Alena Zíková
azikova@paru.cas.cz
Institute of Parasitology, Biology Centre
Ceske Budějovice
Plasmodium falciparum MSP1 - The Native Antigen Company Výsledek obrázku pro trypanosoma
Buněčné biologie prvoků
Parazitičtí prvoci

Parasitos = parasite of the classical Greek antiquity was a tolerated, but not invited co-eater
during a guest meal.
Parasites
Parasites are organisms that live in or on another organism (host) and derive nutrients at the
expense of the host.
Výsledek obrázku pro parasitisms Výsledek obrázku pro tasemnice Výsledek obrázku pro
trypanosoma
unicellular organisms (protists)
helminths
(worms)
arthropods

The malaria-infected red blood cell. 3D illustration showing malaria parasite Plasmodium ovale in
the stage of schizont Stock Illustration | Adobe Stock Stock fotografie Kožní Leishmaniáza Vřed A
Detailní Pohled Na Leishmania Amastigotes – stáhnout obrázek nyní - iStock 524 Trypanosoma Images,
Stock Photos, 3D objects, & Vectors | Shutterstock
Plasmodium
Leishmania
Trypanosoma
Parasitic Protozoans Toxoplasma Gondii Stock Photo - Download Image Now - Toxoplasma Gondii,
Parasitic, Abscess - iStock
Toxoplasma
Parasitos = parasite of the classical Greek antiquity was a tolerated, but not invited co-eater
during a guest meal.
Parasites
Parasites are organisms that live in or on another organism (host) and derive nutrients at the
expense of the host.

The malaria-infected red blood cell. 3D illustration showing malaria parasite Plasmodium ovale in
the stage of schizont Stock Illustration | Adobe Stock Stock fotografie Kožní Leishmaniáza Vřed A
Detailní Pohled Na Leishmania Amastigotes – stáhnout obrázek nyní - iStock 524 Trypanosoma Images,
Stock Photos, 3D objects, & Vectors | Shutterstock
Plasmodium
Leishmania
Trypanosoma
Parasitic Protozoans Toxoplasma Gondii Stock Photo - Download Image Now - Toxoplasma Gondii,
Parasitic, Abscess - iStock
Toxoplasma
Parasites
•Global health impact: Parasitic diseases affect millions worldwide.
•
•Economic implications: Agricultural and livestock parasitism.
•
•Scientific discovery: Unveiling unique features and pathways.

Important Human Parasites of the Tropics · Frontiers for Young Minds
Overview of Parasitology
The Relevance of Parasitology
Stock fotografie Kožní Leishmaniáza Vřed A Detailní Pohled Na Leishmania Amastigotes – stáhnout
obrázek nyní - iStock Stock ilustrace „3d Illustration Schistosoma Adult Haematobium Adult“
1653073225 | Shutterstock

Disease Burden in DALYs
* World Health Report estimates, 2012
Disease
Health burden (millions DALYs)a
Deaths (per annum)
Viral
HIV/AIDS*
89
1.1 millions
Rabies
1.46
26,400
Dengue
0.83
14,700
Bacterial
Tuberculosis
36
1.6 millions
Trachoma
0.33
0
Protozoal
Malaria*
42
670, 000
Sleeping sickness
1.6
13,000
Chagas disease
0.6
13,000
Leishmaniasis
3.32
59,000
Helminthic
Schistosomiasis
3.31
15,000
Onchorcerciasis
1.0
0
Filariasis
2.78
0
Soiled-transmitted
5.19
2,700
Disease burden

Disease Burden in DALYs
The burden of disease and what it means in England – UK Health Security Agency
Disease Burden in DALYs
Disease burden in DALYs
DALYs – disability adjusted life years

Communicable vs non-communicavle diseases
•NEGLECTED TROPICAL DISEASES

https://ourworldindata.org/burden-of-disease

http://www.ipsolutionsblog.com/wp-content/uploads/2012/06/NTD-infographic-blog-size.PNG



