Zebrafish Biology, Health, and Diseases - PowerPoint PPT Presentation

1 / 47
About This Presentation
Title:

Zebrafish Biology, Health, and Diseases

Description:

Zebrafish Biology, Health, and Diseases – PowerPoint PPT presentation

Number of Views:764
Avg rating:3.0/5.0
Slides: 48
Provided by: nezhao
Category:

less

Transcript and Presenter's Notes

Title: Zebrafish Biology, Health, and Diseases


1
Zebrafish Biology, Health, and Diseases
  • Claudia Harper, DVM, Dipl. ACLAM

2
Presentation Outline
  • Zebrafish as a Biomedical Research Model
  • Non Protocol Sources of Variation in Aquatic
    Biomedical Research
  • Disease Prevention
  • Clinical Signs of Disease
  • Zebrafih Pathogens
  • Bacteria
  • Mycosis
  • Virus
  • Protozoa

3
Zebrafish and Research
  • Biological pathways
  • Carcinogenicity
  • Drug development
  • Genomics
  • Genetics
  • Behavioral
  • Molecular
  • Mutagenesis screening
  • Toxicology
  • Vertebrate development
  • Other

4
Non Protocol Sources of Variation on Aquatic
Biomedical Research
  • Maintaining healthy animals minimizes non
    protocol sources of variation associated with
    disease and in apparent infection
  • The widespread use of genetically engineered fish
    is likely to modify current concepts of aquatic
    diseases because of novel or unpredictable
    interaction among genetic alterations which can
    alter disease expression in genetically
    engineered fish

5
Non Protocol Sources of Variation
  • Sources of variation can include any factor that
    may impact histology, organogenesis, behavior,
    gene regulation, physiology and immunology etc.
  • These variables have been well described in
    rodent models used as biomedical research. These
    variables include genetics, bacteria, protozoan,
    viruses, fungal agents and environmental
    parameters.
  • There are few publications regarding non protocol
    variables in zebrafish.

6
Examples of Possible Non Protocol Sources of
Variation in Aquatic Biomedical Research
  • Disease
  • Environmental parameters
  • Fish genetics
  • Health status
  • Husbandry practices
  • Nutrition
  • Etcetera

7
Poor Water Quality - Gill Hyperplasia
10x
40x
Gills are involved in respiration, excretion of
nitrogenous waste, ion balance
8
Disease Prevention
9
(No Transcript)
10
Diseases Prevention
  • Source of Fish, Water and Feed
  • Ekkwill water life resource pond reared in
    Gibsonton Florida, Aquatic Ecosystems in Florida,
    Scientific hatcheries in California, ZIRC in
    Oregon Storage of feed
  • Quarantine Program / Bleach eggs
  • Established Traffic Flow - Clean to Dirty
  • Maintenance of life support systems. Ex.
    Ultraviolet light can minimize the number of
    infectious agents in the water.
  • Husbandry practices which minimizes the presence
    of biological substrate.
  • Cleanliness of facility.
  • Disinfection of systems between groups of fish to
    prevent disease transmission by equipment,
    personnel, or water.

11
Diseases Prevention
  • Wash hands with soap upon entering the facility
  • Disinfect footwear and wheels of carts
  • Reduce the number of visitors to a minimum
  • Monitor water quality parameters
  • Sentinel programs
  • Reduce stressful conditions - susceptibility to
    disease
  • Crowding, low water flow, poor nutrition, poor
    water quality, rapid water fluctuations, fish
    handling

12
Stress in Fish
INCREASING DEGREE OF STRESS
13
Stress Disease Prevention
  • Physiology
  • Elevated cortisol and catecholamine (head kidney)
  • Elevated blood glucose
  • Hematology and CBC chemistry profile
  • Gene regulations
  • Increased expression of Myostatin zfMSTN-1 and-2
    gene expression in spleens from stressed fish -
    Myostatin is a member of the TGF-beta superfamily
    and a potent negative regulator of muscle growth
    and development
  • Immune modulation
  • Stress impairs the production and release of
    antibodies. Temperature stress severely limits
    the fishs ability to release antibodies leading
    to increased disease susceptibility
  • Cell Signaling
  • Heat shock proteins

14
Why Do Laboratory Zebrafish Get Sick
  • Handling
  • Dermal abrasion
  • Net induced injury
  • Egg stripping
  • Pathogens
  • Parasites
  • Bacteria
  • Poor water quality
  • Stress
  • Overcrowding

15
Signs of Disease
  • Eyes
  • Exophthalmia
  • Gill
  • coloration
  • Fins / Skin
  • Frayed fins
  • Ulceration
  • Excess mucus
  • Discoloration
  • Skeletal deformities
  • Body Condition
  • Abdominal distention
  • Emaciation
  • Urogenital pore
  • Fecal casts

