zebrafish as a model system to study toxicology

Amol R. PadolPhD Scholar

Division of Pharmacology and Toxicology, IVRI

What is Zebrafish..??

o Tropical fresh water

fish

o Origin- Ganges &

Brahmaputra river

basin

o popular aquarium fish

Kingdom Animalia

Phylum Chordata

Class Actinopterygii

Order Cypriniformes

Family Cyprinidae

Genus Danio

Species D. rerio

Developmental stages

Zygote

Cleavage

Blastula

Gastrula

Segmentation

Hatching

Larva

Juvenile

Adult

Zebrafish into Research

o 1970's- University of Oregon

o Dr George Streisinger

o Zebrafish Information Network (ZFIN)

o Over 5,000 researchers in 450 labs

throughout 31 countries

o NCBI- over 1400 publications

Genome sequencing

o The Wellcome Trust Sanger Institute - zebrafish

genome sequencing project

o 2009- Institute of Genomics & Integrative

Biology, New Delhi

o 17 April 2013- zebrafish reference genome

sequence was published

Zebrafish a model system

o Small size

o Short life cycle & generation time

o Good reproduction captivity

o External fertilization

o Optically transparent embryo

o Rapid embryonic development

o High similarity in cellular structure, signaling &

physiology with other high-order vertebrate

o Drug metabolising CYPs (1A, 3A) & phase II

enzymes (e.g. GST, sulfotransferases) (Goldstone et al., 2010)

Zebrafish a model system

Orthologue genes between

Danio rerio & humans

Powerful model organism

o Genetics

o Developmental biology

o Toxicology

o Pharmacology

o DNA repair

o Cancer

Organizations that promotes

alternatives to animal testing

o European Centre for Validation of Alternative

Methods (ECVAM)

o Interagency Coordinating Committee on the

Validation of Alternative Methods (ICCVAM)

o Department of Pharmacology, Jawaharlal Nehru

Medical College, Aligarh Muslim University, Aligarh

o Japanese Centre for the Validation of Alternative

Methods (JACVAM)

Zebrafish use in ecotoxicology

o Eco-environmental monitoring

o Sensitivity to different contaminants

o Toxic heavy metals, endocrine disruptors &

organic pollutants

o Changes in morphology, gene expression,

behavior or physiology(Dai et al., 2014)

Current OECD guidelines

o OECD TG 236: Fish Embryo Acute Toxicity (FET) Test

o OECD TG 203: Fish, Acute Toxicity Test

o OECD 204: Fish, Prolonged Toxicity Test: 14-day Study

o OECD 215: Fish, Juvenile Growth Test

o OECD TG 203: Fish,

acute toxicity test

Exposure period- 96 h

Mortalities are recorded at

24, 48, 72 & 96 h to

determine LC50

Zebrafish use in ecotoxicology

Zebrafish use in ecotoxicology

OECD TG 236: Fish embryo

toxicity

Test system- embryonic stages

Exposure period- 96 h

Indicators of lethality

coagulation of fertilized eggs,

lack of somite formation,

lack of detachment of the tail-bud

from the yolk sac,

lack of heart-beat.

LC 50 is determined

Biomarker Toxicant Reference

Cholinesterases Cadmium acetate, lead

acetate

Richetti et al., 2011

SOD, catalase Cadmium, zinc Ling et al., 2011

Adenosine

deaminase

mercury chloride Senger et al., 2010

Metallothionein Cu2+, Hg2+, Cd2+ Chan et al., 2007

Thyroid hormone

levels

Polybrominated

diphenyl ethers

Yu et al., 2010

Principal biomarkers used in

ecotoxicological evaluations with

zebrafish

Monitoring endocrine disruptors

o Polybrominated diphenyl ethers (PBDEs )-

disrupts transport, storage & metabolism of

retinoid in zebrafish (Chen et al., 2012)

o Dioxin inhibits follicle maturation by

disturbing estrogen biosynthesis & estrogen-

regulated signal transduction (Heiden et al., 2008)

Monitoring endocrine disruptors

o BPA exposure - brain-specific overexpression of

aromatase in early zebrafish embryos (Chung et al.,

2011)

o Vitellogenin 1 (vtg1) mRNA expression in male

zebrafish - BPA, endosulfan, heptachlor,

Methoxychlor

(Zhong et al., 2014)