Neglected Tropical Diseases



Parasites in focus
Parasites in focus
Garcia-Lopez & Moreira 2023

The Original Supergroups – and Where Are They Now?
Five to six supergroups were originally proposed, depending on whether Opisthokonta and Amoebozoa
were unified in the larger group unikonts. The name unikonts (based on a now-discarded hypothesis
of a uniflagellated ancestor) was later replaced by Amorphea.
The six supergroups version corresponded to the following.
›Opisthokonta includes animals, fungi, and several protist lineages that are most closely related
to either animals or fungi. Opisthokonta remains a robust clade in modern phylogenies; however, it
is nested within at least two larger taxa, Amorphea and Obazoa, that are frequently treated as
supergroups instead.
›Amoebozoa is also still a robust group, but now is often regarded as a member of the supergroup
Amorphea. Amoebozoa includes free-living amoeboid forms with lobose pseudopodia (e.g., Amoeba) but
also more filose amoebae, some flagellates, and various slime molds.
›Excavata was originally proposed based on a distinctive morphology, namely a particular feeding
groove form and associated cytoskeleton system, found in many enigmatic flagellated protists.
Phylogenetics and phylogenomics defined three monophyletic subgroups – Discoba, Metamonada, and
malawimonads – but have not consistently placed them together as a single clade. The name is now
usually restricted to a Discoba–Metamonada clade (quite possibly artificial; see main text) or
regarded as referring to a paraphyletic group.
›Archaeplastida are distinguished by the presence of primary plastids – the photosynthetic
organelles deriving directly from cyanobacteria by endosymbiosis. The three main groups with
primary plastids are the green algae and land plants, red algae (and likely their recently
discovered relative Rhodelphis), and glaucophyte algae. Today, Archaeplastida is generally still
considered a supergroup, although most phylogenomic analyses do not strongly support its monophyly
(i.e., all three host lineages forming a single clade to the exclusion of other supergroups).
›Chromalveolata contained groups with red alga-derived secondary plastids (i.e., Alveolata,
Stramenopila, Haptophyta, and Cryptophyta). This group was based on the assumption that these
plastids were acquired once in a common ancestor, which was supported by plastid evidence but never
strongly from the host perspective. Chromalveolata has been shown to be polyphyletic, with
Alveolata and Stramenopila belonging to Sar (in TSAR), Haptophyta in Haptista, and Cryptophyta in
Cryptista.
›Rhizaria was the latest addition at the time the supergroup model was proposed. It includes a wide
diversity of amoebae (e.g., foraminiferans, the radiolarians, filose testate amoebae), flagellates,
various parasites, and the chlorarachniophyte algae. In contrast to all other original supergroups,
which were at least partly distinguished by morphological characters, Rhizaria was inferred more or
less exclusively using molecular phylogenetics. It is now part of Sar (in TSAR) along with
Alveolata and Stramenopila.

Model Organisms in Parasitology
Model organisms serve as valuable tools for understanding the biology, genetics, and pathogenic
mechanisms of parasites.
›Genetic Manipulation: Ease of genetic modification facilitates the study of specific genes and
their functions.
›
›Short Reproductive Cycles: Allows for quick generation of experimental data and observations.
›
›In Vitro Cultivation: Facilitates controlled experimentation and observation.
›
›Conservation of Biological Processes: Many biological processes are conserved across species,
allowing extrapolation of findings.
The malaria-infected red blood cell. 3D illustration showing malaria parasite Plasmodium ovale in
the stage of schizont Stock Illustration | Adobe Stock Stock fotografie Kožní Leishmaniáza Vřed A
Detailní Pohled Na Leishmania Amastigotes – stáhnout obrázek nyní - iStock 524 Trypanosoma Images,
Stock Photos, 3D objects, & Vectors | Shutterstock
Plasmodium
Leishmania
Trypanosoma
Parasitic Protozoans Toxoplasma Gondii Stock Photo - Download Image Now - Toxoplasma Gondii,
Parasitic, Abscess - iStock
Toxoplasma