16
BACTERIA
Electron micrograph of Aeromonas hydrophila
  • Bacteria
  • Mycobacterium spp.
  • Flexibacter columnaris
  • Aeromonas hydrophila

17
Flexibacter columnaris
  • ETIOLOGY
  • Gram-negative slender rods (3-8 microns)
  • Gliding bacteria
  •  
  • TRANSMISSION
  • Opportunistic ubiquitous pathogen
  • Fry are the most susceptible. All ages may be
    affected.
  • Skin damage maybe needed to initiate infection
  • CLINICAL PRESENTATION
  • Flared opercula and fish face the water current
  • Mucus strands from gills
  • Lethargy and anorexia
  • Skin lesions and frayed fins

18
Flexibacter columnaris
  • DIAGNOSIS
  • Culture bacteria from lesions (skin or gills)
  • Wet mount preparation of gills
  • Flavobacterium branchiophilum - non motile
  • Flexibacter columnaris gliding bacteria
  • Histopathology of skin or gills
  • proliferation of the epithelium resulting in
    clubbing and fusion of the lamella. Necrosis of
    the gill lamella occurs in serious cases.
  •  

19
Flexibacter columnaris
Abnormal Gill Histology
Normal Gill Histology
20
Motile Aeromonad Septicemia
  • ETIOLOGY
  • Aeromonas hydrophila is an opportunistic gram
    negative motile bacteria
  • HISTORY CLINICAL PRESENTATION
  • Effects many different freshwater species
  • Associated with stress and overcrowding
  • The clinical signs and lesions are variable
  • Most common finding is hemorrhage in skin, fins,
    oral cavity and muscles with superficial
    ulceration of the epidermis.
  • Exophthalmus and ascites are common findings.
  • Splenomegaly and swollen kidneys are common
    findings.
  • Occasionally cavitating ulcers maybe seen.
  • Necrosis of multiple organs such as spleen,
    liver, kidney and heart maybe observed.
  • Acute to chronic mortality
  • Myositis

Pullium et al. 2000
21
Motile Aeromonad Septicemia contd
  • DIAGNOSIS
  • Histology dermatitis / myositis
  • Culture Rimmler-Shotts 22 to 25C
  • PREVENTION
  • Avoid stress stocking density, water quality
  • Avoid elevated water temperature
  • UV approximately 5 000 microW sec/cm2
  • TREATMENT
  • Stress born disease - Remove the environmental
    stress that caused the outbreak
  • Antibiotics may not be necessary
  • Oxytetracycline, sulfamethoxine-ormetoprim,
    chloramphenicol, nifurpirinol

Urogenital pore
22
Mycobacteriosis
Astrofsky et al. 2000
  • ETIOLOGY
  • M. marinum, M. abscessus, M. chelonae and M.
    fortuitum
  • Ubiquitous acid-fast bacteria found in the soil
    and water
  • HISTORY MODE OF TRANSMISSION
  • Poor water quality
  • Colonize biofilms on tanks and pipes
  • Stressed fish (overcrowding or immunocompromised
    animals)
  • CLINICAL PRESENTATION
  • Subclinical, lethargy, anorexia
  • Chronic, systemic bacterial infections with low
    level mortality
  • Skin ulcers, raised scales and frayed fins
  • Decreased reproductive performance
  • Presence of multiple, white nodules in various
    visceral organs
  • DIAGNOSIS
  • Histology acid-fast-positive, rod-shaped
    bacteria
  • Culture on selective media

23
Mycobacterium marinumGranulomatous nephritis and
hepatitis
24
Mycobacteriosis
  • PREVENTION
  • Disinfection
  • Quarantine
  • Maintain good water quality
  • Minimize stress
  • TREATMENT
  • No known treatment
  • ZOONOSIS
  • Fish tank granuloma, swimming pool granuloma

25
Mainous ME, Smith SA. 2005. Efficacy of common
disinfectants against Mycobacterium marinum.
Journal of Aquatic Animal Health 17284288
The most effective disinfectants against M.
marinum are 70 and 50 ethyl alcohol, benzyl-
4-chlorophenol-2-phenylphenol (Lysol), and sodium
chlorite (Clidox-S). They can reduce the number
of detectable M. marinum to zero within 1 min of
contact time. Sodium hypochlorite (Ultra-
Clorox) was moderately effective but required at
least 10 min of contact time to reduce bacterial
counts and 20 min of contact time to eliminate
the organism
26
Nematodes
  • Nematodes / Platyhelminths
  • Pseudocapillaria tomentosa
  • Tubellarians
  • Stylaria

