Difference between revisions of "Leishmania"
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*Cause diseases in humans, dogs and wild animals | *Cause diseases in humans, dogs and wild animals | ||
− | *Present in southern Europe, Africa, Asia and | + | *Present in southern Europe, Africa, Asia and south America |
*Can cause both cutaneous and visceral diseases | *Can cause both cutaneous and visceral diseases | ||
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*Possesses a rod-shaped kinetoplast | *Possesses a rod-shaped kinetoplast | ||
− | *Has a | + | *Has a rudimentary flagellum which does not project beyond the cell margin |
*After the amastigote has transformed into a promastigote inside the [[Biting Flies#Psychodidae|sand fly]], the kinetoplast is situated in the posterior of the body | *After the amastigote has transformed into a promastigote inside the [[Biting Flies#Psychodidae|sand fly]], the kinetoplast is situated in the posterior of the body | ||
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**''Lutzomyia'' spp. in the New World | **''Lutzomyia'' spp. in the New World | ||
− | *The amastigote (morphological form) | + | *The amastigote (morphological form) is found in vertebrate [[Macrophage|macrophages]] |
*Ingested by [[Biting Flies#Psychodidae|sand fly]] during feeding | *Ingested by [[Biting Flies#Psychodidae|sand fly]] during feeding | ||
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*Multiplies and migrates to [[Insecta|insect]] proboscis | *Multiplies and migrates to [[Insecta|insect]] proboscis | ||
− | ** | + | **Inoculated during feeding |
**Can be transmitted percutaneously if [[Biting Flies#Psychodidae|sand fly]] crushed on skin | **Can be transmitted percutaneously if [[Biting Flies#Psychodidae|sand fly]] crushed on skin | ||
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**Produces foci of proliferating ''Leishmania''-infected [[Macrophage|macrophages]] in skin ('''cutaneous''') or internal organs ('''visceral''') | **Produces foci of proliferating ''Leishmania''-infected [[Macrophage|macrophages]] in skin ('''cutaneous''') or internal organs ('''visceral''') | ||
− | *Very long incubation | + | *Very long incubation period |
**Months to years | **Months to years | ||
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**Generalised lymphadenopathy | **Generalised lymphadenopathy | ||
− | *Long periods of remission followed by | + | *Long periods of remission followed by recurrence of clinical signs is not uncommon in infections |
*Involved in [[Parasitic skin infections - Pathology#Protozoa|skin infections]] | *Involved in [[Parasitic skin infections - Pathology#Protozoa|skin infections]] | ||
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*Mechanisms of transmission | *Mechanisms of transmission | ||
− | |||
**[[Biting Flies#Psychodidae|sand fly]] bite | **[[Biting Flies#Psychodidae|sand fly]] bite | ||
+ | **Rarely through direct contact | ||
*Leishmaniasis in British dogs | *Leishmaniasis in British dogs | ||
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*Demonstrate ''Leishmania'' organisms | *Demonstrate ''Leishmania'' organisms | ||
**In skin scraping or smears | **In skin scraping or smears | ||
− | **In [[Lymph Nodes - Anatomy & Physiology|lymph node]] or [[Bone Marrow - Anatomy & Physiology|bone marrow]] biopsies | + | **In joint fluid, [[Lymph Nodes - Anatomy & Physiology|lymph node]] or [[Bone Marrow - Anatomy & Physiology|bone marrow]] biopsies |
'''Treatment and Control''' | '''Treatment and Control''' | ||
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*Destruction of infected and stray dogs | *Destruction of infected and stray dogs | ||
− | **[[Biting Flies#Psychodidae|Sand flies]] biting infected dogs may spread the disease | + | **[[Biting Flies#Psychodidae|Sand flies]] biting infected dogs may spread the disease to other dogs, humans and wildlife |
**There is a slight possibility of transmission to humans by direct contact | **There is a slight possibility of transmission to humans by direct contact | ||
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*Causes sleeping sickness in humans | *Causes sleeping sickness in humans | ||
− | *Particularly | + | *Particularly seen in sub-Saharan Africa |
− | ** | + | **Affects cattle production |
− | ** | + | **Causes Nagana (Wasting disease) |
− | *Divided into two groups depending on the mode of development | + | *Divided into two groups depending on the mode of development in the insect vector |
**'''Salivarian''' | **'''Salivarian''' | ||
***Multiply in the foregut and proboscis | ***Multiply in the foregut and proboscis | ||
− | ***Transmitted via | + | ***Transmitted via inoculation during feeding |