Model Organisms in Parasitology
Model organisms serve as valuable tools for understanding the biology, genetics, and pathogenic
mechanisms of parasites.
›Genetic Manipulation: Ease of genetic modification facilitates the study of specific genes and
their functions.
›
›Short Reproductive Cycles: Allows for quick generation of experimental data and observations.
›
›In Vitro Cultivation: Facilitates controlled experimentation and observation.
›
›Conservation of Biological Processes: Many biological processes are conserved across species,
allowing extrapolation of findings.
The malaria-infected red blood cell. 3D illustration showing malaria parasite Plasmodium ovale in
the stage of schizont Stock Illustration | Adobe Stock Stock fotografie Kožní Leishmaniáza Vřed A
Detailní Pohled Na Leishmania Amastigotes – stáhnout obrázek nyní - iStock 524 Trypanosoma Images,
Stock Photos, 3D objects, & Vectors | Shutterstock
Plasmodium
Leishmania
Trypanosoma
Parasitic Protozoans Toxoplasma Gondii Stock Photo - Download Image Now - Toxoplasma Gondii,
Parasitic, Abscess - iStock
Toxoplasma

SAR CLADE: ALVEOLATA (meaning "with cavities„)
presence of cortical (outer-region) alveoli (sacs)
Výsledek obrázku pro alveolata alveoli
flattened vesicles (sacs) packed into a continuous layer just under the membrane and supporting it,
typically forming a flexible pellicle
Výsledek obrázku pro alveolata alveoli
Paramecium putrinum

SAR CLADE: ALVEOLATA (meaning "with cavities„)
        alveoli → ALVEOLIN
Výsledek obrázku pro GOULD ET AL ALVEOLIN Výsledek obrázku pro GOULD ET AL ALVEOLIN Výsledek
obrázku pro GOULD ET AL ALVEOLIN
Gould et al., 2008

APICOMPLEXA



APICOMPLEXA - VÝTRUSOVCI
a group of structures and organelles
consists of structural components and secretory organelles
required for invasion of host cells during the parasitic stages of the Apicomplexan life cycle
figure1 Výsledek obrázku pro apical complex electron microscopy a) Schematic enlarged view of the
apical complex cytoskeleton, showing... | Download Scientific Diagram
Apical complex

APICOMPLEXA
Apicoplast
a derived non-photosynthetic plastid
originated by secondary endosymbiosis (4 membranes)
has its own genome
 essential metabolic pathways
drug target
Toxoplasma gondii
Seeber et al., 2014

Toxoplasma gondii
›coccidia
›found worldwide
›capable of infecting virtually all warm-blooded animals (incl. birds)
›but felids such as domestic cats are the only known definitive hosts in which the parasite may
undergo sexual reproduction
›one of the most common parasites in developed countries
›
Toxoplasmosis
›significant health consequences, particularly in immunocompromised individuals and pregnant women
(risk of congenital toxoplasmosis).
›serological studies estimate that 30–50% of the global population has been exposed
›France 84% prevalence, CZ 30% prevalence
Manipulation theory
•Rats
•Mice
•Human (Ig Nobel prize to Jaroslav Flegr)

Toxoplasma gondii
https://cmr.asm.org/content/cmr/25/2/264/F3.large.jpg?width=800&height=600&carousel=1
https://cmr.asm.org/content/cmr/25/2/264/F3.large.jpg?width=800&height=600&carousel=1
unsporulated and sporulated oocysts
SouvisejÃcà obrázek Výsledek obrázku pro tachyzoites toxoplasma gondii
tachyzoites → rapid growth and replication
SouvisejÃcà obrázek SouvisejÃcà obrázek
bradyzoite → sessile, slow-growing form
oocyst → mature oocyst containing sporozoites

Toxoplasma gondii as model organism
›the best model system to study the biology of the Apicomplexa
›
›life cycle can be completed in vitro ← controlled experiments to investigate various biology
aspects ease of in vitro culture