27
Intestinal Capillariasis
  • ETIOLOGY
  • Metazoan parasite Pseudocapillaria tomentosa
  • Broad host specificity infecting approx. 25
    fishes in the Cyprinid family
  • Capillarids infect all classes of vertebrates and
    are pathogenic as they invade tissues
  • TRANSMISSION
  • Indirect life cycle intermediate hosts such as
    oligochaete worms
  • Tubifex tubifex can serve as a host
  • Direct transmission can also occur
  • CLINICAL PRESENTATION
  • Reduced growth potential
  • Decrease reproductive rate
  • Wasting Disease
  • Intestinal carcinomas

Fig 1. Double operculated Capillaria egg
28
Intestinal Capillariasis
  • DIAGNOSIS
  • Microscopic examination
  • fresh feces allows visualization of the egg
  • gut content allows visualization of the worm
  • PREVENTION
  • Quarantine
  • Do not feed worms
  • TREATMENT
  • No treatment tested in zebrafish
  • Ivermectin low therapeutic index and thus
    dangerous
  • Fenbendazole

29
Intestinal Capillariasis(Kent et al. 2002)
30
Tubellarian
  • ETIOLOGY
  • Free living tubellarian, trematode
  • Opportunistic organism in fresh water aquaria
  • TRANSMISSION
  • Direct transmission
  • CLINICAL PRESENTATION
  • Infection is load dependant
  • Affects skin and gills
  • DIAGNOSIS
  • Wet mount of gills or skin
  • PREVENTION
  • Minimize organic load accumulation
  • TREATMENT
  • Improve water quality and husbandry

31
Stylaria
  • ETIOLOGY
  • Free living oligochaete
  • TRANSMISSION
  • Direct transmission
  • CLINICAL PRESENTATION
  • None
  • DIAGNOSIS
  • Wet mount of organic waste
  • RISK
  • Intermediate host for many pathogens
  • PREVENTION
  • Minimize organic load accumulation

32
WATER MOLDS MICROSPORIDIAN
  • Microsporidian
  • Pseudoloma neurophilia
  • Mold
  • Saprolegnia sp.
  • Acremonium sp.
  • Lecythophora mutabilis

33
Microsporodiosis
  • ETIOLOGY
  • Neural microsporidiosis
  • Pseudoloma neurophila obligate intracellular
    parasites
  • CLINICAL DISEASE
  • Emaciation
  • Spinal curvature (lordosis, kyphosis, scoliosis)
  • TRANSMISSION
  • Horizontal and vertical transmission
  • PATHOLOGY DIAGNOSIS
  • PCR whole body
  • Wet mounts central nervous system (laborious)
  • Histology Acid fast stain and HE
  • Xenoma (spores) in central nervous system
  • Spinal cord and hindbrain
  • CONTROL AND TREATMENT

34
Microsporidiosis, Pseudoloma neurophiliain
Zebrafish Brain Muscle
35
Typical Water Mold Infection
  • ETIOLOGY
  • Saprolegnia spp. is an opportunistic fresh water
    fungus
  • Most common fungal infection of fresh water and
    estuarine fish
  • Class Oomycetes
  • TRANSMISSION
  • Direct transmission and affects all species and
    ages
  • The fungi are normal water inhabitants that
    invade the traumatized epidermis.
  • Infection acquired from inanimate sources such as
    fungi sporulating on inanimate sources releasing
    motile zoospores (dead fish or eggs)
  • Improper handling, bacterial or viral skin
    diseases, and trauma are the major causes of the
    disease.
  • CLINICAL PRESENTATION
  • White to brown cotton-like growths on skin, fins,
    gills, traumatized epidermis
  • Superficial lesions start on small surface and
    spread rapidly
  • Fish die due to osmotic or respiratory problems
    if the affected area of skin or gills is large.

36
Typical Water Mold Infection
  • DIAGNOSIS
  • Wet mount broad nonseptate branching hyphae
    motile flagellated zoospores in the terminal
    sporangia skin or gills
  • Culture
  • Potato dextrose agar pH 5.6 (yeast fungi)
  • Cottonseed Agar
  • Cornmeal Agar
  • PREVENTION TREATMENT
  • Avoid skin damage and predisposing stress
  • Water molds cannot be eliminated from any culture
    system
  • Prolonged salt immersion 1-5 ppt (1-5 gm / L)

37
Lecythophora mutabilis (Dykstra et al. 2001)
  • ETIOLOGY
  • Ubiquitous, opportunistic fungal agent
  • TRANSMISSION
  • Direct transmission
  • CLINICAL PRESENTATION
  • Lethargy, reduced appetite, mortality
  • Fry ( 5-24 days post hatch) most commonly
  • affected
  • Biofilm around the head occluding of oral cavity,
  • starvation, asphyxiation
  • DIAGNOSIS
  • Culture
  • PREVENTION TREATMENT
  • Maintain total hardness and calcium within normal
    levels

