Retrovirology
BioMed Central
Open Access
Research
Trypanosoma cruzi (Chagas' disease agent) reduces HIV-1
replication in human placenta
Guillermina Laura Dolcini*1, María Elisa Solana2, Guadalupe Andreani1,
Ana María Celentano2, Laura María Parodi3, Ana María Donato4,
Natalia Elissondo4, Stella Maris González Cappa2, Luis David Giavedoni3
and Liliana Martínez Peralta1
Address: 1National Reference Center for AIDS, Microbiology Department, School of Medicine, University of Buenos Aires, Buenos Aires, Argentina,
2Laboratory of Parasitology, Microbiology Department, School of Medicine, University of Buenos Aires, Buenos Aires, Argentina, 3Department of
Virology and Immunology, Southwest National Primate Research Center (SNPRC), Southwest Foundation for Biomedical Research (SFBR), San
Antonio, Texas, USA and 4Endocrinology Service, Department of Clinical Biochemistry, José de San Martín Hospital, School of Pharmacy and
Biochemistry, University of Buenos Aires, Buenos Aires, Argentina
Email: Guillermina Laura Dolcini* - gdolcini@fmed.uba.ar; María Elisa Solana - melisolana@yahoo.com.ar;
Guadalupe Andreani - gandreani@fmed.uba.ar; Ana María Celentano - amcele@fmed.uba.ar; Laura María Parodi - lparodi@sfbr.org;
Ana María Donato - donatoam@hotmail.com; Natalia Elissondo - natieli@hotmail.com; Stella Maris
González Cappa - smgcappa@fmed.uba.ar; Luis David Giavedoni - lgiavedo@sfbr.org; Liliana Martínez Peralta - lilimp@fmed.uba.ar
* Corresponding author
Published: 1 July 2008
Retrovirology 2008, 5:53
doi:10.1186/1742-4690-5-53
Received: 7 February 2008
Accepted: 1 July 2008
This article is available from: http://www.retrovirology.com/content/5/1/53
© 2008 Dolcini et al; licensee BioMed Central Ltd.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0),
which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract
Background: Several factors determine the risk of HIV mother-to-child transmission (MTCT),
such as coinfections in placentas from HIV-1 positive mothers with other pathogens. Chagas'
disease is one of the most endemic zoonoses in Latin America, caused by the protozoan
Trypanosoma cruzi. The purpose of the study was to determine whether T. cruzi modifies HIV
infection of the placenta at the tissue or cellular level.
Results: Simple and double infections were carried out on a placental histoculture system
(chorionic villi isolated from term placentas from HIV and Chagas negative mothers) and on the
choriocarcinoma BeWo cell line. Trypomastigotes of T. cruzi (VD lethal strain), either purified from
mouse blood or from Vero cell cultures, 24 h-supernatants of blood and cellular trypomastigotes,
and the VSV-G pseudotyped HIV-1 reporter virus were used for the coinfections. Viral
transduction was evaluated by quantification of luciferase activity. Coinfection with whole
trypomastigotes, either from mouse blood or from cell cultures, decreased viral pseudotype
luciferase activity in placental histocultures. Similar results were obtained from BeWo cells.
Supernatants of stimulated histocultures were used for the simultaneous determination of 29
cytokines and chemokines with the Luminex technology. In histocultures infected with
trypomastigotes, as well as in coinfected tissues, IL-6, IL-8, IP-10 and MCP-1 production was
significantly lower than in controls or HIV-1 transducted tissue. A similar decrease was observed
in histocultures treated with 24 h-supernatants of blood trypomastigotes, but not in coinfected
tissues.
Conclusion: Our results demonstrated that the presence of an intracellular pathogen, such as T.
cruzi, is able to impair HIV-1 transduction in an in vitro system of human placental histoculture.
Page 1 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
http://www.retrovirology.com/content/5/1/53
Direct effects of the parasite on cellular structures as well as on cellular/viral proteins essential for
HIV-1 replication might influence viral transduction in this model. Nonetheless, additional
mechanisms including modulation of cytokines/chemokines at placental level could not be excluded
in the inhibition observed. Further experiments need to be conducted in order to elucidate the
mechanism(s) involved in this phenomenon. Therefore, coinfection with T. cruzi may have a
deleterious effect on HIV-1 transduction and thus could play an important role in viral outcome at
the placental level.
Background
Mother-to-child transmission (MTCT) of human immunodeficiency virus type 1 (HIV-1) occurs mainly when the
newborn comes in contact with infected secretions of the
mother during birth, though HIV-1 can also be transmitted through breastfeeding and in utero [1]. MTCT rates
between 1–2% have been achieved after successful application of preventive therapies, mainly in industrialized
countries [2-5]. However, studies performed in large
cohorts with a follow-up of 8 years have shown that in
utero transmission may still occur before therapy is initiated or effective [6]. Thus, this type of transmission seems
to be a relevant way of MTCT even when efficient antiretroviral treatment and avoiding breastfeeding are being
successfully performed.
The exact mechanisms by which the fetus acquires HIV-1
during pregnancy are not yet clear, even though the placenta is an efficient natural barrier that plays a role in the
regulation of MTCT [7,8]. Soluble factors in the placental
environment are part of this barrier. Indeed, several studies have suggested that cytokines and chemokines may be
major regulators of transplacental transmission of HIV-1
[9-12]. A recent study demonstrated that placental
explants from HIV-1 positive treated women secreted
higher levels of leukemia inhibitory factor (LIF), interleukin (IL)-16, and regulated upon activation of normal T
cells expressed and secreted (RANTES), soluble factors
that inhibit HIV replication, and lower levels of TNF-α
and IL-8, proinflammatory factors known as stimulators
of viral replication [13].
Maternal viral load and immunological status are the
main factors that determine the risk of HIV-MTCT [14,15].
Other risk factors are coinfections of the mother [16,17],
an important issue since world regions with the highest
prevalence of HIV-1 infection are also affected by other
infections. Thus, HIV positive pregnant women are usually infected with other pathogens, and such placental
coinfections may have consequences on MTCT of the
pathogens. This is the case for HIV-1 infected pregnant
women of sub-Saharan Africa coinfected with Plasmodium
falciparum, who showed an increased peripheral and/or
placental viral replication with more adverse birth outcomes than HIV uninfected women, particularly multi-
gravida women [18]. Also noted, a shift in cytokine
production towards a proinflammatory profile has been
associated with P. falciparum placental infection [19,20],
which could stimulate HIV-1 replication [21].