›the mouse animal model is well-established
›readily amenable to genetic manipulation in the laboratory
›the high efficiency of transient and stable transfection
›gene knockout, gene tagging, and transgenic expression
›the availability of many cell markers
›advanced microscopic techniques
›functions of specific genes and pathways involved in parasite biology
›heterologous expression of apicomplexan proteins in T. gondii
›
›
›molecular mechanisms of host-parasite interactions, host cell invasion, and immune evasion
strategies
›(← intracellular parasitsm)
›
›mechanisms of drug resistance, the biology of the apicoplast
›
›interactions with different hosts and the resulting pathogenesis (← wide host range)
https://jcs.biologists.org/content/joces/121/9/1559/F4.large.jpg?width=800&height=600&carousel=1
IMC = the inner membrane complex

A Genome-wide CRISPR Screen in Toxoplasma Identifies Essential Apicomplexan Genes
Sidik et al., 2016. Cell


Lourido talk on basics of Toxoplasma



https://www.youtube.com/watch?v=wML68MA--Kw

https://www.youtube.com/watch?v=wML68MA--Kw

https://www.youtube.com/watch?v=YGTe6Kk9w8E

https://www.youtube.com/watch?v=YGTe6Kk9w8E

APICOMPLEXA



›Hematozoa
›many species were discovered in various hosts and classified
›mammals ~ 50 species; birds ~ 40 species; reptiles ~ 60 species
›five species that regularly infect human
›P. vivax, P. falciparum, P. malariae, P. ovale, and P. knowlesi
MALARIA („mal aria“ = špatný vzduch)
300 mil infections/year
2.5 billions in endemic area
Plasmodium
P. falciparum
›„falx“ = „srp“
›also called malignant or falciparum malaria
›the most dangerous form of malaria
›the highest rates of complications and mortality
›as of 2006 - an estimated 247 million human malarial infections (98% in Africa)
›almost every malarial death is caused by P. falciparum
›
›disease: malignant tertian malaria (36-48h), „tropicana“
https://upload.wikimedia.org/wikipedia/en/thumb/7/75/Fever_Patterns_v1.2.svg/1920px-Fever_Patterns_
v1.2.svg.png
SouvisejÃcà obrázek Výsledek obrázku pro samec symbol SouvisejÃcà obrázek Výsledek obrázku
pro sporozoite plasmodium
ACONOIDEA
= „zoit“ lacks conoid

Plasmodium spp. life cycle
Výsledek obrázku pro plasmodium mosquito gut oocysts








P. falciparum
›in vitro cultivation
›challenging mosquito infection („in vitro feeding“)
›
›genetic manipulation has historically been challenging
›the availability of many cell markers
›advanced microscopic techniques
›
P. berghei
›a popular model organism for the study of human malaria
›can be genetically manipulated more easily than the species which infect humans
›the mouse animal model is well-established
›experimental cerebral malaria
›easy infection of mosquitoes incl. transmission
›
›development and screening of anti-malarial drugs
›development of an effective vaccine against malaria
Plasmodium as model organism
https://upload.wikimedia.org/wikipedia/en/7/76/Berghei_03.png
https://upload.wikimedia.org/wikipedia/commons/8/84/Liver_stage_malaria_parasite.jpg
A liver cell with P. berghei expressing mCherry (red).
P. berghei expression of bioluminescent reporter protein Luciferase

Overview of Parasitology
Classification of Parasites
Parasites in focus
Garcia-Lopez & Moreira 2023