***Transmitted by [[Biting Flies#Glossinidae|''Tsetse'' flies]] | ***Transmitted by [[Biting Flies#Glossinidae|''Tsetse'' flies]] | ||
***Also known as '''anterior station development''' | ***Also known as '''anterior station development''' | ||
**'''Stercorarian''' | **'''Stercorarian''' | ||
***Multiply in the hindgut | ***Multiply in the hindgut | ||
− | ***Infective | + | ***Infective form migrates to the [[Rectum - Anatomy & Physiology|rectum]] |
***Transmitted via contamination of wounds with insect faeces | ***Transmitted via contamination of wounds with insect faeces | ||
***Also known as '''posterior station development''' | ***Also known as '''posterior station development''' | ||
*All ''Trypansomes'' except for ''T. equiperdum'' have arthropod vectors | *All ''Trypansomes'' except for ''T. equiperdum'' have arthropod vectors | ||
− | **''T. equiperdum'' is a | + | **''T. equiperdum'' is a venereally transmitted disease |
*'''Non-cyclical''' transmission can also occur | *'''Non-cyclical''' transmission can also occur | ||
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*Salivarian trypanosomes are transmitted by [[Biting Flies#Glossinidae|Tsetse flies]] | *Salivarian trypanosomes are transmitted by [[Biting Flies#Glossinidae|Tsetse flies]] | ||
− | **Trypanosomes pass | + | **Trypanosomes pass forward to the salivary glands where they transform into the infective stage |
− | ** | + | **Inoculated with saliva when [[Biting Flies#Glossinidae|Tsetse fly]] next feeds on a host |
*Stercorarian trypanosomes are transmitted by triatomid bugs, [[Biting Flies#Tabanidae|tabanids]] and [[Biting Flies#Melophagus spp.|keds]] | *Stercorarian trypanosomes are transmitted by triatomid bugs, [[Biting Flies#Tabanidae|tabanids]] and [[Biting Flies#Melophagus spp.|keds]] | ||
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***Occurs in South America | ***Occurs in South America | ||
***Infects armadillos, possums and humans | ***Infects armadillos, possums and humans | ||
− | ***Causes Chagas Disease | + | ***Causes Chagas' Disease |
**Transmitted by a triatomid (kissing) bug | **Transmitted by a triatomid (kissing) bug | ||
**Chronic infections are often fatal causing heart failure | **Chronic infections are often fatal causing heart failure | ||
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**Progressive loss of body condition | **Progressive loss of body condition | ||
**Fever and appetite loss occur during parasite peaks | **Fever and appetite loss occur during parasite peaks | ||
− | **Chronic disease | + | **Chronic disease usually terminates in death of the animal if untreated |
**Can cause abortion, infertility and decreased growth in herds | **Can cause abortion, infertility and decreased growth in herds | ||
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*In dogs and cats: | *In dogs and cats: | ||
**''T. brucei'' and ''T. congolese'' | **''T. brucei'' and ''T. congolese'' | ||
− | ** | + | **Acute infections |
**Fever, anaemia, myocarditis, corneal opacity | **Fever, anaemia, myocarditis, corneal opacity | ||
**Occasionally neurological signs present, such as increased aggression, ataxia and convulsions | **Occasionally neurological signs present, such as increased aggression, ataxia and convulsions | ||
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*Host response | *Host response | ||
− | **Trypanotolerant wild animals remain parasitaemic for | + | **Trypanotolerant wild animals remain parasitaemic for prolonged periods without showing clinical signs of disease |
***Cause lasting reservoirs of infection | ***Cause lasting reservoirs of infection | ||
**Most domestic livestock are susceptible to trypanosomosis | **Most domestic livestock are susceptible to trypanosomosis | ||
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*Prophylactic drug treatment | *Prophylactic drug treatment | ||
− | **Change drug group periodically to decrease the chances of resistance | + | **Change drug group periodically to decrease the chances of resistance occurring |
**May lead to protective immunity but livestock will still be susceptible to heterologous challenges | **May lead to protective immunity but livestock will still be susceptible to heterologous challenges | ||
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**''T. evansi'' in Asia | **''T. evansi'' in Asia | ||
− | * | + | *Venereally transmitted |
**E.g. Dourine | **E.g. Dourine | ||
***Transmitted by ''T. equiperdum'' | ***Transmitted by ''T. equiperdum'' | ||
− | ***Causes genital and abdominal oedema, | + | ***Causes genital and abdominal oedema, emaciation and CNS signs |
***Affects horses and donkeys in Africa, Asia, Central and South America | ***Affects horses and donkeys in Africa, Asia, Central and South America | ||
Revision as of 11:41, 7 January 2009
This article has been peer reviewed but is awaiting expert review. If you would like to help with this, please see more information about expert reviewing. |
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Leishmania
- Leishmania spp. are intracellular parasites of macrophages
- Are closely related to Trypanosoma spp.
