

[37]  H. Ruan,et al.  Systemic inoculation of Escherichia coli causes emergency myelopoiesis in zebrafish larval caudal hematopoietic tissue , 2016, Scientific Reports.

[38]  L. Kremer,et al.  Mycobacterium abscessus-Induced Granuloma Formation Is Strictly Dependent on TNF Signaling and Neutrophil Trafficking , 2016, PLoS pathogens.

[39]  Hongqiang Cheng,et al.  Manipulating the air-filled zebrafish swim bladder as a neutrophilic inflammation model for acute lung injury , 2016, Cell Death & Disease.

[40]  A. van der Ende,et al.  Infection of zebrafish embryos with live fluorescent Streptococcus pneumoniae as a real-time pneumococcal meningitis model , 2016, Journal of Neuroinflammation.

[41]  R. Kim,et al.  Developmental Toxicity of Zinc Oxide Nanoparticles to Zebrafish (Danio rerio): A Transcriptomic Analysis , 2016, PloS one.

[42]  A. Wei,et al.  Vascular toxicity of silver nanoparticles to developing zebrafish (Danio rerio) , 2016, Nanotoxicology.

[43]  Junchao Duan,et al.  Low-dose exposure of silica nanoparticles induces cardiac dysfunction via neutrophil-mediated inflammation and cardiac contraction in zebrafish embryos , 2016, Nanotoxicology.

[44]  T. Efferth,et al.  In Vivo Cardiotoxicity Induced by Sodium Aescinate in Zebrafish Larvae , 2016, Molecules.

[45]  Samantha Donnellan,et al.  A rapid screening assay for identifying mycobacteria targeted nanoparticle antibiotics , 2016, Nanotoxicology.

[46]  K. Awasthi,et al.  Silver Nanoparticles and Carbon Nanotubes Induced DNA Damage in Mice Evaluated by Single Cell Gel Electrophoresis , 2015 .

[47]  A. Salehzadeh,et al.  Toxicity of zinc oxide nanoparticles on adult male Wistar rats. , 2015, Food and chemical toxicology : an international journal published for the British Industrial Biological Research Association.

[48]  P. Hoet,et al.  Lung distribution, quantification, co-localization and speciation of silver nanoparticles after lung exposure in mice. , 2015, Toxicology letters.

[49]  David Rejeski,et al.  Nanotechnology in the real world: Redeveloping the nanomaterial consumer products inventory , 2015, Beilstein journal of nanotechnology.

[50]  David M. Brown,et al.  Mechanism of neutrophil activation and toxicity elicited by engineered nanomaterials. , 2015, Toxicology in vitro : an international journal published in association with BIBRA.

[51]  Robert L. Tanguay,et al.  Comparative metal oxide nanoparticle toxicity using embryonic zebrafish , 2015, Toxicology reports.

[52]  Da‐long Ren,et al.  Melatonin regulates the rhythmic migration of neutrophils in live zebrafish , 2015, Journal of pineal research.

[53]  Okhyun Lee,et al.  Transgenic fish systems and their application in ecotoxicology , 2015, Critical reviews in toxicology.

[54]  Jürgen Schnekenburger,et al.  Pulmonary toxicity of nanomaterials: a critical comparison of published in vitro assays and in vivo inhalation or instillation studies. , 2014, Nanomedicine.

[55]  Farooq Ahmad,et al.  Particle‐specific toxic effects of differently shaped zinc oxide nanoparticles to zebrafish embryos (Danio rerio) , 2014, Environmental toxicology and chemistry.

[56]  Christine Kirschhock,et al.  Toxicity of nanoparticles embedded in paints compared with pristine nanoparticles in mice. , 2014, Toxicological sciences : an official journal of the Society of Toxicology.

[57]  D. Girard,et al.  Zinc oxide nanoparticles delay human neutrophil apoptosis by a de novo protein synthesis-dependent and reactive oxygen species-independent mechanism. , 2014, Toxicology in vitro : an international journal published in association with BIBRA.