The Original Supergroups – and Where Are They Now?
Five to six supergroups were originally proposed, depending on whether Opisthokonta and Amoebozoa
were unified in the larger group unikonts. The name unikonts (based on a now-discarded hypothesis
of a uniflagellated ancestor) was later replaced by Amorphea.
The six supergroups version corresponded to the following.
›Opisthokonta includes animals, fungi, and several protist lineages that are most closely related
to either animals or fungi. Opisthokonta remains a robust clade in modern phylogenies; however, it
is nested within at least two larger taxa, Amorphea and Obazoa, that are frequently treated as
supergroups instead.
›Amoebozoa is also still a robust group, but now is often regarded as a member of the supergroup
Amorphea. Amoebozoa includes free-living amoeboid forms with lobose pseudopodia (e.g., Amoeba) but
also more filose amoebae, some flagellates, and various slime molds.
›Excavata was originally proposed based on a distinctive morphology, namely a particular feeding
groove form and associated cytoskeleton system, found in many enigmatic flagellated protists.
Phylogenetics and phylogenomics defined three monophyletic subgroups – Discoba, Metamonada, and
malawimonads – but have not consistently placed them together as a single clade. The name is now
usually restricted to a Discoba–Metamonada clade (quite possibly artificial; see main text) or
regarded as referring to a paraphyletic group.
›Archaeplastida are distinguished by the presence of primary plastids – the photosynthetic
organelles deriving directly from cyanobacteria by endosymbiosis. The three main groups with
primary plastids are the green algae and land plants, red algae (and likely their recently
discovered relative Rhodelphis), and glaucophyte algae. Today, Archaeplastida is generally still
considered a supergroup, although most phylogenomic analyses do not strongly support its monophyly
(i.e., all three host lineages forming a single clade to the exclusion of other supergroups).
›Chromalveolata contained groups with red alga-derived secondary plastids (i.e., Alveolata,
Stramenopila, Haptophyta, and Cryptophyta). This group was based on the assumption that these
plastids were acquired once in a common ancestor, which was supported by plastid evidence but never
strongly from the host perspective. Chromalveolata has been shown to be polyphyletic, with
Alveolata and Stramenopila belonging to Sar (in TSAR), Haptophyta in Haptista, and Cryptophyta in
Cryptista.
›Rhizaria was the latest addition at the time the supergroup model was proposed. It includes a wide
diversity of amoebae (e.g., foraminiferans, the radiolarians, filose testate amoebae), flagellates,
various parasites, and the chlorarachniophyte algae. In contrast to all other original supergroups,
which were at least partly distinguished by morphological characters, Rhizaria was inferred more or
less exclusively using molecular phylogenetics. It is now part of Sar (in TSAR) along with
Alveolata and Stramenopila.

„EXCAVATA“
DISCOBA
METAMONADA
Euglenozoa
Heterlobosea
Jakobea
Preaxostyla
Fornicata
Parabasala
parasites, one group with plastids (chloroplast)
alternate between flagellate and ameboid forms
free living
free-living or living in the hindguts of insects
mostly symbiotes and parasites of animals
generally intestinal commensals of insects, some human pathogens
SouvisejÃcà obrázek SouvisejÃcà obrázek SouvisejÃcà obrázek

„EXCAVATA“
DISCOBA
METAMONADA
Euglenozoa
Heterlobosea
Jakobea
Preaxostyla
Fornicata
Parabasala
alternate between flagellate and ameboid forms
free living
free-living or living in the hindguts of insects
mostly symbiotes and parasites of animals
generally intestinal commensals of insects, some human pathogens
SouvisejÃcà obrázek SouvisejÃcà obrázek SouvisejÃcà obrázek

Milíčovský rybník | Pražská příroda Sound waves of undersea earthquakes reveal changes in ocean
warming
Diplonemea
Kinetoplastea
Free-living, parasitic
Free-living (in most cases)
Free-living (auto- and heterotrophs)
Trypanosoma brucei, T. congolense, T. vivax, causative agent of African Trypanosomiases
T. cruzi, Chagas disease
Leishmania spp., causative agent of leishmaniases
Diplonema papillatum
D. japonicum
Euglena gracilis
Euglenids
A picture containing fabric Description automatically generated Background pattern Description
automatically generated
Euglenozoa

each causing a distinct disease and possessing unique genetic marker(s)