Developmental Toxicology: In Vivo

Assays

Mammalian studies:

o Segment I: Fertility in males & females (rats)

o Segment II: Developmental toxicity/embryotoxicity (rats

& rabbits)

o Segment III: Peri-natal toxicity (rats)

Segment II protocol (rabbits)*:

6-18 days Day 30Day 0Maternal Developmental

Body weight Implantation

Feed consumption Resorption rate

Clinical signs Fetal weight

Gross lesions External, visceral,

skeletal alterations

o Fertilized eggs

o Exposure period- 3 days

o Morphological endpoints:

Heart, spinal cord, somite, notochord,

brains, arches, jaws, tail, fins, face,

stomach, liver

o Growth measurements:

Body length, body shape, somite numbers,

yolk ball, swimming bladder, pigmentation

o Teratogenic index

Teratogenicity: Zebrafish

Brannen et al., 2010

Teratogenicity

o Evaluation of embryotoxicity of 12 compounds

• compared with teratogenicity of these

compounds in mammals

• non-teratogenic - 75 %

• teratogenic - 100 % (McGrath et al., 2008)

o Can detect both direct teratogens & proteratogens

o to develop a harmonized zebrafish developmental

toxicity assay

o 10 teratogens & 10 non-teratogens

cont…

o Inter-laboratory assessment achieved 60-70

% concordance

o Entire test set re-evaluated using the

optimized protocol- 85 % concordance was

achieved

o Zebrafish developmental toxicity assay can

be used for predictive classification of

teratogenic potential of drugs

o 10 % market withdrawals

o Current assessment

mammalian models

FOB

neurohistopathology

behavioral assessment

o laborious & time consuming

Neurobehavioral toxicity

Neurobehavioral toxicity:

Zebrafish

o Developing or adult zebrafish

o Impairment of swimming

o Locomotor activity

o Morphologic lesions neuronal apoptosis

proliferation

integrity of the myelin

sheath

(Muth-Köhne et al., 2012)

o Two chamber heart

o Voltage gated sodium channel, L & T-

type Ca channels & potassium

channels

o Clarity of embryos & larvae

o survive for several days without

circulation

o ECG pattern

Cardiotoxicity

A. Human

Cardiotoxicity

o Zebrafish larvae (3 dpf)

o Exposure period- 3 h

o ventricular & auricular heart rate, cardiac

output & stroke volume

o Cardiac morphologyWu et al., 2013

Ototoxicity

o Common side effect of many drugs- no

standard screen

o Neuromasts- the zebrafish counterpart of hair

cells

o Neuromasts- sensitive to ototoxic agents like

gentamicin, cisplatin & quinine(Buck et al., 2012)

o 5 day old embryo

o Exposure period- 24 h

o Endpoints:

• Microscopic evaluation

• Hair cell density

• reversiblity

Ototoxicity: Zebrafish

Chang et al., 2013

Organ-specific toxicity

Preparation Concentration Observed effect/toxicity

Doxorubicin 30 mg/l Teratogenicity, nephrotoxicity,

Hepatotoxicity, cardiotoxicity

Dexamethasone 324 mg/l Nephrotoxicity, hepatotoxicity,

GIT lesion

Methotrexate 454 mg/l Teratogenicity, nephrotoxicity,

Hepatotoxicity, cardiotoxicity,

GIT lesion

Fluorouracil 3.3 mg/l Nephrotoxicity, hepatotoxicity

Cyclosporin A 69 mg/l Teratogenicity, nephrotoxicity,

Hepatotoxicity, cardiotoxicity

Caffeine 108 mg/l Change of locomotor activity,

Muscular spasticity

Zebrafish Labs in India

o Institute of Genomics and Integrative Biology

(New Delhi)

o Center for Cellular and Molecular Biology

(Hyderabad)

o Indian Institute of Science (Bangalore)

o Tata Institute of Fundamental Research

(Mumbai)

o Institute of Life Sciences (Hyderabad)

o National Centre for Radio Astrophysics (Pune)

Limitations:

o The metabolizing enzymes are not fully

characterized

o Studies on zebrafish takes into consideration

only aqueous concentration of the TS

o Far more remote from humans than other animal

models such as rodents

o Anatomical differences with human

Conclusion

o Zebrafish as a model organism for toxicology has

low cost, ease of breeding & other advantages

o Certain known pathways leading to drug toxicity

in mammals are conserved in zebrafish

o Zebrafish model does not replace classical

mammalian models, but does represent an early

stage model for the toxicological assessment