[58]  David Kistler,et al.  Dissolution of metal and metal oxide nanoparticles in aqueous media. , 2014, Environmental pollution.

[59]  G. Lutfalla,et al.  Transient infection of the zebrafish notochord with E. coli induces chronic inflammation , 2014, Disease Models & Mechanisms.

[60]  B. Wehrli,et al.  Comparative effects of zinc oxide nanoparticles and dissolved zinc on zebrafish embryos and eleuthero-embryos: importance of zinc ions. , 2014, The Science of the total environment.

[61]  T. Lu,et al.  Oxidative stress increased hepatotoxicity induced by nano‐titanium dioxide in BRL‐3A cells and Sprague–Dawley rats , 2014, Journal of applied toxicology : JAT.

[62]  Sabine U. Vorrink,et al.  Toxicity assessment of zinc oxide nanoparticles using sub-acute and sub-chronic murine inhalation models , 2014, Particle and Fibre Toxicology.

[63]  Z. Gong,et al.  Development of a Convenient In Vivo Hepatotoxin Assay Using a Transgenic Zebrafish Line with Liver-Specific DsRed Expression , 2014, PloS one.

[64]  Chun-Qi Li,et al.  Zebrafish models for assessing developmental and reproductive toxicity. , 2014, Neurotoxicology and teratology.

[65]  Maria João Silva,et al.  Genotoxicity evaluation of nanosized titanium dioxide, synthetic amorphous silica and multi-walled carbon nanotubes in human lymphocytes. , 2014, Toxicology in vitro : an international journal published in association with BIBRA.

[66]  L. Fraceto,et al.  Toxicity assessment of TiO₂ nanoparticles in zebrafish embryos under different exposure conditions. , 2014, Aquatic toxicology.

[67]  Wenqing Zhang,et al.  Endotoxin Molecule Lipopolysaccharide-Induced Zebrafish Inflammation Model: A Novel Screening Method for Anti-Inflammatory Drugs , 2014, Molecules.

[68]  Olivia J. Osborne,et al.  Effects of particle size and coating on nanoscale Ag and TiO2 exposure in zebrafish (Danio rerio) embryos , 2013, Nanotoxicology.

[69]  M. L. Cordero-Maldonado,et al.  Optimization and Pharmacological Validation of a Leukocyte Migration Assay in Zebrafish Larvae for the Rapid In Vivo Bioactivity Analysis of Anti-Inflammatory Secondary Metabolites , 2013, PloS one.

[70]  Junchao Duan,et al.  Toxic Effects of Silica Nanoparticles on Zebrafish Embryos and Larvae , 2013, PloS one.

[71]  W. Baumgartner,et al.  The toxicity of silver nanoparticles to zebrafish embryos increases through sewage treatment processes , 2013, Ecotoxicology.

[72]  K. Paszkiewicz,et al.  Molecular Mechanisms of Toxicity of Silver Nanoparticles in Zebrafish Embryos , 2013, Environmental science & technology.

[73]  E. Szabová,et al.  Acute toxicity of 31 different nanoparticles to zebrafish (Danio rerio) tested in adulthood and in early life stages – comparative study , 2013, Interdisciplinary toxicology.

[74]  M. Mortimer,et al.  Toxicity of Ag, CuO and ZnO nanoparticles to selected environmentally relevant test organisms and mammalian cells in vitro: a critical review , 2013, Archives of Toxicology.

[75]  V. Trudeau,et al.  Assessment of nanosilver toxicity during zebrafish (Danio rerio) development. , 2013, Chemosphere.

[76]  J. Rawls,et al.  Mucosal candidiasis elicits NF-κB activation, proinflammatory gene expression and localized neutrophilia in zebrafish , 2013, Disease Models & Mechanisms.