- Cause diseases in humans, dogs and wild animals
- Present in southern Europe, Africa, Asia and south America
- Can cause both cutaneous and visceral diseases
Recognition
- Ovoid shaped
- Possesses a rod-shaped kinetoplast
- Has a rudimentary flagellum which does not project beyond the cell margin
- After the amastigote has transformed into a promastigote inside the sand fly, the kinetoplast is situated in the posterior of the body
Life Cycle
- Transmitted by blood sucking sand flies
- Phlebotomus spp. in the Old World
- Lutzomyia spp. in the New World
- The amastigote (morphological form) is found in vertebrate macrophages
- Multiplies and migrates to insect proboscis
- Inoculated during feeding
- Can be transmitted percutaneously if sand fly crushed on skin
- Invades macrophages and reverts to amastigote
- Multiplies by binary fission
Pathogenesis
- Infection of vertebrate host
- Produces foci of proliferating Leishmania-infected macrophages in skin (cutaneous) or internal organs (visceral)
- Very long incubation period
- Months to years
- Many infected dogs are asymptomatic
- Visceral form causes chronic wasting condition
- Generalised eczema
- Loss of hair around eyes producing 'spectacle' effect
- Intermittent fever
- Generalised lymphadenopathy
- Generalised eczema
- Long periods of remission followed by recurrence of clinical signs is not uncommon in infections
- Involved in skin infections
Epidemiology
- Disease dependent on sand fly vectors
- E.g. Common in dogs around the Mediterranean coast, foci around southern Europe and around Madrid
- Reservoirs of infection
- E.g. Wild animals such as rodents and stray dogs
- Mechanisms of transmission
- sand fly bite
- Rarely through direct contact
- Leishmaniasis in British dogs
- Susceptible to infection if exposed whilst abroad in endemic areas as have no immunity
- No sand flies in Britain but dogs have become infected whilst in contact with infected imported animals
Diagnosis
- Demonstrate Leishmania organisms
- In skin scraping or smears
- In joint fluid, lymph node or bone marrow biopsies
Treatment and Control
- Chemotherapy
- Prolonged treatment, expensive, suppresses infection
- Does not cure infection
- Prevent sand flies biting
- Collars, sprays containing insecticide with repellent effect
- Destruction of infected and stray dogs
- Sand flies biting infected dogs may spread the disease to other dogs, humans and wildlife
- There is a slight possibility of transmission to humans by direct contact
Trypanosoma
- Protozoal parasites found in the blood and tissues of vertebrates
- Worldwide distribution
- Causes sleeping sickness in humans
- Particularly seen in sub-Saharan Africa
- Affects cattle production
- Causes Nagana (Wasting disease)
- Divided into two groups depending on the mode of development in the insect vector
- Salivarian
- Multiply in the foregut and proboscis
- Transmitted via inoculation during feeding
- Transmitted by Tsetse flies
- Also known as anterior station development
- Stercorarian
- Multiply in the hindgut
- Infective form migrates to the rectum
- Transmitted via contamination of wounds with insect faeces
- Also known as posterior station development
- Salivarian
- All Trypansomes except for T. equiperdum have arthropod vectors
- T. equiperdum is a venereally transmitted disease
- Non-cyclical transmission can also occur
- Mechanical transmission
- Transferred by interrupted feeding from one host to another
- Usually transmitted by biting flies, e.g. Tabanidae and Stomoxys
Recognition
- Elongated, spindle shaped protozoa
- Between 8 and 39 μm in length
- Flagellate
- Flagellum runs the length of the body attached to the pellicle which forms an undulating membrane
- Kinetoplast present which contains the DNA of the single mitochondrion
Life Cycle
- Undergo morphological transformations in intermediate host before becoming infective for the next host
- Blood-sucking flies ingest trypanosomes whilst taking a blood meal from an infected animal
- Trypanosomes multiply first in the gut of the fly
- Salivarian trypanosomes are transmitted by Tsetse flies
- Trypanosomes pass forward to the salivary glands where they transform into the infective stage