In Latin America, one of the most important endemic protozoonoses is Chagas' disease, caused by the protozoan
parasite Trypanosoma cruzi. It extends from southern USA
to southern South America. There are approximately 16–
18 million infected people, representing the largest parasitic disease burden on the continent, with around 50,000
deaths per year and 100 million at risk of infection
[22,23]. Largely considered as a rural entity, Chagas' disease has become an urban public health problem due to
mass migration of rural inhabitants to big cities and an
increase in poverty [24]. This "urbanization" of Chagas'
disease facilitates coinfection in the most important areas
for HIV prevalence: the City of Buenos Aires and surrounding areas. T. cruzi is mainly transmitted to humans
by vectors such as blood-sucking bugs present in rural
areas, but also by blood transfusion or congenital transmission. Due to the development of national programs
for vector control and for the selection of blood donors,
congenital transmission in women of child-bearing age
still remains a pressing public health issue since T. cruzi
could be transmitted to their newborn throughout the
course of infection [23]. The rates of congenital transmission vary from 1% to 10%, according to geographic areas
[25]. Such transmission takes place more frequently in the
chronic stage of Chagas' disease, in endemic as well as in
non-endemic areas, though its mechanisms have not been
clearly defined [24,26]. In the case of T. cruzi infected
mothers, no preventive treatment is possible during pregnancy due to the antiparasitic drugs' toxicity for the fetus
[27]. Indeed, clinical management of these women differs
greatly for HIV infected mothers.
Data from HIV-T. cruzi coinfected patients indicated reactivation of parasite infection with exacerbation of clinical
signs and unusual clinical manifestations [28-31]. Even if
no evidence exist focus on clinical features of coinfected
mothers, MTCT of both pathogens with severe outcome
for the children [32] and congenital transmission of T.
cruzi without confirmation of HIV-1 MTCT [33] were
reported. However, little is known about interaction of
Page 2 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
both pathogens on an in vitro cellular or ex vivo tissue
model. Thus, the purpose of the study was to determine
whether coinfection with T. cruzi and HIV-1 at the tissue
or cellular level modifies HIV-1 infection.
Results
Tissue viability and responsiveness to stimuli
Viability of the placental histocultures throughout the culture period was evaluated by quantifying total hCG production in histoculture supernatants every 3 to 4 days
from day 1 to day 18 or 21. The maximum level of total
hCG was observed at day 4 or 7. A decrease was observed
between day 7 and day 11 of culture, and the minimum
level was reached after day 18. These levels are comparable to those obtained in histocultures from previously
reported term placentas [34]. Kinetics of hCG production
are shown in Figure 1.
After the set-up of the histoculture system and before the
start of the infection protocols, the tissue response to an
external stimulus such as LPS was evaluated. Placental
histocultures were stimulated with 0.1 and 10 μg/ml LPS
at day 0, 3 and 6 for 24 h before supernatant collection.
Placental histocultures showed a response to this stimulus
in a dose-dependent manner secreting high amounts of
TNF-α at all the times tested (data not shown).
http://www.retrovirology.com/content/5/1/53
Tissue function is not modified by pseudotyped virus
transduction and or parasite infection
After viral transduction with or without parasite infection,
tissue function of placental histocultures was analyzed by
measuring total hCG secretion levels in histoculture
supernatants from each experiment. As shown in Figure 2,
neither viral nor parasite treatment significantly modified
hCG secretion, indicating that the outcome of infection
was not due to direct cytotoxicity of the inocula for the
histocultures.
T. cruzi trypomastigotes and 24 h-supernatants of
trypomastigotes decrease HIV-1 replication in BeWo cells
The effect of blood trypomastigotes (BT) on HIV-1 replication was assessed on BeWo cells, a model of early trophoblast cells which are the first placental layer in direct
contact with maternal blood. Previous data indicated that
the HIV-1 R5 (BaL) or X4 (HXB2) pseudotyped reporter
virus did not replicate in BeWo cells [35], thus we used
only VSV-G pseudotyped HIV-1 reporter virus. Cells were
incubated with BT and/or pseudotyped virus, and transduction of the luciferase reporter gene as an indicator of
viral replication was evaluated at the end of the experiment. As shown in Figure 3 (left bar), viral replication was
decreased by BT (-86%, p < 0.005).
As trypomastigotes shed several soluble factors [36], we
wanted to determine whether the trypomastigote supernatant could interfere with HIV-1 replicative cycle, or if an
active T. cruzi infection was necessary to achieve the previ-
Figure 1 of hCG in the culture medium of placental histocultures
Production
Production of hCG in the culture medium of placental histocultures. Chorionic villi were placed on 1.5 cm2 collagen
sponge gels at medium-air interface into the wells of 6-well plates, 9 blocks per collagen sponge and per well. Production of
hCG was measured in histoculture supernatants every 3 to 4 days from day 1 to day 18 or 21 by the chemiluminescence
method. Placental histocultures were maintained in 5% CO2 atmosphere/95% air at 37°C. Results represent mean ± SD of
duplicates and are representative of 3 independent experiments.
Page 3 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
http://www.retrovirology.com/content/5/1/53
Figurefunctionality
Tissue
2
after pseudotyped virus transduction and/or parasite infection
Tissue functionality after pseudotyped virus transduction and/or parasite infection. Placental villi were dissected
and immediately transducted overnight with VSV-G pseudotyped HIV-1 (V) (100 ng p24/placental block) alone or in the presence of blood trypomastigotes (BT) (106 parasites/placental block) or 24 h-supernatant of BT (BTSn). After infection or coinfection, tissue functionality of placental histocultures was analyzed by measuring total hCG secretion levels in histoculture
supernatants by the chemiluminescence method at day 4 post-infection or coinfection. Results represent mean ± SD of duplicates and are representative of 5 independent experiments.
ously described effect. Thus, BeWo cells were incubated
with 24 h-supernatants from BT (BTSn) and VSV-G pseudotype virus. Similar effect on luciferase activity as in the
case of BT was observed for BTSn (-76%, p < 0.005) (Figure 3, right bar).
T. cruzi trypomastigotes and 24 h-supernatants of
trypomastigotes decrease HIV-1 replication in placental
histocultures
Transduction with pseudotyped virus harboring VSV-G,
HIV-1 R5 (BaL) or HIV-1 X4 (HXB2) envelope protein
were performed on placental histocultures, with or without infections with BT. Results were normalized in each
sample by total protein concentration. When placental
histocultures were transducted with HXB2 pseudotyped
virus, no luciferase activity was detected (data not shown).
When BaL pseudotyped virus was used, even at higher
doses than VSV-G pseudotyped virus, levels of luciferase
activity were lower. However, for both pseudotyped virus
luciferase activities were significantly decreased in coinfection with BT (mean ± SD; -90.98% ± 5.83, p < 0.001 for
VSV-G and -94% ± 5.02, p < 0.001 for BaL) (Figure 4A).
Purification of BT might carry other components from
mouse blood, mainly white cells and platelets, which
could interfere with HIV-1 replication. Thus, similar
experiments were performed using trypomastigotes purified from Vero cell culture supernatants (CT). Similarly,
live CT significantly decreased virus-driven luciferase
of
Effect
Figure
trypomastigotes
of3blood T. cruzi
on trypomastigotes
HIV-1 replicationand
in BeWo
24 h-supernatant
cells
Effect of blood T. cruzi trypomastigotes and 24 hsupernatant of trypomastigotes on HIV-1 replication
in BeWo cells. The human choriocarcinoma BeWo cell line
was transducted overnight with VSV-G pseudotyped HIV-1
(V) (100 ng p24/2 × 104 cells per well) alone or in the presence of blood trypomastigotes (BT) (2 × 105 parasites/2 ×
104cells per well) or 24 h-supernatant of BT (BTSn). Cells
were lysed and luciferase activity as an indicator of viral replication was read from cell lysates at day 4 post-infection or
coinfection. Results are expressed as relative light units per
second (RLU/sec), presented as a percentage relative to VSVG. The histogram in red corresponds to the % of infection
with VSV-G (= 100%) and the histogram in white corresponds to the % of infection in the presence of BT. Results
are representative of 3 independent experiments.
