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Redox Paradox: The Contribution of Reactive Oxygen Species (ROS) in the Proliferation and Differentiation of Trypanosoma cruzi
quantitatively measure mitochondrial network features in
this phenomenon is accompanied by a marked time and
cells treated with E2 or the selective estrogen receptor-α
concentration dependent increase in ROS formation and the
and β modulators (SERMs) propylpyrazole triol (PPT) and
modulation of epimastigotes mitochondrial physiology in an
diarylpropionitrile (DPN), respectively. 48h treatment of
effort to increase ROS as a metabolic mechanism to
mouse C2C12 myoblasts with various concentrations of
maintain
either E2 or DPN, but not PPT, significantly modified
Conversely, the antioxidants reverse the heme-induced ROS
mitochondrial network morphology. Both E2 and DPN
and
approximately
mitochondrial
Following the cycle, when these forms are taken into the
networks as well as the number of branches per network,
hindgut of the triatomine they return to the non-replicative,
while PPT had no effect on these parameters. Similarly, both
infective form, the metacyclic trypomastigotes. During the
E2 and DPN significantly increased the mitochondrial
metacyclogenesis,
footprint, a measure of mitochondrial abundance, while PPT
increment of trypomastigotes. These data gives us the idea
failed to modulate this feature. These data indicate that ER-
of
doubled
the
number
of
epimastigote
dramatically
a
“shift”
survival
impair
proliferation.
epimastigotes
antioxidants
between
and
induce
proliferation
to
proliferation.
a
significant
differentiation
β agonists strongly promote mitochondrial fusion. Thus,
according to the influence of the redox status. Surprisingly,
these observations provide initial quantitative evidence of
when metacyclic trypomastigotes are released into the insect
beneficial
feces the infection is again favored by ROS since inhibitors
actions
of
SERMs
such
as
DPN
as
a
pharmacological tool for targeting mitochondrial fusion in
of Nox and antioxidants greatly decrease macrophage
pathological
deficient
infection. Moreover, while the parasite needs oxidants for its
certain
proliferation inside the vector, the opposite occurs during its
conditions
mitochondrial
network
characterized formation,
such
by as
neurodegenerative diseases and cancers.
development inside the vertebrate host. H2O2 diminishes amastigotes proliferation and increases the trypomastigote
DOI: 10.1016/j.freeradbiomed.2017.10.269
differentiation into amastigotes. Taken together, our data reveal a redox paradox in which ROS plays antagonistic roles along Trypanosoma cruzi life cycle demonstrating a high capacity to adapt to its habitats.
257
DOI: 10.1016/j.freeradbiomed.2017.10.270
Redox Paradox: The Contribution of Reactive Oxygen Species (ROS) in the Proliferation and Differentiation of
258
Trypanosoma cruzi Natalia Nogueira1, Francis Saraiva1, Jessica Oliveira1, Gustavo Laranja1, Elmo Almeida-Amaral2, Georgia Atella3, Marcus Oliveira , and Marcia Paes 3
1
1
University of State of Rio de Janeiro -UERJ, Brazil
2
IOC - FIOCRUZ, Brazil
3
Federal University of Rio de Janeiro - UFRJ, Brazil
Poldip2 is an Oxygen-sensitive Mitochondrial Protein that Controls Oxidative/glycolytic Metabolism Balance and Proteasome Activity Felipe Paredes1, Holly Williams1, and Alejandra San Martin1
Trypanosoma cruzi is a protozoan that causes Chagas disease
1
Emory University, USA
or American trypanosomiasis. The parasite has a heteroxenic biological cycle developing between a vertebrate host
The polymerase delta interacting protein 2 (Poldip2) is a
(mammal) and an invertebrate (insect vector). The first
nuclear-encoded
environment encountered by T. cruzi after the blood meal is
function.
the midgut of the insect, where large amounts of
under hypoxia and that its deficiency results in repressed
hemoglobin are degraded resulting in the release of huge
mitochondrial function and increased glycolytic activity.