[77]  Julie M. Green,et al.  Localized bacterial infection induces systemic activation of neutrophils through Cxcr2 signaling in zebrafish , 2013, Journal of leukocyte biology.

[78]  Vicki Stone,et al.  An in vitro assessment of panel of engineered nanomaterials using a human renal cell line: cytotoxicity, pro-inflammatory response, oxidative stress and genotoxicity , 2013, BMC Nephrology.

[79]  Anton J. Enright,et al.  The zebrafish reference genome sequence and its relationship to the human genome , 2013, Nature.

[80]  C. Reyes-Aldasoro,et al.  Cxcl8 (IL-8) Mediates Neutrophil Recruitment and Behavior in the Zebrafish Inflammatory Response , 2013, The Journal of Immunology.

[81]  W. Heideman,et al.  TiO2 nanoparticle exposure and illumination during zebrafish development: mortality at parts per billion concentrations. , 2013, Environmental science & technology.

[82]  J. Marwick,et al.  Flavones induce neutrophil apoptosis by down-regulation of Mcl-1 via a proteasomal-dependent pathway , 2013, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[83]  W. Kreyling,et al.  Effects of silver nanoparticles on the liver and hepatocytes in vitro. , 2013, Toxicological sciences : an official journal of the Society of Toxicology.

[84]  Vicki Stone,et al.  Engineered Nanomaterial Impact in the Liver following Exposure via an Intravenous Route-The Role of Polymorphonuclear Leukocytes and Gene Expression in the Organ , 2012 .

[85]  Bing Hu,et al.  Establishment of multi-site infection model in zebrafish larvae for studying Staphylococcus aureus infectious disease. , 2012, Journal of genetics and genomics = Yi chuan xue bao.

[86]  Philip S Crosier,et al.  Neutrophils exert protection in the early tuberculous granuloma by oxidative killing of mycobacteria phagocytosed from infected macrophages. , 2012, Cell host & microbe.

[87]  Richard E Peterson,et al.  Titanium dioxide nanoparticles produce phototoxicity in the developing zebrafish , 2012, Nanotoxicology.

[88]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[89]  Antonio Marcomini,et al.  In vitro assessment of engineered nanomaterials using a hepatocyte cell line: cytotoxicity, pro-inflammatory cytokines and functional markers , 2012, Nanotoxicology.

[90]  T. Kudoh,et al.  Biosensor Zebrafish Provide New Insights into Potential Health Effects of Environmental Estrogens , 2012, Environmental health perspectives.

[91]  Kathryn E. Crosier,et al.  Infection-responsive expansion of the hematopoietic stem and progenitor cell compartment in zebrafish is dependent upon inducible nitric oxide. , 2012, Cell stem cell.

[92]  A. Huttenlocher,et al.  Distinct signalling mechanisms mediate neutrophil attraction to bacterial infection and tissue injury , 2012, Cellular microbiology.

[93]  Mark Bradley,et al.  Differential pro-inflammatory effects of metal oxide nanoparticles and their soluble ions in vitro and in vivo; zinc and copper nanoparticles, but not their ions, recruit eosinophils to the lungs , 2012, Nanotoxicology.

[94]  F. Besenbacher,et al.  In Vivo Toxicity of Silver Nanoparticles and Silver Ions in Zebrafish (Danio rerio) , 2011, Journal of toxicology.

[95]  A. Huttenlocher,et al.  Lyn is a redox sensor that mediates leukocyte wound attraction in vivo , 2011, Nature.

[96]  P. Ingham,et al.  Activation of hypoxia-inducible factor-1α (Hif-1α) delays inflammation resolution by reducing neutrophil apoptosis and reverse migration in a zebrafish inflammation model. , 2011, Blood.

[97]  H. Autrup,et al.  Cytotoxicity and genotoxicity of silver nanoparticles in the human lung cancer cell line, A549 , 2011, Archives of Toxicology.