Page 4 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
http://www.retrovirology.com/content/5/1/53
Figure
Effect
histocultures
of4blood and culture T. cruzi trypomastigotes and 24 h-supernatants of trypomastigotes on HIV-1 replication in placental
Effect of blood and culture T. cruzi trypomastigotes and 24 h-supernatants of trypomastigotes on HIV-1 replication in placental histocultures. A: Placental villi were transducted overnight with BaL (B) (250 ng p24/placental block) or
VSV-G pseudotyped HIV-1 (V) (100 ng p24/placental block) alone or in the presence of blood trypomastigotes (BT) (106 parasites/placental block). Fragments were homogenized and luciferase activity as an indicator of viral replication was read from tissue lysate at day 4 post-infection or coinfection. Results are expressed as relative light units per second (RLU/sec), presented
as a percentage relative to B or V and were normalized in each sample by total protein concentration (RLU/prot). The histogram in red corresponds to the % of infection with BaL or VSV-G (= 100%) and the histogram in white corresponds to the %
of infection in the presence of BT. B: Placental villi were transducted overnight with VSV-G pseudotyped HIV-1 (V) (100 ng
p24/placental block) alone or in the presence of blood trypomastigotes (BT) or cell trypomastigotes (CT) (106 parasites/placental block), or 24 h-supernatants of BT (BTSn) or 24 h-supernatants of CT (CTSn). Fragments were homogenized and luciferase
activity as an indicator of viral replication was read from tissue lysate at day 4 post-infection or coinfection. Results are
expressed as relative light units per second (RLU/sec), presented as a percentage relative to V and were normalized in each
sample by total protein concentration (RLU/prot). The histogram in red corresponds to the % of infection with VSV-G (=
100%) and the histogram in white corresponds to the % of infection in the presence of BT, CT, BTSn or CTSn (p < 0.001).
Results are represented as a mean of 5 independent experiments.
Page 5 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
http://www.retrovirology.com/content/5/1/53
Figureof5blood T. cruzi trypomastigotes on cytokine/chemokine secretion in placental histocultures
Effect
Effect of blood T. cruzi trypomastigotes on cytokine/chemokine secretion in placental histocultures. Placental villi
were transducted overnight with VSV-G pseudotyped HIV-1 (V) (100 ng p24/placental block) alone or in the presence of blood
trypomastigotes (BT) (106 parasites/placental block). Histoculture supernatants were collected after infection or coinfection,
diluted with 10% FCS in RPMI and used for the simultaneous determination of cytokine/chemokine production with Luminex
technology. Results displayed correspond to IL-6 (p < 0.01), IL-8 (p < 0.05), IP10 (p < 0.01) and MCP-1 (p < 0.02). Results are
expressed as the mean ± SD and are representative of 5 independent experiments.
activity in placental histocultures when they were coinfected with VSV-G pseudotyped HIV-1 reporter virus
(mean ± SD; -97.36% ± 0.98, p < 0.001) (Figure 4B).
Additionally, placental explants were incubated with 24
h-supernatants from either BT (BTSn) or CT (CTSn) and
VSV-G pseudotype virus. A similar effect on luciferase
activity as in the case of BT was observed for BTSn (mean
of diminution ± SD; -81.48% ± 8.15, p < 0.001), while
CTSn also decreased luciferase activity although at a lower
degree (-61.21% ± 1.94, p < 0.001) (Figure 4B).
Effect of coinfection on soluble factor secretion
In an attempt to determine whether changes in the placental microenvironment due to parasite-viral interaction
are responsible for inhibiting HIV replication, cytokine/
chemokine secretion was measured in histoculture supernatants at day 1 and at day 4 post-infection or coinfection.
Results for day 1 presented in Figure 5 demonstrate that T.
cruzi acts as a potent inhibitor of IL-6 (p < 0.01), IL-8 (p <
0.05), IP10 (p < 0.01) and MCP-1 (p < 0.02), while no significant changes were observed in RANTES, MIP-1α, MIP1β, G-CSF, GRO-α, GM-CSF, IFN-γ, IL-10, IL-13, IL-1β, IL2, IL-4 and IL-5 production (data not shown). The effect
of HIV-T. cruzi interaction on cytokine/chemokine secretion seems to be parasite-driven since their levels correlated with those induced by the parasite alone.
When placental histocultures were treated with BTSn, significant decreases only in IL-6 (p < 0.04), IL-8 (p < 0.05),
MCP-1 (p < 0.01), GM-CSF (p < 0.05), MIP-1α (p < 0.05),
and MIP-1β (p < 0.05) secretion were detected in histoculture supernatants collected at day 1 post-infection or coinfection (Figure 6). Surprisingly, this diminution was
detected only in BTSn treated histocultures but no
changes were observed in HIV-BTSn treated samples.
In all experiments, the differences seen at day 1 were no
longer seen at day 4 post-infection or coinfection.
Page 6 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
http://www.retrovirology.com/content/5/1/53
Figure
Effect of624 h-supernatants of blood T. cruzi trypomastigotes on cytokine/chemokine secretion in placental histocultures
Effect of 24 h-supernatants of blood T. cruzi trypomastigotes on cytokine/chemokine secretion in placental
histocultures. Placental villi were transducted overnight with VSV-G pseudotyped HIV-1 (V) (100 ng p24/placental block)
alone or in the presence of 24 h-supernatants of blood trypomastigotes (BTSn) (106 parasites/placental block). Histoculture
supernatants were collected after infection or coinfection, diluted with 10% FCS in RPMI and used for the simultaneous determination of cytokine/chemokine production with Luminex technology. Results displayed correspond to IL-6 (p < 0.04), IL-8 (p
< 0.05), MIP-1α (p < 0.05), MIP-1β (p < 0.05), GM-CSF (p < 0.05) and MCP-1 (p < 0.01) (pg/ml). Results are expressed as the
mean ± SD and are representative of 5 independent experiments.
Discussion
As a result of the significant burden of the HIV pandemics
in resource-poor regions, a number of potential epidemiological, biological, and clinical interactions between HIV
and other tropical pathogens gained relevance and need
to be studied. The interactions between HIV and tropical
infectious agents are complex. Each pathogen has the
potential to alter the epidemiology, natural history, and/
or response to therapy of the other pathogens [37]; therefore, it is unpredictable to establish the outcome of such
Page 7 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
coinfections. In Latin America, one of the most significant
endemic protozoonoses is Chagas' disease, and several
clinical studies from HIV-T. cruzi coinfected patients have
been reported [28-31]. MTCT is one way of transmission
shared by both pathogens. The exact mechanisms
involved in MTCT of both pathogens are not clear. Hence,
the study of their interaction at the placental level is critical for designing strategies that abolish MTCT.