Kinetoplastea
Free-living, parasitic
Trypanosoma brucei, T. congolense, T. vivax, causative agent of African Trypanosomiases
T. cruzi, Chagas disease
Leishmania spp., causative agent of leishmaniases
A picture containing fabric Description automatically generated Background pattern Description
automatically generated
›the presence of an organelle with a large massed DNA called kinetoplast
›
›
›glycosomes
›
›
›acidocalcisoms
›
Ultrastructure of Trypanosoma cruzi and its interaction with host ...
Arrow indicates the nucleus and arrowhead indicates the kinetoplast of T. brucei.
Kinetoplastida, Trypanosomatida

each causing a distinct disease and possessing unique genetic marker(s)

African Trypanosomes
Adapted from Lukeš et al., 2022. Trends in Parasitol.
Trypanosoma brucei (T. b. brucei, T. b. gambiense, T. b. rhodesiense, T. b. evansi, T. b.
equiperdum)
T. congolense, T. vivax
-
-Human African Trypanosomiasis (HAT)
-36 African states
-50 millions in affected areas
-Always lethal if untreated
-
-Animal African Trypanosomiasis (AAT)
-Direct loos of livestock products
-Loss of crop productivity due to loss
      of the animals draught power
Text Description automatically generated with low confidence

T. brucei life cycle



Trypanosome transmission through tsetse. | Download Scientific Diagram
T. brucei life cycle – insect forms development


Trypanosoma brucei as model organism
›a model organism for the kinetoplastids
›in vitro culture of both bloodstream and procyclic stages
›the mouse animal model is well-established
›infection in rodents provide valuable platforms for studying
disease pathogenesis, immune responses, and drug efficacy.
›well-established tools for genetic manipulation
›
›
›unusual nuclear architecture compared to those of other eukaryotic model organisms
›genome organization and nuclear gene expression regulation
›
›
›kinetoplast structure: minicircles and maxicircles
›RNA editing
›
›antigenic variation
›
›glycosomes → dealing changes in nutrient availability

Trypanosoma cruzi
T. cruzi
6 definovaných skupin, různé kmeny
Zoonóza
Přenášena plošticemi rodu Triatominae (kissing bugs)
Geographical distribution
Chagasova choroba
16-18 mil infikovaných
90 mil žijících v rizikových oblastech
Akutní a chronická faze (kardio-, gastrointestinální komplikace)
 úmrtí až v 10%
Treatment – benznidazole, nifurtimox

https://www.google.com/search?sca_esv=977e94292b20825f&sxsrf=ACQVn0_C7_WU9ZA3F-gYj9bMvdkRWzttNw:171
3780308355&q=trypanosoma+cruzi+life+cycle&tbm=vid&source=lnms&prmd=ivnbz&sa=X&sqi=2&ved=2ahUKEwjZpo
KUydWFAxV93AIHHf6XD58Q0pQJegQICBAB&biw=2133&bih=1050&dpr=0.9#fpstate=ive&vld=cid:d2bde252,vid:_mZIz
MU10OY,st:0
https://www.google.com/search?sca_esv=977e94292b20825f&sxsrf=ACQVn0_C7_WU9ZA3F-gYj9bMvdkRWzttNw:171
3780308355&q=trypanosoma+cruzi+life+cycle&tbm=vid&source=lnms&prmd=ivnbz&sa=X&sqi=2&ved=2ahUKEwjZpo
KUydWFAxV93AIHHf6XD58Q0pQJegQICBAB&biw=2133&bih=1050&dpr=0.9#fpstate=ive&vld=cid:f65593c5,vid:1ais6
9H0li8,st:0