- Inoculated with saliva when Tsetse fly next feeds on a host
- Stercorarian trypanosomes are transmitted by triatomid bugs, tabanids and keds
- Trypanosomes pass back to the rectum
- Next host is infected when skin wounds are contaminated with infected insect faeces
Pathogenesis
- Salivarian
- Causes wasting disease in cattle (nagana)
- Sleeping sickness in humans
- Stercorarian
- T. cruzi most important in veterinary medicine
- Occurs in South America
- Infects armadillos, possums and humans
- Causes Chagas' Disease
- Transmitted by a triatomid (kissing) bug
- Chronic infections are often fatal causing heart failure
- Non-pathogenic species are transmitted by tabanids and keds
- T. theileria and T. melophagium
- T. cruzi most important in veterinary medicine
- Enlarged lymph nodes and spleen
- Causes lymphoid exhaustion
- Associated with plasma cell hypertrophy and hypergammaglobulinaemia
- Due to an increase in IgM
- With infections of increased duration, the lymph nodes and spleen shrink due to exhaustion of their cellular elements
- Anaemia
- Red blood cells are removed from circulation (haemolytic)
- Is a cardinal feature of the disease
- Degeneration and inflammation of multiple organs
- E.g. Skeletal muscle, myocardium and CNS
Clinical Signs
- In ruminants:
- Anaemia
- Enlargement of the lymph nodes
- Progressive loss of body condition
- Fever and appetite loss occur during parasite peaks
- Chronic disease usually terminates in death of the animal if untreated
- Can cause abortion, infertility and decreased growth in herds
- In horses:
- Acute or chronic infections of T. brucei
- Oedema of the limbs and genitalia
- In pigs:
- T. congolense infections are mild or chronic
- T. simiae infections are hyperacute usually leading to death from pyrexia in a few days
- In dogs and cats:
- T. brucei and T. congolese
- Acute infections
- Fever, anaemia, myocarditis, corneal opacity
- Occasionally neurological signs present, such as increased aggression, ataxia and convulsions
Epidemiology
- Vector distribution
- Tsetse flies found in riverine, savannah and forest habitats
- Up to 20% flies infected
- Flies infected for life
- Parasite virulence
- Some parasitaemic animals survive for long periods of time
- E.g. T. brucei and T. congolense
- Increases the opportunity for infection of flies
- Some trypanosomes kill their host in 1-2 weeks
- E.g. T. vivax
- Decreases the chances of fly infection
- Trypanosomes avoid host immune defences by altering glycoprotein coat (surface antigen) before host antibody response
- Antigenic variation can occur many times over several months causes relapsing parasitaemia
- Some parasitaemic animals survive for long periods of time
- Host response
- Trypanotolerant wild animals remain parasitaemic for prolonged periods without showing clinical signs of disease
- Cause lasting reservoirs of infection
- Most domestic livestock are susceptible to trypanosomosis
- Some local breeds of sheep, goats and cattle are trypanotolerant
- E.g. Bos indicus
- Trypanotolerant wild animals remain parasitaemic for prolonged periods without showing clinical signs of disease
Diagnosis
- Demonstrate trypanosomes in blood
- Giemsa stained smears
- Fresh blood films
- Motile trypanosomes
- Haematocrit tube
- Motile trypanosomes at the plasma/buffy coat interface
Control
- Tsetse fly control
- Spraying and trapping
- Prophylactic drug treatment
- Change drug group periodically to decrease the chances of resistance occurring
- May lead to protective immunity but livestock will still be susceptible to heterologous challenges
- Barrier fences and buffer zones
- Separate livestock and wild animals
- Trypanotolerant livestock
Other trypanosomes
- Mechanically transmitted by biting flies
- E.g. Surra affecting horses and camels in North Africa, Asia and South America
- T. equinum in South America
- T. evansi in Asia
- Venereally transmitted
- E.g. Dourine
- Transmitted by T. equiperdum
- Causes genital and abdominal oedema, emaciation and CNS signs
- Affects horses and donkeys in Africa, Asia, Central and South America
- E.g. Dourine
- Non-pathogenic species occur in the UK
- In sheep caused by T. melophagium
- In cattle caused by T. theileri