In our in vitro culture system of term placental histocultures, as well as in the trophoblast cell line BeWo, we demonstrate that acute coinfection with T. cruzi and HIV-1
pseudotyped virus decreases HIV-1 replication. This is the
first report about interaction of these pathogens at the placental level.
In order to validate our placenta in vitro model, we evaluated the viability and responsiveness to stimuli of the
histocultures. As previously described [34], micro-explant
villi of term placentas were morphologically viable until
day 7 or 11 with no significant alterations (data not
shown) and total hCG secretions peaked at day 7 or 11.
Additionally, they were able to react to external stimuli
such as LPS, secreting a great amount of TNF-α, as previously described [38]. Altogether, these results provide evidence that placental villi are intact and remain viable and
functional until at least day 7 of culture.
For BeWo cells and placental histoculture infection, a
pseudotyped Vesicular Stomatitis Virus G/HIV-1 was
used. This pseudotyped virus, due to its amphotropic
nature, is able to infect any cell type, regardless of receptor
and coreceptor surface expression [39]. When R5-Env
pseudotyped HIV-1 was used on placental histocultures,
coinfection with trypomastigotes also abolished HIV-1
replication almost completely (Fig. 4A). Previous studies
have demonstrated that X4-Env HIV-1 pseudotype viruses
do not infect human term placental chorionic villi and
that a higher dose of R5-Env HIV-1 pseudotypes, compared to viruses pseudotyped with VSV-G, is necessary to
observe an infection of placental tissue [21]. Similarly,
previous studies have shown that malignantly transformed human cell lines of the trophoblast lineage are
resistant to cell-free HIV-1 pseudotypes bearing the R5
and X4 envelopes, and that this resistance was bypassed
when HIV-1 envelopes were substituted by the VSV-G protein [35]. Thus, subsequent experiments of our study on
placental histocultures as well as on BeWo cell line were
performed only with VSV-G pseudotyped virus. Although
we do not address the effects of T. cruzi on the binding of
HIV-1 to their natural receptors, our experiments are valid
in studying the effects of the parasite on viral replication.
A great impairment of HIV-1 replication was observed in
coinfection with viable T. cruzi trypomastigotes purified
http://www.retrovirology.com/content/5/1/53
from mouse blood (BT). Moreover, when other source of
viable trypomastigotes was used, such as those grown in
cell culture (CT), the same effect on HIV-1 replication was
observed. In all cases, hCG secretion was measured in
histoculture supernatants and no significant differences
were observed between control, viral infection, or treatment with trypomastigotes. These results indicate that placental tissue remains viable and that parasite impairment
of HIV-1 replication was not associated with direct cell
toxicity caused by T. cruzi. Previous data indicate that the
parasite induces rearrangement of cortical cytoskeleton of
syncytiotrophoblast with actin microfilament depletion
during human placental invasion [40].
Considering that after entering the cell, the HIV-1 virion
interacts initially with actin filaments which assist binding
to microtubules and transport to the nuclear periphery
[41], modifications in trophoblast cytoskeleton might
impair viral replication at an early phase in the case of
active T.cruzi invasion. However, the inhibition of HIV
replication seems to be caused not only by viable trypomastigotes but also by soluble factors shed by the parasite,
either from BT or CT.
Taking into account that T. cruzi sheds several proteases
(cysteine, serine, threonine and metalloproteinases) that
participate in host cell invasion [36], those molecules
could interfere with some critical structures inside the
cytosol of host cells required for viral genome retrotranscription and transfer to the nucleus. Indeed, this is
allowed by the reverse transcription complex that later
becomes the preintegration complex, and both complexes
include not only viral RNA or DNA and several accessory
viral proteins, but also cellular proteins [42], which are
necessary for efficient reverse transcription of HIV-1 [43].
Disruption of these complexes by exogenous enzymes or
alteration of protein interactions can lead to an impaired
HIV-1 replication [44]. We might hypothesize that this is
the case when T. cruzi proteases are present.
Since the T cruzi is a complex intracellular organism that
has a great impact on host cell structure and also on its
metabolism, we decided to evaluate whether the parasite
or its soluble products are able to modify the placental
environment. In fact, many soluble factors, including
cytokines and hormones, with regulatory activities are
essential for establishing and maintaining pregnancy
[45,46]. HIV-1 and antiretroviral treatment in pregnant
women have an impact on the pattern of placental soluble
factors [13,38]. On the other hand, little is known about
the changes in human fetal-maternal interface in T. cruzi
infection. In histocultures infected with trypomastigotes
and in coinfected tissue, IL-6, IL-8, IP-10 and MCP-1 production was significantly lower than in controls or HIV-1
infected tissues. Certainly, most of these chemokines are
Page 8 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
an important driving-force for CD8+ T-cell recruitment,
which plays a significant role in the control of acute T.
cruzi infection [47]. Concerning HIV-1, many reports
describe the role of cytokines/chemokines on its replication. Among them, IL-6 is a well-known cytokine with upregulating activity on HIV replication [48]. Moreover,
MCP-1 and IP-10 were associated with an increase in leukocyte density and cerebrospinal fluid viral load [49-51].
Indeed, IP-10, as well as IL-8 may stimulate HIV-1 replication in different cell types [52,53], although mechanisms
are not clearly defined. In our system, a diminished secretion of those stimulatory cytokines/chemokines was
observed at day 1 post-infection whenever the parasite
was present. These transitory changes in the placental
environment might contribute to HIV-1 replication
impairment.
Parallel studies have also been conducted on another cellular system for the study of HIV/T. cruzi interaction as
one of the main cell targets for both pathogens, the monocyte-derived macrophages, and similar inhibition of viral
replication was observed at different levels of HIV-1 replication cycle (Andreani G. at al., manuscript in preparation). Thus, related mechanisms by which T. cruzi impair
HIV-1 replication seem to be involved in different in vitro
systems.
Conclusion
Our results demonstrate that the presence of an intracellular pathogen such as T. cruzi is able to impair HIV-1 transduction in an in vitro system of human placental
histocultures. Direct effects of the parasite on cellular
structures as well as on cellular/viral proteins essential for
HIV-1 replication might influence viral transduction in
this model. Nonetheless, additional mechanisms including modulation of cytokines/chemokines at placental
level could not be excluded in the inhibition observed.
Further experiments need to be conducted in order to clarify the mechanism(s) involved in this phenomenon.
In summary, coinfection with T. cruzi may have a deleterious effect on HIV-1 transduction and thus could play an
important role in viral outcome at the placental level.