T. cruzi trypomastigote
T. cruzi amastigote
MAMMMALIAN HOST
INSECT VECTOR
Trypanosoma cruzi life cycle

Schematic illustration of T. cruzi life cycle. (1) During the blood meal, the triatomine bites a
mammalian host and ingests the trypomastigotes present in the bloodstream of the mammalian host.
The metacyclic trypomastigotes (2) differentiate into epimastigotes and some spheromastigotes (3).
(4) In the midgut, the epimastigotes multiply by binary fission, and (5) transform into metacyclic
trypomastigotes in the hindgut. (6) The metacyclic trypomastigotes are released in feces near the
site of the bite wound when the insect feeds on a host. After entering the host through the wound
or intact mucosal membranes, (7) the metacyclic parasites infects macrophages (8) and inside the
cell, they differentiate into amastigote (9). (10) After releasing 3
the parasitophorous vacuole, (11) the amastigote multiplies in the cytoplasm. (12) Amastigotes
transform into trypomastigotes and (13) they burst out of the cell. (14) Amastigotes and
trypomastigotes forms. (15) Trypomastigotes (a) and (b) amastigotes infect macrophages. Adapted and
reproduced from Teixeira et al., 2012
Life cycle of Trypanosoma cruzi in the gut of the insect vector. After feeding on blood containing
trypomastigotes (TRY), the parasites transform in the stomach (a) into epimastigotes (EPI) and some
amastigotes and spheromastigotes
(SPH). In the small intestine (b) the parasites multiply and adhere to the perimicrovillar
membranes of the intestinal cells. In the rectum (c) the
epimastigotes multiply intensively, attach to the rectal wall and transform to metacyclic
trypomastigotes which are eliminated with feces and urine (stages of T. cruzi from Ref. [10]).

Trypanosoma cruzi life cycle

Schematic illustration of T. cruzi life cycle. (1) During the blood meal, the triatomine bites a
mammalian host and ingests the trypomastigotes present in the bloodstream of the mammalian host.
The metacyclic trypomastigotes (2) differentiate into epimastigotes and some spheromastigotes (3).
(4) In the midgut, the epimastigotes multiply by binary fission, and (5) transform into metacyclic
trypomastigotes in the hindgut. (6) The metacyclic trypomastigotes are released in feces near the
site of the bite wound when the insect feeds on a host. After entering the host through the wound
or intact mucosal membranes, (7) the metacyclic parasites infects macrophages (8) and inside the
cell, they differentiate into amastigote (9). (10) After releasing 3
the parasitophorous vacuole, (11) the amastigote multiplies in the cytoplasm. (12) Amastigotes
transform into trypomastigotes and (13) they burst out of the cell. (14) Amastigotes and
trypomastigotes forms. (15) Trypomastigotes (a) and (b) amastigotes infect macrophages. Adapted and
reproduced from Teixeira et al., 2012
Life cycle of Trypanosoma cruzi in the gut of the insect vector. After feeding on blood containing
trypomastigotes (TRY), the parasites transform in the stomach (a) into epimastigotes (EPI) and some
amastigotes and spheromastigotes
(SPH). In the small intestine (b) the parasites multiply and adhere to the perimicrovillar
membranes of the intestinal cells. In the rectum (c) the
epimastigotes multiply intensively, attach to the rectal wall and transform to metacyclic
trypomastigotes which are eliminated with feces and urine (stages of T. cruzi from Ref. [10]).

Trypanosoma cruzi life cycle
https://www.youtube.com/watch?v=1ais69H0li8


Trypanosoma cruzi life cycle
https://www.youtube.com/watch?v=_mZIzMU10OY


Trypanosoma cruzi as model organism
›in vitro culture → parasite biology, drug susceptibility, and host interactions
›the mouse animal model is established
›disease pathogenesis, immunopathology, and vaccine development
›host-parasite interactions, and drug resistance in Chagas disease
›well-established tools for genetic manipulation
›specific genes and pathways involved in parasite biology, virulence, and drug resistance
Transgenic Trypanosoma cruzi expressing GFP or DsRed. Left: mixed... | Download Scientific Diagram
Transgenic Trypanosoma cruzi expressing
GFP or DsRed