[98]  A. Andrianopoulos,et al.  mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish. , 2011, Blood.

[99]  Paul Martin,et al.  Live Imaging of Innate Immune Cell Sensing of Transformed Cells in Zebrafish Larvae: Parallels between Tumor Initiation and Wound Inflammation , 2010, PLoS biology.

[100]  Wei Bai,et al.  Toxicity of zinc oxide nanoparticles to zebrafish embryo: a physicochemical study of toxicity mechanism , 2010 .

[101]  P. Ingham,et al.  Pivotal Advance: Pharmacological manipulation of inflammation resolution during spontaneously resolving tissue neutrophilia in the zebrafish , 2009, Journal of leukocyte biology.

[102]  N. Trede,et al.  Fish immunology , 2009, Current Biology.

[103]  R. Albrecht,et al.  Toxicity assessments of multisized gold and silver nanoparticles in zebrafish embryos. , 2009, Small.

[104]  Nicklas Raun Jacobsen,et al.  Lung inflammation and genotoxicity following pulmonary exposure to nanoparticles in ApoE-/- mice , 2009, Particle and Fibre Toxicology.

[105]  R. L. Jones,et al.  Unique cellular interaction of silver nanoparticles: size-dependent generation of reactive oxygen species. , 2008, The journal of physical chemistry. B.

[106]  A. Cvejic,et al.  Analysis of WASp function during the wound inflammatory response – live-imaging studies in zebrafish larvae , 2008, Journal of Cell Science.

[107]  Cheol‐Hee Kim,et al.  Real-time imaging of mitochondria in transgenic zebrafish expressing mitochondrially targeted GFP. , 2008, BioTechniques.

[108]  Z. Gong,et al.  Impact of multi-walled carbon nanotubes on aquatic species. , 2008, Journal of nanoscience and nanotechnology.

[109]  Z. Gong,et al.  Toxicity of silver nanoparticles in zebrafish models , 2008, Nanotechnology.

[110]  Brandon W. Kusik,et al.  Detection of Mercury in Aquatic Environments Using EPRE Reporter Zebrafish , 2008, Marine Biotechnology.

[111]  Yan Li,et al.  Comparative toxicity of several metal oxide nanoparticle aqueous suspensions to Zebrafish (Danio rerio) early developmental stage , 2008, Journal of environmental science and health. Part A, Toxic/hazardous substances & environmental engineering.

[112]  Jennifer M. Bates,et al.  Intestinal alkaline phosphatase detoxifies lipopolysaccharide and prevents inflammation in zebrafish in response to the gut microbiota. , 2007, Cell host & microbe.

[113]  P. Currie,et al.  Animal models of human disease: zebrafish swim into view , 2007, Nature Reviews Genetics.

[114]  P. Ingham,et al.  MODELING INFLAMMATION IN THE ZEBRAFISH: HOW A FISH CAN HELP US UNDERSTAND LUNG DISEASE , 2007, Experimental lung research.

[115]  P. Ingham,et al.  A transgenic zebrafish model of neutrophilic inflammation. , 2006, Blood.

[116]  Stephen L. Johnson,et al.  How the zebrafish gets its stripes. , 2001, Developmental biology.

[117]  Sung-Kook Hong,et al.  Analysis of upstream elements in the HuC promoter leads to the establishment of transgenic zebrafish with fluorescent neurons. , 2000, Developmental biology.

[118]  A. Dodd,et al.  Zebrafish: bridging the gap between development and disease. , 2000, Human molecular genetics.

[119]  A. Collins,et al.  In vitro genotoxicity testing of four reference metal nanomaterials, titanium dioxide, zinc oxide, cerium oxide and silver: towards reliable hazard assessment , 2017, Mutagenesis.

[120]  P. Tchounwou,et al.  Silver nanoparticle-induced oxidative stress-dependent toxicity in Sprague-Dawley rats , 2014, Molecular and Cellular Biochemistry.