Methods
Histocultures of chorionic villi from term placentas
Term placentas were obtained after programmed cesarean
section at the Obstetrics Unit of the Fernández and Ramos
Mejía Hospitals in the city of Buenos Aires, in accordance
with Argentinean ethics guidelines. This study was
approved by the Ethics Committee from the School of
Medicine, University of Buenos Aires. Histocultures of
chorionic villi were performed as previously described
[34] with slight modifications. Briefly, placental villi were
http://www.retrovirology.com/content/5/1/53
isolated, washed extensively with RPMI 1640 (CellGro,
USA) and dissected into 2–3 mm blocks. After infection or
coinfection, chorionic villi were placed on 1.5 cm2 collagen sponge gels (Espongostan, Johnson & Johnson, USA)
at medium-air interface into the wells of 6- or 12-well
plates (Greiner, Germany) with 3 or 2 ml media per well
respectively, at 9 tissue blocks per collagen sponge and per
well. Histoculture medium was RPMI 1640 (CellGro)
supplemented with 15% heat-inactivated fetal calf serum
(FCS, PAA-Bioser, Argentina), 1% penicillin-streptomycin, 0.1% gentamicin, 1% L-glutamine, 1% non-essential
amino acids, 1% sodium pyruvate; (Gibco BRL Ltd.,
USA). Placental histocultures were maintained in 5% CO2
atmosphere/95% air at 37°C. Each experimental point
means a duplicate histoculture well.
Evaluation of histoculture viability and response to stimuli
Viability of histocultures was monitored by detection of
total hCG secretion determined with a chemiluminescence method (Immulite 1000, detection limit 1.1 mIU/
ml, Siemens Medical Solutions Diagnostics, USA) in
supernatants from both histoculture system setup protocols (from day 1 to day 18) and in infection protocols
(day 4 post-infection or coinfection). Tissue responses to
LPS were analyzed by incubating tissue fragments with 0.1
and 10 μg/ml LPS (from E. coli serotype 055:B5, SigmaAldrich, USA) at day 0, 3 and 6 of histoculture. After 24 h,
levels of Tumor Necrosis Factor-alpha (TNF-α) secretion
were quantified by ELISA (Peprotech, Mexico) in histoculture supernatants.
Trophoblast cell line
The human choriocarcinoma BeWo cell line [54], used as
a model for early trophoblast cells [55-57], was obtained
from the American Type Culture Collection (ATCC #
CCL98, Rockville, Md.). These cells were maintained in
Dulbecco's Modified Eagle Medium (DMEM, CellGro)
containing 25 mM glucose, supplemented with 20% heatinactivated FCS, 20 mM glutamine, 50 IU/ml penicillin
and 50 μg/ml streptomycin, in 5% CO2 atmosphere/95%
air at 37°C.
Pseudotyped viruses
Luciferase reporter viruses were produced as previously
described [35] by transiently cotransfecting (SuperFect;
Qiagen, Germany) 293T cells with the proviral pNL-LucE-R+ vector [58], which lack the env gene and has the firefly
luciferase gene inserted into the nef gene, and the expression vector pCMV harboring the gene coding for either the
VSV-G envelope protein or the HIV-1 R5 (BaL) envelope
protein [59], or the expression vector pSV harboring the
gene coding for HIV-1 X4 (HXB2) envelope protein [60].
Supernatants from 293T cells were harvested 72 h after
transfection and p24gag levels were measured using a
commercial ELISA kit (Murex, UK).
Page 9 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
T. cruzi purification and supernatant preparation
T. cruzi VD strain (isolated from a case of congenital Chagas' disease, lethal for mice, lineage II) was used [61]. This
subpopulation was maintained by serial passages in 21day old CF1 mice. Either bloodstream forms (BT) or tissue
culture-derived (CT) trypomastigotes were employed for
the coinfection assays. BT were collected from blood of T.
cruzi infected mice at the peak of parasitemia by cardiac
puncture. To enrich blood supernatants with BT, the centrifuged blood was incubated for 1 h at 37°C and the
supernatant was collected. Thus, BT were pelleted by centrifugation for 30 min at 10,000 × g, counted in a Neubauer hematocytometer and diluted to 107 BT/ml in
BeWo medium or to 4 × 107 BT/ml in histoculture
medium for further use in coinfection assays. In order to
obtain CT, Vero cell monolayers were allowed to interact
with BT in a parasite/cell ratio of 5:1 for 24 h. CT harvested from the second passage in Vero monolayers were
pelleted by centrifugation for 30 min at 10,000 × g,
counted in a Neubauer hematocytometer and diluted to 4
× 107 CT/ml in histoculture medium for further use in
coinfection assays.
In order to obtain parasite supernatants, 107 BT diluted in
BeWo medium or 4 × 107 BT or CT diluted in histoculture
medium were incubated for 24 h at 37°C in 5% CO2. To
remove parasites and cellular debris, both parasite suspensions were pelleted as described above and the supernatants were filtered through a 0.22 μm pore-size filter.
Filtrated aliquots were stored at -80°C until use for coinfection assays.
Infection of trophoblast cells
BeWo cells were seeded in 96-well plates (2 × 104cells per
well) 24 h before infection and then incubated with VSVG pseudotyped HIV-1 (100 ng of p24 per well) and 2 ×
105 BT or 24 h-supernatant of BT (BTSn) overnight at
37°C in 5% CO2. Controls included transduction with
only the pseudotyped virus or Δenv pseudotype, infection
with parasites or treatment with parasite supernatants,
and also mock infected cells with culture medium. After
culture for an additional 72 h, 100 μl of luciferase lysis
buffer (Promega) per well was added and luciferase activity as an indicator of viral replication was measured in 10
μl of lysate with a luminometer (Veritas), using the commercially available substrate; data were expressed as RLU/
sec.
Infection of placental histocultures
After dissection, 18 blocks of placental villi were placed in
24-well plates and transducted overnight with BaL (250
ng p24/placental block), HXB2 (250 ng p24/placental
block) or VSV-G pseudotyped HIV-1 (100 ng p24/placental block) and infected with BT or CT (106 parasites/placental block), or parasite supernatants. Controls included
http://www.retrovirology.com/content/5/1/53
transduction with only the pseudotyped virus or Δenv
pseudotype, infection with parasites or treatment with
parasite supernatants, and also mock infected histocultures with culture medium. The following day, placental
blocks were washed 6 times in 6-well plates with PBS 1×
(Gibco BRL Ltd.) using a cell strainer (BD Biosciences,
USA), placed on collagen sponges and cultured as
described above for an additional 72 h. Protocols of overnight infection and then supernatant collection were also
performed.
For further cytokine/chemokines quantification, at the
end of each experiment, supernatants were collected, clarified by centrifugation at 1,000 × g for 10 minutes, filtered
(0,22 μm), aliquoted and stored at -80°C. Placental fragments were collected and preserved at -80°C until
homogenization.
For luciferase activity quantification, placental fragments
were homogenized in 500 μl of luciferase lysis buffer
(Promega, USA) with an Ultra-turrax homogenizer (IKA,
USA). Luciferase activity was measured at day 4 post-infection or coinfection in 20 μl of lysate with a luminometer
(Veritas, USA), using a commercially available substrate
(Dual-Luciferase Reporter Assay System, Promega), and
expressed as relative light units (RLU). Results were normalized to total protein concentration measured on
lysates from each sample using a Micro BCA™ Protein
Assay Kit (Pierce, USA). Final data were expressed as RLU/
μg prot (RLU/prot).