Leishmania spp.
Ilustrace „Cutaneous leishmaniasis ulcer and close-up view of Leishmania promastigotes, up, and
amastigotes infected human histiocyte cells, bottom , 3D illustration“ ze služby Stock | Adobe
Stock Leishmaniasis

WHO 2018 Coutaneous & visceral leishmania worldwide map WHO 2018 Coutaneous & visceral leishmania
worldwide map
Leishmaniasis

•Depending on the person infected, treatment may not be necessary.
•It can speed healing and prevent further complications.
•In this form of disease, the parasite enters the host through the nose, throat, and mouth.
•This can cause partial or complete destruction of the mucous membrane in those regions.
•Though this form of Leishmaniasis is known as the subset of Cutaneous Leishmaniasis, it is more
serious.

Leishmania spp. life cycle

Digenetic life cycle of Leishmania: (A) Inside the sandfly, amastigotes undergo several
non-infective stages before they finally differentiate into metacyclic promastigotes; (a)
amastigotes enter into the sandfly (vector), while it bites an infected mammal (host), (b)
amastigotes transform into replicative procyclic promastigotes (flagellated form) inside the fly
abdominal midgut, (c) Procyclic stage transforms into an elongated nectomonad promastigote that
attaches to the microvilli of the abdominal midgut through its flagella, (d) nectomonad then
differentiates into a replicative form (leptomonad promastigote), and migrates towards the thoracic
midgut, (e) leptomonad promastigotes can differentiate into either heptomonad promastigotes, or (f)
metacyclic promastigotes. The haptomonad promastigotes can attach to the stomodeal valve, (g)
during the second blood meal, a new replicative stage, known as retroleptomonad promastigote,
exists due to reverse metacyclogenesis, where they multiply rapidly and differentiate into
metacyclic promastogotes enhancing sandfly infectivity. (B) The metacyclic promastigote belongs to
the infective stage that is transmitted to the mammalian host when an infected sandfly bites; (a)
metacyclic promastigotes are taken up by phagocytic cells such as macrophages and neutrophils
present in the skin, (b) promastigotes are internalised into phagosomes (later, it transforms into
a parasitophorus vacuole), (c) promastigotes change into amastigotes inside the parasitophorus
vacuole and proliferate, (d) amastigotes burst out from the phagocytes, (e) amastigotes can enter
into another life cycle inside the sandfly when taken with the blood meal, or can re-infect fresh
phagocytes.

Leishmania as model organism
Experimental accessibility
›in vitro culture → parasite biology, drug susceptibility, and host interactions
›the mouse animal model is established → gene expression, pathogenesis
Genetic tractability
›relatively small genome that is genetically tractable
›genetic manipulation →  gene function and impact on parasitic biology.
Complex life cycle → mechanisms by which parasites adapt to different host environments
Drug resistance → studying mechanisms of drug resistance and identifying new drug targets
Immune evasion → various strategies to evade the host immune system → chronic infections
Comparative studies → comparative genomics between Leshmania and related parasites → evolution of
parasitic traits and host-parasite interactions
Assessing the efficiency of parasite inoculation. Imaging and quantifying bioluminescent Leishmania
parasites during infection with IVIS. Wild-type BALB/c mice were injected intradermally in the
lower right flank with HBSS (mock) or transgenic Leishmania i. chagasi L. i. chagasi
pIR1SAT-LUC(A). The mice were then analyzed with the IVIS imaging technology one hour after
inoculation. A) A black and white photograph of the mice was taken immediately before the
luminescent signal (light intensity) was measured. Red arrows point to the injection site on each
animal. B) The pseudo-color image of the luminescence was overlaid on the photograph. C) Regions of
interest (ROI) were selected (red circles) and the luminescence was quantified in each ROI. The
data represent the net luminescence of infected ROI minus the ROI of mock infected.
Aminophthalocyanine-Mediated Photodynamic Inactivation of Leishmania tropica | Antimicrobial Agents
and Chemotherapy