concentrations of heme, a molecule known to increase the
However, the mechanisms responsible for this metabolic
formation of ROS. Heme induces T. cruzi proliferation, and
reprograming and its consequences are unknown. In this
SfRBM 2017
mitochondrial
protein
of
unknown
We recently reported that Poldip2 is repressed
173
this phenomenon is accompanied by a marked time and
cells treated with E2 or the selective estrogen receptor-α
concentration dependent increase in ROS formation and the
and β modulators (SERMs) propylpyrazole triol (PPT) and
modulation of epimastigotes mitochondrial physiology in an
diarylpropionitrile (DPN), respectively. 48h treatment of
effort to increase ROS as a metabolic mechanism to
mouse C2C12 myoblasts with various concentrations of
maintain
either E2 or DPN, but not PPT, significantly modified
Conversely, the antioxidants reverse the heme-induced ROS
mitochondrial network morphology. Both E2 and DPN
and
approximately
mitochondrial
Following the cycle, when these forms are taken into the
networks as well as the number of branches per network,
hindgut of the triatomine they return to the non-replicative,
while PPT had no effect on these parameters. Similarly, both
infective form, the metacyclic trypomastigotes. During the
E2 and DPN significantly increased the mitochondrial
metacyclogenesis,
footprint, a measure of mitochondrial abundance, while PPT
increment of trypomastigotes. These data gives us the idea
failed to modulate this feature. These data indicate that ER-
of
doubled
the
number
of
epimastigote
dramatically
a
“shift”
survival
impair
proliferation.
epimastigotes
antioxidants
between
and
induce
proliferation
to
proliferation.
a
significant
differentiation
β agonists strongly promote mitochondrial fusion. Thus,
according to the influence of the redox status. Surprisingly,
these observations provide initial quantitative evidence of
when metacyclic trypomastigotes are released into the insect
beneficial
feces the infection is again favored by ROS since inhibitors
actions
of
SERMs
such
as
DPN
as
a
pharmacological tool for targeting mitochondrial fusion in
of Nox and antioxidants greatly decrease macrophage
pathological
deficient
infection. Moreover, while the parasite needs oxidants for its
certain
proliferation inside the vector, the opposite occurs during its
conditions
mitochondrial
network
characterized formation,
such
by as
neurodegenerative diseases and cancers.
development inside the vertebrate host. H2O2 diminishes amastigotes proliferation and increases the trypomastigote
DOI: 10.1016/j.freeradbiomed.2017.10.269
differentiation into amastigotes. Taken together, our data reveal a redox paradox in which ROS plays antagonistic roles along Trypanosoma cruzi life cycle demonstrating a high capacity to adapt to its habitats.
257
DOI: 10.1016/j.freeradbiomed.2017.10.270
Redox Paradox: The Contribution of Reactive Oxygen Species (ROS) in the Proliferation and Differentiation of
258
Trypanosoma cruzi Natalia Nogueira1, Francis Saraiva1, Jessica Oliveira1, Gustavo Laranja1, Elmo Almeida-Amaral2, Georgia Atella3, Marcus Oliveira , and Marcia Paes 3
1
1
University of State of Rio de Janeiro -UERJ, Brazil
2
IOC - FIOCRUZ, Brazil
3
Federal University of Rio de Janeiro - UFRJ, Brazil
Poldip2 is an Oxygen-sensitive Mitochondrial Protein that Controls Oxidative/glycolytic Metabolism Balance and Proteasome Activity Felipe Paredes1, Holly Williams1, and Alejandra San Martin1
Trypanosoma cruzi is a protozoan that causes Chagas disease
1
Emory University, USA
or American trypanosomiasis. The parasite has a heteroxenic biological cycle developing between a vertebrate host
The polymerase delta interacting protein 2 (Poldip2) is a
(mammal) and an invertebrate (insect vector). The first
nuclear-encoded
environment encountered by T. cruzi after the blood meal is
function.
the midgut of the insect, where large amounts of
under hypoxia and that its deficiency results in repressed
hemoglobin are degraded resulting in the release of huge
mitochondrial function and increased glycolytic activity.
concentrations of heme, a molecule known to increase the
However, the mechanisms responsible for this metabolic
formation of ROS. Heme induces T. cruzi proliferation, and
reprograming and its consequences are unknown. In this
SfRBM 2017
mitochondrial
protein
of
unknown
We recently reported that Poldip2 is repressed
173