Quantification of the protein secretion of soluble factors
in placental histocultures
Supernatants of stimulated histocultures were diluted
with 10% FCS in RPMI and used for the simultaneous
determination of 29 cytokines and chemokines with
Luminex technology as previously described [62,63]. The
coated bead/biotinylated antibody combinations used
were: G-CSF (LINCOplex human G-CSF, Linco Research,
St. Charles. MO), GM-CSF (Beadlyte human GM-CSF,
Upstate USA, Charlottesville, VA), GRO-α (Beadlyte
human GRO-α, Upstate), IFN-α (anti-human IFN-α
clones MMHA-11 and MMHA-2, PBL Biomedical Laboratories, Piscataway, NJ), IFN-γ (Beadlyte primate IFN-γ,
Upstate), IL-1β (Monkey IL-1β ELISPOT reagents, UCytech), IL-1Ra (Fluorokine MAP human IL-1Ra/IL-1F3,
R&D System, Minneapolis, MN), IL-2 (Beadlyte primate
IL-2, Upstate), IL-4 (LINCOplex human IL-4, Linco), IL-5
(LINCOplex human IL-5, Linco), IL-6 (LINCOplex
human IL-6, Linco), IL-7 (anti-human IL-7 clone 7417
and polyclonal anti-human IL-7, R&D), IL-8 (Beadlyte
human IL-8, Upstate), IL-9 (Beadlyte human IL-9,
Upstate), IL-10 (anti-human IL-10 clones BN-10 and QS10, Cell Sciences Inc., Canton, MA), IL12(p40) (antihuman IL-12 clones IL-12I and IL-12II, Mabtech Inc.,
Page 10 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
Mariemont, OH), IL-12(p70) (anti-human IL-12 p70
clone 20C2, Endogen, and IL-12II, Mabtech), IL-13
(Beadlyte human IL-13, Upstate), IL-15 (anti-human IL15 clone 34505 and polyclonal anti-human IL-15, R&D),
IL-17 (Human IL-17, Biosource International, Camarillo,
CA), IL-18 (anti-human IL-18 clones 125-2H and 15912B, MBL International, Woburn, MA), IP-10 (antihuman IP-10 clone 33036 and polyclonal anti-human IP10, R&D), MCP-1 (Human MCP-1, Biosource), MIP-1α
(Human MIP-1α, Biosource), MIP-1β (Human MIP-1β,
Biosource), RANTES (Beadlyte human RANTES, Upstate),
sCD40L (Fluorokine MAP human sCD40L, R&D System),
TNF-α (Beadlyte human TNF-α, Upstate), and TNF-β
(Beadlyte human TNF-β, Upstate). Cytokine concentrations were determined using human cytokines (Upstate)
as standards and the Masterplex QT software from Mirabio.
http://www.retrovirology.com/content/5/1/53
work was partly supported by grants from Argentina's National Agency for
Promotion of Science and Technology (PICT 05-11734 and PICT 05-34123)
and the National Council for Technological and Scientific Research (PIP
6119). Additional support was provided by NIH Grants R51 RR013986 and
R24 RR023345.
References
1.
2.
3.
4.
5.
Statistical Analysis
Results of luciferase activity and cytokine/chemokine production from each group (infected or coinfected tissue/
cells) are presented as mean ± SD. Comparison of their
distributions between 2 groups for luciferase activity was
performed by a t-Student test and distribution between
more than 2 groups for cytokine/chemokine expression
was performed by a non-parametric Friedman test and a
post-test Dunns, using the Graph Pad Prism 4 software.
6.
7.
8.
Competing interests
The authors declare that they have no competing interests.
9.
Authors' contributions
GLD was responsible for the design, testing and writing of
the manuscript. GLD and GA were responsible for viral
preparation and for all the coinfection experiments in the
in vitro placental model and BeWo cells. MES and AMC
were responsible for the isolation, culture and characterization of the parasites, and contributed to writing the
manuscript. SMGC contributed to the design of the experiments and discussion of the manuscript. LMP1 and LDG
performed and interpreted the cytokine measurements.
AMD and NE performed all the hormonal determinations. LMP2 was responsible for the design and writing of
the manuscript. All authors read and approved the final
manuscript.
1 Laura
María Parodi
2 Liliana
10.
11.
12.
13.
Martinez Peralta
14.
Acknowledgements
We are very thankful to Dr. Andrea Gamarnik for helping us with all the
luciferase determinations. We thank the patients for their supporting samples and we also would like to thank Dr. Dunaiewsky (Hospital Fernández)
and Dr. Lapidius (Hospital Ramos Mejía), and their respective groups from
the Obstetrics Unit for their kind collaboration in placental collection. This
15.
16.
Newell ML: Mechanisms and timing of mother-to-child transmission of HIV-1. Aids 1998, 12:831-837.
Cooper ER, Charurat M, Mofenson L, Hanson IC, Pitt J, Diaz C, Hayani K, Handelsman E, Smeriglio V, Hoff R, Blattner W: Combination
antiretroviral strategies for the treatment of pregnant HIV1-infected women and prevention of perinatal HIV-1 transmission. J Acquir Immune Defic Syndr 2002, 29:484-494.
Mandelbrot L, Landreau-Mascaro A, Rekacewicz C, Berrebi A, Benifla
JL, Burgard M, Lachassine E, Barret B, Chaix ML, Bongain A, et al.:
Lamivudine-zidovudine combination for prevention of
maternal-infant transmission of HIV-1.
Jama 2001,
285:2083-2093.
European Collaborative Study: Mother-to-child transmission of
HIV infection in the era of highly active antiretroviral therapy. Clin Infect Dis 2005, 40:458-465.
Ioannidis JP, Abrams EJ, Ammann A, Bulterys M, Goedert JJ, Gray L,
Korber BT, Mayaux MJ, Mofenson LM, Newell ML, et al.: Perinatal
transmission of human immunodeficiency virus type 1 by
pregnant women with RNA virus loads <1000 copies/ml. J
Infect Dis 2001, 183:539-545.
Warszawski J, Tubiana R, Le Chenadec J, Blanche S, Teglas JP, Dollfus
C, Faye A, Burgard M, Rouzioux C, Mandelbrot L: Mother-to-child
HIV transmission despite antiretroviral therapy in the ANRS
French Perinatal Cohort. Aids 2008, 22:289-299.
Dictor M, Lindgren S, Bont J, Anzen B, Lidman K, Wallin KL, Naver L,
Bohlin AB, Ehrnst A: HIV-1 in placentas of untreated HIV-1infected women in relation to viral transmission, infectious
HIV-1 and RNA load in plasma. Scand J Infect Dis 2001, 33:27-32.
Menu E, M'Bopi Keou FX, Lagaye S, Pissard S, Mauclere P, Scarlatti G,
Martin J, Goossens M, Chaouat G, Barre-Sinoussi F: Selection of
maternal human immunodeficiency virus type 1 variants in
human placenta. European Network for In Utero Transmission of HIV-1. J Infect Dis 1999, 179:44-51.