38
Lecythophora mutabilis (Dykstra et al. 2001)
eyes
Oral cavity
Fungal hyphae
gills
39
Protozoan
  • Tetrahymena sp.
  • Oodinium sp.
  • Ichthyophthirius multifilis
  • Trichodina sp.
  • Ichthyobodo sp.
  • Epistylis

RM Durborow. 2003. SRAC Publication No. 4701
40
Chilodonella
  • ETIOLOGY
  • Oval flat protozoan
  • Parallel rows of cilia and a notched anterior end
  • TRANSMISSION
  • Direct transmission
  • Parasite glides over the fish gill and skin
    surface
  • CLINICAL PRESENTATION
  • Whitish or bluish sheen on body
  • Heavy infection can cause mortality
  • DIAGNOSIS
  • Wet mount Free swimming parasite with erratic
    swimming behavior
  • Histopathology skin or gill
  • TREATMENT
  • Salt bath
  • Copper Sulfate

41
Tetrahymenosis
  • ETIOLOGY
  • Tetrahymena spp.
  • Ciliated protozoa that have worldwide
    distribution in FW SW
  • Related to Ichthyophthirius multifiliis
  • TRANSMISSION
  • Direct contact
  • Mode of entry into the host has not been well
    documented
  • Commonly found
  • Resident of biofilter
  • Food source
  • CLINICAL PRESENTATION
  • Sudden, high mortality in 30-day-old fry - 100
    mortality
  • Epithelial necrosis and hemorrhage, myositis,
    exophthalmos due to peri-ocular tissue invasion,
    subdermal muscle tissue necrosis with minimal
    inflammatory
  • Colonize the surface epithelium and cause excess
    mucus production
  • DIAGNOSIS
  • Wet mount, histopathology gills, skin or
    internal organs

42
Trichodiniasis
  • ETIOLOGY
  • Trichodina sp.
  • Ciliated protozoans
  • Saucer-shaped, 50 microns diameter, cilia, macro
    micro nucleus
  • HISTORY AND CLINICAL PRESENTATION
  • Not always associated with disease.
  • Flashing and become lethargic
  • Skin -increase in mucus production (white to
    bluish haze)
  • - ulcers and the fins may fray
  • Respiratory distress.
  • TRANSMISSION
  • Direct contact with infected fish and or
    contaminated water.
  • DIAGNOSIS
  • Wet mount of skin and gills
  • Histologically, masses of organisms are attached
    by adhesive discs to the skin.
  • The underlying epithelial cells undergo necrosis.
  • There is secondary hyperplasia and hypertrophy of
    the gill epithelium.

RM Durborow. 2003. SRAC Publication No. 4701
43
Costiosis
  • ETIOLOGY
  • Ichthyobodo spp.
  • Protozoa
  • 6-12 microns long with flagella smallest
    parasite
  • Piriform shaped Stalked protozoa
  • HISTORY AND CLINICAL PRESENTATION
  • Commonly affects hatchery raised fish and
    attaches to the skin or gills (feeds on fish)
  • Flashing
  • Skin -increase in mucus production (white to
    bluish haze)
  • Respiratory distress (flaring of gills).
  • Mortalities
  • TRANSMISSION
  • Direct contact
  • DIAGNOSIS
  • Wet mount (40X)
  • Histology of skin and gills

44
VIRUS
45
Lymphocystis
  • ETIOLOGY
  • Iridovirus DNA virus affecting freshwater and
    saltwater fishes
  • Most common viral infection - reported in over
    125 species of FW and SW fish
  • TRANSMISSION CLINICAL PRESENTATION
  • causes diseases that range in severity from
    subclinical to lethal
  • White yellow raised cauliflower-like lesions on
    fin and skin
  • Epidermal abrasions acts as port of entry.
    Infected cells are enlarged and rupture or
    slough off and which release the viral particles
    into the water.
  • Disease runs its course in 4 or more weeks
    (depending on species and water temperature)
    Complications
  • Lesions on the mouth may lead to difficulty in
    feeding and difficulty breathing if gills are
    affected.
  • Prone to secondary bacterial or fungal infections
  • Lethargy and low mortality rate
  • DIAGNOSIS
  • Wet mount skin or gills showing massively
    enlarged dermal fibroblasts
  • Histology Virus infects dermal fibroblast and
    causes cytomegaly
  • TREATMENT
  • Isolate affected animals as viral particles in
    the water can infect other fish.

Picture from http//www.aquariumpharm.com/disease/
lymphocystis.html
46
Drugs and Ammonia Detoxification BacteriaFrom
Noga EJ. 1996. Fish Diseases Diagnosis and
Treatment. P.65
47
Conclusions on Zebrafish Diseasesin Biomedical
Research
  • Most diseases in zebrafish research settings can
    be prevented by good husbandry, good water
    quality and preventive programs.
  • More research and publications are needed which
    specifically pertain to zebrafish.
Write a Comment
User Comments (0)
About PowerShow.com