Moussa M, Mognetti B, Dubanchet S, Menu E, Roques P, Gras G, Dormont D, Barre-Sinoussi F, Chaouat G: Vertical transmission of
HIV: parameters which might affect infection of placental
trophoblasts by HIV-1: a review. Biomed Group on the Study
of in Utero Transmission of HIV 1. Am J Reprod Immunol 1999,
41:312-319.
Patterson BK, Behbahani H, Kabat WJ, Sullivan Y, O'Gorman MR,
Landay A, Flener Z, Khan N, Yogev R, Andersson J: Leukemia inhibitory factor inhibits HIV-1 replication and is upregulated in
placentae from nontransmitting women. J Clin Invest 2001,
107:287-294.
Menu E, Mognetti B, Moussa M, Nardese V, Tresoldi L, Tscherning C,
Mbopi Keou FX, Dubanchet S, Mauclere P, Fenyo EM, et al.: Insights
into the mechanisms of vertical transmission of HIV-1.
BIOMED2 Working Group on the in utero transmission of
HIV-1. Early Pregnancy 1997, 3:245-258.
Lee BN, Ordonez N, Popek EJ, Lu JG, Helfgott A, Eriksen N, Hammill
H, Kozinetz C, Doyle M, Kline M, et al.: Inflammatory cytokine
expression is correlated with the level of human immunodeficiency virus (HIV) transcripts in HIV-infected placental trophoblastic cells. J Virol 1997, 71:3628-3635.
Faye A, Pornprasert S, Mary JY, Dolcini G, Derrien M, Barre-Sinoussi
F, Chaouat G, Menu E: Characterization of the main placental
cytokine profiles from HIV-1-infected pregnant women
treated with anti-retroviral drugs in France. Clin Exp Immunol
2007, 149:430-439.
Bongertz V: Vertical human immunodeficiency virus type 1
(HIV-1) transmission: a review. Mem Inst Oswaldo Cruz 2001,
96:1-14.
Scarlatti G: Mother-to-child transmission of HIV-1: advances
and controversies of the twentieth centuries. AIDS Rev 2004,
6:67-78.
WHO/UNAIDS: HIV in pregnancy: a review. WHO/CHS/RHT/
99.15, UNAIDS/99.35E 1999.
Page 11 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
Hotez PJ, Molyneux DH, Fenwick A, Ottesen E, Ehrlich Sachs S, Sachs
JD: Incorporating a rapid-impact package for neglected tropical diseases with programs for HIV/AIDS, tuberculosis, and
malaria. PLoS Med 2006, 3:e102.
ter Kuile FO, Parise ME, Verhoeff FH, Udhayakumar V, Newman RD,
van Eijk AM, Rogerson SJ, Steketee RW: The burden of co-infection with human immunodeficiency virus type 1 and malaria
in pregnant women in sub-saharan Africa. Am J Trop Med Hyg
2004, 71:41-54.
Fievet N, Moussa M, Tami G, Maubert B, Cot M, Deloron P, Chaouat
G: Plasmodium falciparum induces a Th1/Th2 disequilibrium,
favoring the Th1-type pathway, in the human placenta. J
Infect Dis 2001, 183:1530-1534.
Rogerson SJ, Brown HC, Pollina E, Abrams ET, Tadesse E, Lema VM,
Molyneux ME: Placental tumor necrosis factor alpha but not
gamma interferon is associated with placental malaria and
low birth weight in Malawian women. Infect Immun 2003,
71:267-270.
Kfutwah AK, Mary JY, Nicola MA, Blaise-Boisseau S, Barre-Sinoussi F,
Ayouba A, Menu E: Tumour necrosis factor-alpha stimulates
HIV-1 replication in single-cycle infection of human term
placental villi fragments in a time, viral dose and envelope
dependent manner. Retrovirology 2006, 3:36.
Morel CM, Lazdins J: Chagas disease. Nat Rev Microbiol 2003,
1:14-15.
PAHO: American trypanosomiasis (Chagas' disease). Epidemiological Bulletin. Case Definitions 2003, 24:14-15 [http://
www.paho.org/english/dd/ais/be_v24n3-cover.htm].
Carlier Y, Pinto Dias JC, Ostermayer Luquetti A, Hontebeyrie M,
Torrico F, Truyens C: Trypanosomiase américaine ou maladie
de Chagas. In Encycl Méd Chir, Maladies infectieuses SAS ESeME.
Paris; 2002:1-21.
Hermann E, Truyens C, Alonso-Vega C, Rodriguez P, Berthe A, Torrico F, Carlier Y: Congenital transmission of Trypanosoma cruzi
is associated with maternal enhanced parasitemia and
decreased production of interferon- gamma in response to
parasite antigens. J Infect Dis 2004, 189:1274-1281.
Sanchez Negrette O, Mora MC, Basombrio MA: High prevalence
of congenital Trypanosoma cruzi infection and family clustering in Salta, Argentina. Pediatrics 2005, 115:e668-672.
Castro JA, de Mecca MM, Bartel LC: Toxic side effects of drugs
used to treat Chagas' disease (American trypanosomiasis).
Hum Exp Toxicol 2006, 25:471-479.
Ferreira MS, Borges AS: Some aspects of protozoan infections
in immunocompromised patients- a review. Mem Inst Oswaldo
Cruz 2002, 97:443-457.
Harms G, Feldmeier H: HIV infection and tropical parasitic diseases – deleterious interactions in both directions? Trop Med
Int Health 2002, 7:479-488.
Sartori AM, Caiaffa-Filho HH, Bezerra RC, do SGC, Lopes MH, Shikanai-Yasuda MA: Exacerbation of HIV viral load simultaneous
with asymptomatic reactivation of chronic Chagas' disease.
Am J Trop Med Hyg 2002, 67:521-523.
Sartori AM, Ibrahim KY, Nunes Westphalen EV, Braz LM, Oliveira
OC Jr, Gakiya E, Lopes MH, Shikanai-Yasuda MA: Manifestations of
Chagas disease (American trypanosomiasis) in patients with
HIV/AIDS. Ann Trop Med Parasitol 2007, 101:31-50.
Freilij H, Altcheh J: Congenital Chagas' disease: diagnostic and
clinical aspects. Clin Infect Dis 1995, 21:551-555.
Nisida IV, Amato Neto V, Braz LM, Duarte MI, Umezawa ES: A survey of congenital Chagas' disease, carried out at three health
institutions in Sao Paulo City, Brazil. Rev Inst Med Trop Sao Paulo
1999, 41:305-311.
Faye A, Pornprasert S, Dolcini G, Ave P, Taieb J, Taupin JL, Derrien
M, Huerre M, Barre-Sinoussi F, Chaouat G, Menu E: Evaluation of
the placental environment with a new in vitro model of
histocultures of early and term placentae: determination of
cytokine and chemokine expression profiles. Placenta 2005,
26:262-267.
Dolcini G, Derrien M, Chaouat G, Barre-Sinoussi F, Menu E: Cellfree HIV type 1 infection is restricted in the human trophoblast choriocarcinoma BeWo cell line, even with expression
of CD4, CXCR4 and CCR5. AIDS Res Hum Retroviruses 2003,
19:857-864.
http://www.retrovirology.com/content/5/1/53
36.
37.
38.
39.
40.
41.
42.
43.
44.
45.
46.
47.
48.
49.
50.
51.
52.
53.
54.
55.
56.
57.
Cazzulo JJ: Proteinases of Trypanosoma cruzi: patential targets
for the chemotherapy of Changas desease. Curr Top Med Chem
2002, 2:1261-1271.
Karp CL, Auwaerter PG: Coinfection with HIV and tropical
infectious diseases. I. Protozoal pathogens. Clin Infect Dis 2007,
45:1208-1213.
Pornprasert S, Faye A, Mary JY, Dolcini G, Leechanachai P, Chaouat
G, Ngo N, Barre-Sinoussi F, Menu E: Down modulation of TNFalpha mRNA placental expression by AZT used for the prevention of HIV-1 mother-to-child transmission. Placenta 2006,
27:989-995.
Akkina RK, Walton RM, Chen ML, Li QX, Planelles V, Chen IS: Highefficiency gene transfer into CD34+ cells with a human
immunodeficiency virus type 1-based retroviral vector pseudotyped with vesicular stomatitis virus envelope glycoprotein G. J Virol 1996, 70:2581-2585.
Sartori MJ, Pons P, Mezzano L, Lin S, de Fabro SP: Trypanosoma
cruzi infection induces microfilament depletion in human
placenta syncytiotrophoblast. Placenta 2003, 24:767-771.
Warrilow D, Harrich D: HIV-1 replication from after cell entry
to the nuclear periphery. Curr HIV Res 2007, 5:293-299.
Miller MD, Farnet CM, Bushman FD: Human immunodeficiency
virus type 1 preintegration complexes: studies of organization and composition. J Virol 1997, 71:5382-5390.
Warrilow D, Meredith L, Davis A, Burrell C, Li P, Harrich D: Cell
factors stimulate human immunodeficiency virus type 1
reverse transcription in vitro. J Virol 2008, 82:1425-1437.
Gurer C, Hoglund A, Hoglund S, Luban J: ATPgammaS disrupts
human immunodeficiency virus type 1 virion core integrity.
J Virol 2005, 79:5557-5567.
Saito S: Cytokine network at the feto-maternal interface. J
Reprod Immunol 2000, 47:87-103.
Bowen JM, Chamley L, Keelan JA, Mitchell MD: Cytokines of the
placenta and extra-placental membranes: roles and regulation during human pregnancy and parturition. Placenta 2002,
23:257-273.
Teixeira MM, Gazzinelli RT, Silva JS: Chemokines, inflammation
and Trypanosoma cruzi infection.
Trends Parasitol 2002,
18:262-265.
Breen EC: Pro- and anti-inflammatory cytokines in human
immunodeficiency virus infection and acquired immunodeficiency syndrome. Pharmacol Ther 2002, 95:295-304.
Cinque P, Bestetti A, Marenzi R, Sala S, Gisslen M, Hagberg L, Price
RW: Cerebrospinal fluid interferon-gamma-inducible protein
10 (IP-10, CXCL10) in HIV-1 infection. J Neuroimmunol 2005,
168:154-163.
Monteiro de Almeida S, Letendre S, Zimmerman J, Lazzaretto D,
McCutchan A, Ellis R: Dynamics of monocyte chemoattractant
protein type one (MCP-1) and HIV viral load in human cerebrospinal fluid and plasma. J Neuroimmunol 2005, 169:144-152.
Shacklett BL, Cox CA, Wilkens DT, Karl Karlsson R, Nilsson A,
Nixon DF, Price RW: Increased adhesion molecule and chemokine receptor expression on CD8+ T cells trafficking to cerebrospinal fluid in HIV-1 infection.
J Infect Dis 2004,
189:2202-2212.
Lane BR, King SR, Bock PJ, Strieter RM, Coffey MJ, Markovitz DM:
The C-X-C chemokine IP-10 stimulates HIV-1 replication.
Virology 2003, 307:122-134.
Lane BR, Lore K, Bock PJ, Andersson J, Coffey MJ, Strieter RM, Markovitz DM: Interleukin-8 stimulates human immunodeficiency
virus type 1 replication and is a potential new target for
antiretroviral therapy. J Virol 2001, 75:8195-8202.
Pattillo RA, Gey GO: The establishment of a cell line of human
hormone-synthesizing trophoblastic cells in vitro. Cancer Res
1968, 28:1231-1236.
Ende A van der, du Maine A, Schwartz AL, Strous GJ: Modulation of
transferrin-receptor activity and recycling after induced differentiation of BeWo choriocarcinoma cells. Biochem J 1990,
270:451-457.
Wice B, Menton D, Geuze H, Schwartz AL: Modulators of cyclic
AMP metabolism induce syncytiotrophoblast formation in
vitro. Exp Cell Res 1990, 186:306-316.
Liu F, Soares MJ, Audus KL: Permeability properties of monolayers of the human trophoblast cell line BeWo. Am J Physiol
1997, 273:C1596-1604.
Page 12 of 13
(page number not for citation purposes)
�Retrovirology 2008, 5:53
58.
59.
60.
61.
62.
63.
http://www.retrovirology.com/content/5/1/53
Connor RI, Chen BK, Choe S, Landau NR: Vpr is required for efficient replication of human immunodeficiency virus type-1 in
mononuclear phagocytes. Virology 1995, 206:935-944.
Perez-Bercoff D, David A, Sudry H, Barre-Sinoussi F, Pancino G:
Fcgamma receptor-mediated suppression of human immunodeficiency virus type 1 replication in primary human macrophages. J Virol 2003, 77:4081-4094.
Landau NR, Page KA, Littman DR: Pseudotyping with human Tcell leukemia virus type I broadens the human immunodeficiency virus host range. J Virol 1991, 65:162-169.
Risso MG, Garbarino GB, Mocetti E, Campetella O, Gonzalez Cappa
SM, Buscaglia CA, Leguizamon MS: Differential expression of a
virulence factor, the trans-sialidase, by the main Trypanosoma cruzi phylogenetic lineages.
J Infect Dis 2004,
189:2250-2259.
Giavedoni LD: Simultaneous detection of multiple cytokines
and chemokines from nonhuman primates using luminex
technology. J Immunol Methods 2005, 301:89-101.
Thomson MA, Yoder BA, Winter VT, Giavedoni L, Chang LY, Coalson JJ: Delayed extubation to nasal continuous positive airway
pressure in the immature baboon model of bronchopulmonary dysplasia: lung clinical and pathological findings. Pediatrics 2006, 118:2038-2050.
Publish with Bio Med Central and every
scientist can read your work free of charge
"BioMed Central will be the most significant development for
disseminating the results of biomedical researc h in our lifetime."
Sir Paul Nurse, Cancer Research UK
Your research papers will be:
available free of charge to the entire biomedical community
peer reviewed and published immediately upon acceptance
cited in PubMed and archived on PubMed Central
yours — you keep the copyright
BioMedcentral
Submit your manuscript here:
http://www.biomedcentral.com/info/publishing_adv.asp
Page 13 of 13
(page number not for citation purposes)
